WO1997028273A9 - Expression of group b neisseria meningitidis outer membrane (mb3) protein from yeast and vaccines - Google Patents

Abstract

The present invention relates, in general, to a method for obtaining the outer membrane protein meningococcal group B porin proteins, in particular MB3, and fusion proteins thereof. In particular, the present invention relates to a method of expressing the outer membrane protein meningococcal group B porin proteins in yeast. The invention also relates to a method of high level expression of the above-mentioned proteins wherein the rate of protein expression is enhanced by substituting a nucleotide sequence for the 5' region of the gene encoding said protein wherein the sequence has been optimized for yeast codon usage. The invention also relates to a vaccine comprising group A meningococcal polysaccharide (GAMP), group B meningococcal polysaccharide (GBMP) and group C meningococcal polysaccharide (GCMP) antigens, together with a pharmaceutically acceptable carrier. The invention also relates to a method of inducing an immune response in a mammal, comprising administering the above-mentioned vaccine to a mammal in an amount sufficient to induce an immune response.

Description

Expression of Group B Neisseria meningitidis

Outer Membrane (MB3) Protein from

Yeast and Vaccines

Background of the Invention

Field of the Invention

The present invention is in the field of recombinant genetics, protein expression, and vaccines. The present invention relates to a method of expressing in a recombinant yeast host an outer membrane group B porin protein from Neisseria meningitidis. The invention also relates to a vaccine comprising group A meningococcal polysaccharide (GAMP), group B meningococcal polysaccharide (GBMP) and group C meningococcal polysaccharide (GCMP) antigens, together with a pharmaceutically acceptable carrier. The invention also relates to a method of inducing an immune response in a mammal, comprising administering the above-mentioned vaccine to a mammal in an amount sufficient to induce an immune response.

Background Information

Meningococcal meningitis remains a worldwide problem, and occurs in both endemic and epidemic forms (Peltola, H., Rev. Infect. Dis. 5:71 -91 (1983);

Gotschlich, E.C., "Meningococcal Meningitis," in Bacterial Vaccines, Germanier, E., ed., Academic, New York (1984), pp.237-255). Epidemic disease occurs in all parts of the world and incidences as high as 500 per 100,000 population have been reported. Without antibiotic treatment the mortality is extremely high (85%), and even with antibiotics, it remains at approximately 10%. In addition, patients cured by antibiotic therapy can still suffer serious and permanent neurologic deficiencies. These facts together with the emergence of sulfadiazine- resistant strains of Neisseria meningilidis promoted the rapid development of a commercial vaccine (Peltola, H., Rev. Infect. Dis. 5:71-91 (1983)).

Neisseria meningitidis is a gram-negative organism that has been classified serologically into groups A, B, 29e. W135, X, Y. and Z (Gotschlich, E.C., "Meningococcal Meningitis." in Bacterial Vaccines. Germanier, E., ed..

Academic, New York (1984), pp.237-255). Additional groups H, 1, and were isolated in China (Ding, S.-Q. et al., J. Biol. Stand. 9:307-315 (1981 )) and group L was isolated in Canada (Ashton, F.E. et al., J. Clin. Microbiol. 17:722-727 (1983)). The grouping system is based on the organisms' capsular polysaccharides. It was established (Lui, T.-Y. el al., J. Biol. Chem. 27r5:2849-

2858 (1971 )) that the group A polysaccharide is a partially O-acetylated ( 1 -6) linked homopolymer of 2-acetamido-2-detoxy-D-mannopyranosy I phosphate, and that both groups B and C polysaccharides are homopolymers of sialic acid.

N. meningitidis groups A, B, and C are responsible for approximately 90% of cases of meningococcal meningitis. Success in the prevention of group

A and C meningococcal meningitis was achieved using a bivalent polysaccharide vaccine (Gotschlich, E.C. et al, J. Exp. Med. 729:1 67-1 84 ( 1969); Artenstein, M.S. et al., N Engl. J. Med. 252:417-420 ( 1970)); this vaccine became a commercial product and has been used successfully in the last decade in the prevention and arrest of major meningitis epidemics in many parts of the world.

However, there has been a need to augment this vaccine because a significant proportion of cases of meningococcal meningitis are due to groups other than A and C. Group B is of particular epidemiologic importance, but groups Y and W135 are also significant (Cadoz, M. et al., Vaccine 3:340-342 (1985)). The inclusion of the group B polysaccharide in the vaccine has been a special problem (see below); however, a tetravalent vaccine comprising groups A, C, Wl 35, and Y has proven to be safe and immunogenic in humans (Cadoz, M. et al., Vaccine 5:340-342 (1985)) and is the currently used meningococcal meningitis vaccine (Jennings, H.J., "Capsular Polysaccharides as Vaccine Candidates," in Current Topics in Microbiol. and Immunol, Jann, D. and Jann. B., eds, Springer- Verlag.

Berlin (1990) Vol 150:97-127).

The outer membranes of Neisseria species much like other Gram negative bacteria are semi-permeable membranes which allow free flow access and escape of small molecular weight substances to and from the periplasmic space of these bacteria but retard molecules of larger size (Heasley, F.A., et al. , "Reconstitution and characterization of the N. gonorrhoeae outer membrane permeability barrier," in Genetics and Immunobiology of Neisseria gonorrhoeae. Danielsson and Normark, eds., University of Umea, Umea, pp. 12-15 (1980); Douglas, J.T., et al. FEMS Microbiol. Lett 72:305-309 (1981)). One of the mechanisms whereby this is accomplished is the inclusion within these membranes of proteins which have been collectively named porins. These proteins are made up of three identical polypeptide chains (Jones, R.B., et al. Infect. Immun. 3(7:773-780 (1980); McDade, Jr. and Johnston, J. Bacterial 7-77: 1 183-1 191 (1980)) and in their native trimer conformation, form water filled, voltage-dependent channels within the outer membrane of the bacteria or other membranes to which they have been introduced (Lynch, E.C., et al, Biophys. J. -77:62 (1983); Lynch, E.C., et al, Biophys. J. 45:104-107 (1984); Young, J.D.E., et al, Proc. Nail Acad. Sci USA 50:3831-3835 (1983); Mauro, A., et al, Proc. Natl Acad. Sci. USA 55: 1071 -1075 (1988); Young, J.D., el al, Proc. Natl Acad. Sci. USA 53: 150-154 (1986)). Because of the relative abundance of these proteins within the outer membrane, these protein antigens have also been used to subgroup both Neisseria gonorrhoeae and Neisseria meningilidis into several serotypes for epidemiological purposes (Frasch, C.E., et al. , Rev. Infect. Dis. 7:504-510 (1985); Knapp, J.S., et al, "Overview of epidemiological and clinical applications of auxotype/serovar classification of Neisseria gonorrhoeae ," 777c Pathogenic Neisseriae, Schoolnik, G.K., ed., American Society for Microbiology, Washington, pp. 6-12 (1985)). To date, many of these proteins from both gonococci and meningococci have been purified (Heckels, .I.E., J Gen. Microbiol. 99:333-341 (1977); James and Heckels, J. Immunol Melh. 42:223-228 (1981); Judd, R.C., Anal. Biochem. 773:307-316 (1988); Blake and Gotschlich,

Infect. Immun. 36:277-283 (1982); Wetzler, L.M., et al , J. Exp. Med. 765: 1883- 1897 ( 1988)), and cloned and sequenced (Gotschlich, E.C., et al , Proc. Natl Acad. Sci. USA 54:8135-8139 (1987); McGuinness, B., et al , J. Exp. Med. 777 : 1871 -1882 (1990); Carbonetti and Sparling, Proc. Natl. Acad. Sci. USA 54:9084-9088 (1987); Feavers, I.M.. et al.. Infect. Immun. 60:3620-3629 ( 1992);

Murakami, K., et al, Infect. Immun. 57:2318-2323 (1989): Wolff and Stern. FEMS Microbiol. Lett. 53: 179-186 (1991 ); Ward, M.J., et al , FEMS Microbiol Lett. 73:283-289 (1992)).

The porin proteins were initially co-isolated with lipopolysaccharides (LPS). Consequently, the porin proteins have been termed "endotoxin-associated proteins" (Bjornson et al, Infect. Immun. 56: 1602-1607 (1988)). Studies on the wild type porins have reported that full assembly and oligomerization are not achieved unless LPS from the corresponding bacterial strain is present in the protein environment (Holzenburg et al, Biochemistry 25:4187-4193 (1989); Sen and Nikaido, J. Biol. Chem. 266Λ 1295-1 1300 (1991 )).

The meningococcal porins have been subdivided into three major classifications which in antedated nomenclature were known as Class 1 , 2, and 3 (Frasch, C.E., et al, Rev. Infect. Dis. 7:504-510 (1985)). Each meningococcus examined has contained one of the alleles for either a Class 2 porin gene or a Class 3 porin gene but not both (Feavers, I.M., et al. Infect. Immun. 60:3620-

3629 (1992)); Murakami, K., et al, Infect. Immun. 57:2318-2323 (1989)). The presence or absence of the Class 1 gene appears to be optional. Likewise, all probed gonococci contain only one porin gene with similarities to either the Class 2 or Class 3 allele (Gotschlich, E.C.. et al . Proc. Nail Acad Sci. USA 54:8135- 8139 (1987); Carbonetti and Sparling. Proc. Natl Acad. Sci. USA 54:9084-9088 (1987)). N. gonorrhoeae appear to completely lack the Class 1 allele. The data from the genes that have been thus far sequenced would suggest that all neisserial porin proteins have at least 70% homology with each other with some variations on a basic theme (Feavers, I.M., et al, Infect. Immun. 60:3620-3629 ( 1992)). It has been suggested that much of the variation seen between these neisserial porin proteins is due to the immunological pressures brought about by the invasion of these pathogenic organisms into their natural host, man. However, very little is known about how the changes in the porin protein sequence effect the functional activity of these proteins. It has been previously reported that isolated gonococcal porins of the

Class 2 allelic type behave electrophysically somewhat differently than isolated gonococcal porins of the Class 3 type in lipid bilayer studies both in regards to their ion selectivity and voltage-dependence (Lynch. E.C., et al , Biophys. J. 47:62 (1983); Lynch, E.C., et al, Biophys. J. 45: 104-107 (1984)). Furthermore, the ability of the different porins to enter these lipid bilayers from intact living bacteria seems to correlate not only with the porin type but also with the neisserial species from which they were donated (Lynch, E.C.. el al , Biophys. J. 45: 104- 107 (1984)). It would seem that at least some of these functional attributes could be related to different areas within the protein sequence of the porin. One such functional area, previously identified within all gonococcal

Class 2-like proteins, is the site of chymotrypsin cleavage. Upon chymotrypsin digestion, this class of porins lack the ability to respond to a voltage potential and close. Gonococcal Class 3-like porins as well as meningococcal porins lack this sequence and are thus not subject to chymotrypsin cleavage but nonetheless respond by closing to an applied voltage potential (Greco, F.. "The formation of channels in lipid bilayers by gonococcal major outer membrane protein," thesis. The Rockefeller University, New York ( 1981 ); Greco. F.. el al . Fed. Proc. 39: 1813 (1980)).

As the Neisseria porins are among the most abundant proteins present in the outer membrane of these organisms, and as they do not undergo antigenic shift during infection (unlike several other major surface antigens), their universal presence in both Neisseria meningitidis and Neisseria gonorrhoea, as well as their exposure at the surface, make them candidates for components of vaccines against these organisms. Patients convalescing from meningococcal disease produce anti-porin antibodies, and antibodies elicited by immunization with porin proteins are bactericidal to homologous serotypes. Furthermore, within a particular epidemioiogic setting, most strains causing meningococcal disease belong to a limited number of serotypes, notably serotype 2 among strains with a class 2 protein and serotype 15 among strains with class 3 proteins. Therefore, class 2 and 3 proteins are attractive candidates for vaccines.

The major impediment for such studies has been the ability to easily manipulate the porin genes by modern molecular techniques and obtain sufficient purified protein to carry out the biophysical characterizations of these altered porin proteins. It was early recognized that cloned neisserial porin genes, when expressed in Escherichia coli, were lethal to the host E. coli (Carbonetti and

Sparling, Proc. Natl Acad. Sci. USA 54:9084-9088 ( 1987); Carbonetti, N.H., et al, Proc. Natl. Acad. Sci. USA 55:6841 -6845 ( 1988); Barlow, A.K., el al , Infect. Immun. 55:2734-2740 (1987)). Thus, many of these genes were cloned and sequenced as pieces of the whole gene or placed into low copy number plasmids under tight expression control (Carbonetti, N.H., el al, Proc. Natl. Acad. Sci.

USA 55:6841-6845 (1988)). Under these conditions, even when the entire porin gene was expressed, very little protein accumulated that could be further purified and processed for characterization.

Another tack to this problem which has met with a modicum of success has been to clone the porin genes into a low copy, tightly controlled expression plasmid, introduce modifications to the porin gene, and then reintroduce the modified sequence back into Neisseria (Carbonetti, N.H., el al. Proc. Nail Acad. Sci. USA 55:6841-6845 (1988)). However, this has also been fraught with problems due to the elaborate restriction endonuclease system present in Neisseria, especially gonococci (Davies, J.K., Clin. Microbiol. Rev. 2:S78-S82 (1989)).

While a vaccine comprising neisserial porin has long been sought, an effective meningococcal polysaccharide vaccine which would give complete coverage to all serogroup organisms and to all humans is also needed. Several serious problems remain in the development of such a broad range polysaccharide vaccine. First, it has been established that although the group A and C polysaccharides are efficacious in adults and older children, their effectiveness in infants has only been marginal (Goldschneider, I., el al, J. Infect. Dis. 725:769-776 (1973); Gotschlich, E.C., el al, "The Immune Responses to

Bacterial Polysaccharides in Man." In: Antibodies in Human Diagnosis and Therapy, Haber, E. and Krause, R.M., eds.. Raven, New York (1977), pp. 3 1 - 402). Second, the group B meningococcal polysaccharide is only poorly immunogenic in man (Wyle, F.A., et al, J. Infect. Dis. 726:514-521 (1972)). A third problem is the tendency for muilivalent vaccines to be less immunogenic than each component would be if administered individually (Insel, R.A., "Potential alterations in immunogenicity by combining or simultaneously administering vaccine components," In: Annals of (he New York Academy of Sciences, Vol. 754. Combined Vaccines and Simultaneous Administration: Current Issues and Perspectives, Williams. J.C., et al. eds, New York Academy of Sciences, New York (1993), pp. 35-47; Clemens, J.. el al , "Interactions between PRP-T vaccine against Haemophilus influenzae type b and conventional infant vaccines: lessons for future studies of simultaneous immunization and combined vaccines," In: Annals of the Neiv York Academy of Sciences, Vol. 754. Combined Vaccines and Simultaneous Administration: Current Issues and

Perspectives, Williams, J.C., el al, eds, New York Academy of Sciences. New York (1993), pp. 255-266; Paradiso, P.R., et al.. Pediatrics 92^:827-832 (1993)).

Presently available vaccines against group A and C N. meningilidis are poorly immunogenic in human infants (age two and under) because, in contrast to the immunity generated by most antigens, a polysaccharide-specific immune response in infants is T-cell-independent. In the absence of T-cell involvement, an immune response is of short duration. More importantly, no memory is demonstrable, so no "booster" reactions occur. Furthermore, antibody affinity maturation does not occur. These deficiencies are due to the inability of polysaccharides to specifically bind to T-cells. Presumably, the structural features required for association with a T-cell receptor do not exist in the majority of polysaccharides. Because of the T-cell independent nature of the immune response, the antibody response to a polysaccharide in infants is limited to antibodies of the IgM isotype; the isotype switching necessary for production of non-IgM antibodies requires T-cell involvement. Polysaccharide antigens present less of a problem in more mature humans (over age two), as they are able to induce antibodies of the IgG isotype as well as IgM (Yount el al, J. Exp. Med. 727:633-646 (1968)). The group B meningococcal polysaccharide is even less immunogenic in humans of all ages than other polysaccharides. Two major explanations have been proposed to account for this characteristic (Jennings, H.J., Adv. Carbohydr. Chem. Biochem. 47:155-208 (1983); Lifely, M.R. et al, Vaccine 5: 1 1-26 (1987)). One is that the group B meningococcal polysaccharide, an α-(2— ►8)-linked sialic acid homopolymei, is rapidly depolymerized in human tissue because of the action of neuraminidase. The other is that the structure is recognized as "self by the human immune system and in consequence, the production of antibody specific for this structure is suppressed. The weight of evidence is in favor of the latter explanation because a neuraminidase-sensitive variant of the group C meningococcal polysaccharide [an α-(2→9)-linked sialic acid homopolymer] still proved to be highly immunogenic in man (Glode, M.P. et al, .1. Infect. Dis. 739:52-59 (1979)). In addition it was demonstrated that conjugation of the group B polysaccharide to a protein carrier (tetanus toxoid) through its terminal nonreducing sialic acid, which stabilizes the polysaccharide to neuraminidase, did not result in any significant enhancement in its immunogenicity (Jennings. H..1. and Lugowski, C., J. Immunol. 727: 101 1-1018 (1981)). The above observations are consistent with a theory that the immune mechanism avoids the production of antibody having a specificity for the α-(2→8)-linked sialic acid residues. This theory was further confirmed by the identification of α-(2→8)-linked sialic acid residues in the oligosaccharides of human and animal tissue. A novel approach to overcoming the poor immunogenicity of the group B polysaccharide has been to modify it chemically.

The T-cell independent quality of polysaccharide antigens in infant humans can be overcome by conjugating (covalently coupling) the polysaccharide to a protein carrier. The capsular polysaccharides of the bacteria primarily responsible for postneonatal meningitis have been conjugated to protein carriers; these include type b H. influenzae (Schneerson, R. el al, J. Exp. Med. 752:361 - 376 (1980); Anderson, P.W., Infect. Immun. 39:233-238 (1983); Marburg, S. et al, J. Am. Chem. Soc. 705:5282-5287 (1986)), group A (Jennings, Η.J. and Lugowski, Q., J. Immunol. 727: 1011-1018 (1981 )) ; Beuvery, E.C. el al, Vaccine

1 :31-36 (1983)), B (Jennings, Η.J. and Lugowski, C., J. Immunol. 727:101 1-1018 (1981 )), and C (Jennings, Η.J. and Lugowski, C, J. Immunol 727: 101 1 -101 8 (1981)); Beuvery, E.C. et al. Infect. Immun. 40:39-45 (1983)) N. meningitidis, and type 6A Strep, pneumoniae (Chu, C. et al, Infect. Immun. 40:245-256 (1983)). For the choice of carrier protein most investigators have used tetanus toxoid or diphtheria toxoid, two proteins currently used as infant vaccines. A recent innovation on this theme has been the use of a mutant-derived diphtheria toxin (CRM ,„) (Anderson, P.W., Infec Immun. 39:233-238 (1983)) which is nontoxic. The significance of this protein is that because it does not require detoxifying by treatment with formaldehyde, all its amino groups remain underivatized, which greatly facilitates the conjugation process.

The use of other potential bacterial proteins as carriers has not been extensively explored. However, a serotype outer member protein of Λ'. meningitidis has been used as a protein carrier (Marburg, S. et al, J. Am. Chem. Soc. 705:5282-5287 (1986)). In light of the foregoing, it will be clear that there is a significant need for a process by which large quantities of the outer membrane group B porin proteins of TV. meningitidis can be obtained. It will also be clear that a need exists for a polysaccharide vaccine which would give complete coverage to the three major serogroups of N meningitidis, groups A, B and C, and which would provide immunity against these organisms to both infants and more mature humans.

Summary of the Invention

It is a general object of the invention to provide a method of expressing in yeast the meningococcal group B porin proteins, in particular, the class 3 porin protein.

It is a specific object of the invention to provide a method of expressing the outer membrane meningococcal group B porin protein or a fusion protein thereof in yeast, comprising:

(a) cloning into a plasmid having a selectable marker a gene coding for a protein selected from the group consisting of:

(i) a mature porin protein

(ii) a fusion protein which is a mature porin protein fused to a yeast secretion signal peptide; wherein said gene is operably linked to a yeast promoter; (b) transforming said plasmid containing said gene into a yeast strain;

(c) selecting the transformed yeast by growing said yeast in a culture medium allowing selection of said transformed yeast;

(d) growing the transformed yeast, and

(e) inducing expression of said protein to give yeast containing said protein; wherein the protein so expressed comprises more than about 2% of the total protein expressed in said yeast. It is another specific object of the invention to provide a method of expressing a mature porin protein or fusion protein thereof, wherein the protein so expressed comprises about 3-5% of the total protein expressed in yeast.

It is yet another specific object of the invention to provide a method of expressing a mature porin protein wherein the protein is the Neisseria meningitidis outer membrane meningococcal group B porin protein (MB3).

It is another specific object of the invention to provide a method of expressing a mature porin protein or fusion protein thereof, wherein the yeast promoter is the AOX1 promoter. It is another specific object of the invention to provide a method of expressing the outer membrane meningococcal group B porin protein or a fusion protein thereof in yeast, wherein the yeast secretion signal peptide is selected from the group consisting of the secretion signal of the S. cerevisiae α-mating factor prepro-peptide and the secretion signal of the P. pasloris acid phosphatase gene (P HO).

It is yet another specific object of the invention to provide a method of expressing MB3 or a fusion protein thereof in yeast as described above, wherein the plasmid is selected from the group consisting of pHIL-D2, pHIL-S l , pPIC9 and pPIC9K. It is a further specific object of the invention to provide a method of expressing the above-described meningococcal group B porin protein or fusion protein wherein at least one codon of the 5^' region of the gene encoding said protein has been changed so as to be optimized for yeast codon usage.

It is still a further specific object of the invention to provide a method of expressing the above-described meningococcal group B porin protein or fusion protein wherein the 5' region of the gene encoding said protein comprises a nucleotide sequence that incorporates codons optimized for P pasloris codon usage.

It is another specific object of the invention to provide a method as described above wherein the codon changes are selected from the group of changes consisting of: (GTT to GTC at positions 4-6 of the native sequence), (ACC to ACT at positions 7-9 of the native sequence), (CTG to TTG at positions 10-12 of the native sequence), (GGC to GGT at positions 16-18 of the native sequence), (ACC to ACT at positions 19-21 of the native sequence), (ATC to ATT at positions 22-24 of the native sequence), (AAA to AAG at positions 25-27 of the native sequence), (GCC to GCT at positions 28-30 of the native sequence), (GGC to GGT at positions 31 -33 of the native sequence), (GTA to GTT at positions 34-36 of the native sequence), (GAA to GAG at positions 37-39 of the native sequence); wherein said positions are numbered from the first nucleotide of the native nucleotide sequence encoding said protein.

It is another specific object of the invention to provide a method as described above wherein the 5' region of the gene includes codons optimized for P. pastoris codon usage, and wherein the nucleotide sequence is SEQ ID NO: 26.

It is another specific object of the invention to provide a method of expressing the above-mentioned protein wherein the yeast secretes the protein or fusion protein.

It is another specific object of the invention to provide a method of expressing the above-mentioned protein wherein the vector from which the secreted protein is expressed is selected from the group consisting of pHIL-Sl , pPIC9, and pPIC9K.

It is another specific object of the invention to provide a method of purifying insoluble, intracellular outer membrane meningococcal group B porin protein or fusion protein thereof obtained according to the invention comprising:

(a) lysing the yeast described above which has expressed the protein to release said protein as an insoluble membrane bound fraction;

(b) washing the insoluble material obtained in step (a) with buffers to remove contaminating yeast cellular proteins;

(c) suspending and dissolving said insoluble fraction obtained in step (b) in aqueous solution of denaturant: (d) diluting the solution obtained in step (c) with a detergent; and

(e) purifying said protein by gel filtration and ion exchange chromatography. It is another specific object of the invention to provide a method of purifying the outer membrane meningococcal group B porin protein or fusion protein thereof obtained according to the invention comprising:

(a) centrifuging the yeast culture described above which has expressed the protein to isolate the protein as soluble secreted material;

(b) removing contaminating yeast culture impurities from the soluble secreted material obtained in step (a) by precipitating said impurities with about 20% ethanol, wherein the soluble secreted material remains in the soluble fraction; (c) precipitating the secreted material from the soluble fraction of step (b) with about 80% ethanol;

(d) washing the precipitated material obtained in step (c) with a buffer to remove contaminating yeast secreted proteins;

(e) suspending and dissolving the precipitated material obtained in step (d) in an aqueous solution of detergent; and

(f) purifying the protein by ion exchange chromatography. It is a further specific object of the invention to provide a yeast host cell that contains a gene coding for a protein selected from the group consisting of: (a) a mature porin protein (b) a fusion protein which is a mature porin protein fused to a yeast secretion signal peptide; wherein said gene is operably linked to a yeast promoter.

It is still another specific object of the invention to provide a yeast host cell as described above which is capable of expressing the Neisseria meningilidis mature outer membrane class 3 protein of serogroup B (MB3). It is still another specific object of the invention to provide a yeast host cell as described above wherein the yeast promoter is the AOX1 promoter.

It is another object of the invention to provide a vaccine comprising group A meningococcal polysaccharide (GAMP), group B meningococcal poly- saccharide (GBMP), and group C meningococcal polysaccharide (GCMP) antigens, together with a pharmaceutically acceptable carrier.

It is still another specific object of the invention to provide a method of inducing an immune response in a mammal, comprising administering to a mammal the above-described vaccine in an amount sufficient to induce an immune response in a mammal.

Further objects and advantages of the present invention will be clear from the description that follows.

Brief Description of the Drawings

Figure 1 : A diagram showing the sequencing strategy of the PorB gene. The PCR product described in Example 1 (Materials and Methods section) was ligated into the BamV\\-Xho\ site of the expression plasmid pET-17b. The initial double stranded primer extension sequencing was accomplished using oligonucleotide sequences directly upstream of the Bam\ \\ site and just downstream of the Xho\ site within the pET-17b plasmid. Additional sequence data was obtained by making numerous deletions in the 3 ' end of the gene, using exonuclease III/mung bean nuclease reactions. After religation and transformation back into E. coli, several clones were selected on size of insert and subsequently sequenced. This sequencing was always from the 3' end of the gene using an oligonucleotide primer just downstream of the Bpu\ 1021 site. Figure 2: A gel electrophoresis showing the products of the PCR reaction

(electrophoresed in a 1 % agarose using TAE buffer).

Figures 3 A and 3B. Fig. 3 A: SDS-PAGE analysis of whole cell lysates of E. coli hosting the control pET-17b plasmid without inserts and an E. coli clone harboring pET-17b plasmid containing an insert from the obtained PCR product described in the materials and methods section. Both cultures were grown to an O.D. of 0.6 at 600 nm, IPTG added, and incubated at 37°C for 2 hrs. 1.5 mis of each of the cultures were removed, centrifuged, and the bacterial pellet solubilized in 100 μl of SDS-PAGE preparation buffer. Lane A shows the protein profile obtained with 10 μl from the control sample and Lanes B (5 μl) and C (10 μl) demonstrate the protein profile of the E. coli host expressing the PorB protein. Fig. 3B: Western blot analysis of whole cell lysates of E. coli harboring the control pET-17b plasmid without insert after 2 hrs induction with IPTG, Lane A, 20 μl and a corresponding E. coli clone containing a porB-pET-

17b plasmid, Lane B, 5 μl; Lane C, 10 μl; and Lane D. 20 μl. The monoclonal antibody 4D1 1 was used as the primary antibody and the western blot developed as described. The pre-stained low molecular weight standards from BRL were used in each case. Figure 4: The nucleotide sequence and the translated amino acid sequence of the mature PorB gene cloned into the expression plasmid pET-17b. The two nucleotides which differ from the previously published serotype 15 PorB are underlined.

Figure 5: A graph showing the Sephacryl S-300 column elution profile of both the wild type Class 3 protein isolated from the meningococcal strain 8765 and the recombinant Class 3 protein produced by BL21(DE3) -ΔompA E. coli strain hosting the r3pET-17b plasmid as monitored by absorption at 280nm and SDS-PAGE analysis. The void volume of the column is indicated by the arrow. Fractions containing the meningococcal porin and recombinant porin as determined by SDS-PAGE are noted by the bar.

Figure 6: A graph showing the results of the inhibition ELISA assays showing the ability of the homologous wild type (wt) PorB to compete for reactive antibodies in six human immune sera. The arithmetic mean inhibition is shown by the bold line. Figure 7: A graph showing the results of the inhibition ELISA assays showing the ability of the purified recombinant PorB protein to compete for reactive antibodies in six human immune sera. The arithmetic mean inhibition is shown by the bold line. Figure 8: A graph showing a comparison of these two mean inhibitions obtained with the wt and recombinant PorB protein.

Figure 9A and 9B: The nucleotide sequence and the translated amino acid sequence of the mature class II porin gene cloned into the expression plasmid pET-17b. Figure 10A and 10B: The nucleotide sequence and the translated amino acid sequence of the fusion class II porin gene cloned into the expression plasmid pET-17b.

Figure 1 1 (panels A and B): Panel A depicts the restriction map of the pET-17b plasmid. Panel B depicts the nucleotide sequence between the Bgl and Xhol sites of pET-17b. The sequence provided by the plasmid is in normal print while the sequence inserted from the PCR product are identified in bold print.

The amino acids which are derived from the plasmid are in normal print while the amino acids from the insert are in bold. The arrows demarcate where the sequence begins to match the sequence in Figure 4 and when it ends. Figure 12: A graph showing the level of expression of MB3 for clone pnv

322, where the expression vector used is pHIL-D2. The level of MB3 expressed is depicted as mg of insoluble MB3 per gram of cell pellet per unit time.

Figure 13A: The DNA sequence and translated amino acid sequence of pNV15 (MB3 in pET24a) before codon preference optimization. Figure 13B: The DNA sequence and translated amino acid sequence of

Men.Class3 opt. (MB3 optimized for yeast codon preference).

Figures 14A and 14B: Graphs showing the elution of MB3 from a size exclusion column. MB3 expressed in an intracellular form was purified by a denaturation/renaturation protocol, followed by gel filtration and ion exchange chromatography. The resultant purified protein exhibited by size exclusion chromatography an elution profile which resembles the recombinant class 3 protein overexpressed in E. coli, and both give the same elution profile as the native wild-type counterpart. This indicates that MB3 refolds and oligomerizes, achieving full native conformation. 14(A): the elution profile of MB3; 14(B): the elution profile of class 3 protein expressed and refolded from E. coli inclusion bodies.

Figure 15: A graph showing the size exclusion chromatography of purified MB3 on a Superose 12 (Pharmacia) column connected to an HPLC (Hewlett Packard model 1090). Based on the comparison of MB3 with the native wild-type counterpart, as well as calibration using molecular weight standards

(designated as arrows), the elution profile is indicative of trimeric assembly. Molecular weight markers are: 1 = thyroglobulin (670,000); 2 = gammaglobulin (158,000); 3 = yoglobin (17,000).

Figures 16A, 16B and 16C: The DNA sequence of clone pnv 322. This clone has the MB3 gene inserted into the EcoRl site of the Invitrogen expression vector pHIL-D2. MB3 is thus inserted directly downstream from the AOXI promoter. This construct allows intracellular expression. Vector sequences are shown in upper case letters, while the MB3 sequence is given in lower case letters. Figures 17A, 17B and 17C: The DNA sequence of clone pnv 318. This clone has the MB3 gene inserted into the XhoI-BamHI sites of the Invitrogen expression vector pHIL-Sl . MB3 is thus inserted directly downstream from the

PHOl leader peptide, in frame with the secretion signal open reading frame for secretion of expressed protein. Vector sequences are shown in upper case letters, while the MB3 sequence is given in lower case letters.

Figures 18A, 18B and 18C: The DNA sequence of clone pnv 342. This clone has the MB3 gene inserted into the EcoRl-Avrll sites of the Invitrogen expression vector pPIC-9. MB3 is thus inserted directly downstream from the secretion signal of α-factor prepro peptide, for secretion of expressed protein. Vector sequences are shown in upper case letters, while the MB3 sequence is given in lower case letters.

Figures 19A, 19B and 19C: The DNA sequence of clone pnv 350. This clone has the MB3 gene inserted into the EcoRl-Avrll sites of the Invitrogen expression vector pPIC-9K. MB3 is thus inserted directly downstream from the secretion signal of α-factor prepro peptide, for secretion of expressed protein. Vector sequences are shown in upper case letters, while the MB3 sequence is given in lower case letters.

Figure 20: A graph showing the absorbance spectra (electropherogram) of GAMP, TT-monomer, and GAMP-TT conjugate.

Figure 21 : A graph showing the absorbance spectra (electropherogram) of GCMP, TT-monomer, and GCMP-TT conjugate.

Figure 22: A graph showing the A-specific IgG ELISA titer elicited by monovalent (A) and trivalent (A/B/C) meningococcal conjugate vaccines in mice. Figure 23: A graph showing the B-specific IgG ELISA titer elicited by monovalent (A) and trivalent (A7B/C) meningococcal conjugate vaccines in mice.

Figure 24: A graph showing the C-specific IgG ELISA titer elicited by monovalent (C) and trivalent (A/B/C) meningococcal conjugate vaccines in mice.

Figure 25: A graph showing the A-specific bacteriocidal activity elicited by monovalent (A) and trivalent (A/B/C) meningococcal conjugate vaccines in mice.

Figure 26: A graph showing the B-specific bacteriocidal activity elicited by monovalent (A) and trivalent (A/B/C) meningococcal conjugate vaccines in mice. Figure 27: A graph showing the C-specific bacteriocidal activity elicited by monovalent (A) and trivalent (A/B/C) meningococcal conjugate vaccines in mice. Detailed Description of the Invention

It is possible to overcome some of the difficulties involved in expressing and purifying the outer membrane group B porin proteins of N meningilidis from E. coli. The DNA sequences of the mature porin proteins, e.g. class 2 and class 3 as well as fusions thereof, were amplified using the chromosome of the meningococcal bacteria as a template for the PCR reaction. The amplified porin sequences were ligated and cloned into an expression vector containing the T7 promoter. E. coli strain BL21 lysogenic for the DE3 lambda phage (Studier and Moffatt, J. Mol. Biol. 759:1 13-130 (1986)), modified to eliminate the ompA gene. was selected as one expression host for the pET-17b plasmid containing the porin gene. Upon induction, large amounts of the meningococcal porin proteins accumulated within E. coli without any obvious lethal effects to the host bacterium. The expressed meningococcal porin proteins were extracted and processed through standard procedures and finally purified by molecular sieve chromatography and ion exchange chromatography. As judged by the protein profile from the molecular sieve chromatography, the recombinant meningococcal porins eluted from the column as trimers. To be certain that no PCR artifacts had been introduced into the meningococcal porin genes to allow for such high expression, the inserted PorB gene sequence was determined. Inhibition ELISA assays were used to give further evidence that the expressed recombinant porin proteins had renatured into their natural antigenic and trimer conformation.

As an alternative to the bacterial E. coli host system, Meningococcal B Class 3 porin protein (MB3) may be expressed in yeast. A preferred host is the methylotrophic yeast Pichia pasloris, which may be transformed with the Pichia

Expression Kit developed by Invitrogen. Yeasts are attractive hosts for the production of heterologous proteins. Unlike prokaryotic systems, their eukaryotic subcellular organization enables them to carry out many of the post-translational folding, processing and modification events required to produce "authentic" and bioactive proteins. As a eukaryote, Pichia pasloris has many of the advantages of a higher eukaryotic expression system, while being as easy to manipulate as E. coli or Saccharomyces cerevisiae. As a yeast, it shares the advantages of molecular and genetic manipulations with Saccharomyces, and it has the added advantages of 10- to 100-fold higher heterologous protein expression levels and the protein processing characteristics of higher eukaryotes.

Expression in Pichia also provides advantages compared to expression in other yeast strains because Pichia does not tend to hyperglycosylate proteins as does S. cerevisiae. Further, proteins expressed and modified in Pichia may be more useful therapeutically than those produced by S. cerevisiae, as oligosaccharides added by Pichia lack the αl ,3 glycan linkages which are believed to be primarily responsible for the hyper-antigenic nature of proteins produced by S. cerevisiae. Several vaccine antigens have been produced in yeast cells, including hepatitis B surface antigen which is in clinical use (Cregg et al. ,

Bio/Technology 77:905-910 (1993)).

Unlike the porin proteins of E. coli and a few other gram negative bacteria, relatively little is known about how changes in the primary sequence of porins from Neisseria effect their ion selectivity, voltage dependence, and other biophysical functions. Recently, the crystalline structure of iwo E. coli porins,

OmpF and PhoE, were solved to 2.4A and 3.0A, respectively (Cowan, S.W., et al, Nature 358:121-133 (1992)). Both of these E. coli porins have been intensively studied owing to their unusual stability and ease with which molecular genetic manipulations could be accomplished. The data obtained for the genetics of these two porins correlated well with the crystalline structure. Although it has been shown in several studies using monoclonal antibodies to select neisserial porins that the surface topology of Neisseria closely resembles that of these two E. coli porins (van der Ley, P., et al, Infect. Immun. 59:2963-2971 ( 1991 )), almost no information is available about how changes in amino acid sequences in specific areas of the neisserial porins effect their biophysical characteristics, as is known about the E. coli porins (Cowan, S.W., et al. Nature 355:727-733 (1992)).

Two of the major problems impeding this research are: (1 ) the inability to easily manipulate Neisseria genetically by modern molecular techniques and (2) the inability to express sufficient quantities of neisserial porins in E. coli or yeast for further purification to obtain biophysical and biochemical characterization data. In fact, most of the DNA sequence data on gonococcal and meningococcal porins have been obtained by cloning overlapping pieces of the porin gene and then reconstructing the information to reveal the entire gene sequence (Gotschlich, E.C, et al, Proc. Natl. Acad. Sci. USA 54:8135-8139

(1987); Murakami, K., el al, Infect. Immun. 57:2318-2323 (1989)). Carbonetti et al. were the first to clone an entire gonococcal porin gene into E. coli using a tightly controlled pT7-5 expression plasmid. The results of these studies showed that when the porin gene was induced, very little porin protein accumulated and the expression of this protein was lethal to the E. coli (Carbonetti and Sparling,

Proc. Natl Acad. Sci. USA 54:9084-9088 (1987)). In additional studies, Carbonetti et al. (Proc. Nail Acad. Sci. USA 55:6841 -6845 ( 1988)) did show that alterations in the gonococcal porin gene could be made in this system in E. coli and then reintroduced into gonococci. However, the ease with which one can make these manipulations and obtain enough porin protein for further biochemical and biophysical characterization seems limited.

Feavers et al. have described a method to amplify, by PCR, neisserial porin genes from a wide variety of sources using two synthesized oligonucleotides to common domains at the 5' and 3' ends of the porin genes respectively (Feavers, I.M., et al, Infect. Immun. 60:3620-3629 (1992)). The oligonucleotides were constructed such that the amplified DNA could be forced cloned into plasmids using the restriction endonucleases BglU and Xhol.

Using the Feavers et al. PCR system, the DNA sequence of the mature PorB protein from meningococcal strain 8765 serotype 15 was amplified and ligated into the BamHl-Xhol site of the T7 expression plasmid pET-17b. This placed the mature PorB protein sequence in frame directly behind the T7 promoter and 20 amino acids of the φl O protein including the leader sequence. Upon addition of IPTG to a culture of E. coli containing this plasmid, large amounts of PorB protein accumulated within the bacteria. A complete explanation for why this construction was non-lethal to the E. coli and expressed large amount of the porin protein, await further studies. However, one possible hypothesis is that by replacing the neisserial promoter and signal sequence with that of the T7 and φl O respectively, the porin product was directed to the cytoplasm rather than toward the outer membrane. Henning and co-workers have reported that when E. coli OmpA protein and its fragments are expressed, those products which are found in the cytoplasm are less toxic than those directed toward the periplasmic space (Klose, M., et l., J. Biol. Chem. 263: 13291 -13296 (1988); Klose, M., et al., J. Biol. Chem. 263: 13297-13302 (1988); Freudl, R., et al, J. Mol Biol. 205:771-775 (1989)). Whatever the explanation, once the PorB protein was expressed, it was easily isolated, purified and appeared to reform into trimers much like the native porin. The results of the inhibition ELISA data using human immune sera suggests that the PorB protein obtained in this fashion regains most if not all of the antigenic characteristics of the wild type PorB protein purified from meningococci. This expression system lends itself to the easy manipulation of the neisserial porin gene by modern molecular techniques. In addition, this system allows one to obtain large quantities of pure porin protein for characterization. In addition, the present expression system allows the genes from numerous strains of Neisseria, both gonococci and meningococci, to be examined and characterized in a similar manner. The Neisseria meningitidis outer membrane class 3 protein from serogroup B (MB3) was also expressed in the methylotrophic yeast Pichia pasloris by placing the MB3 DNA fragment under the control of the strong P. pasloris alcohol oxidase promoter AOXI . Upon induction on methanol, strains of P. pasloris transformed with the recombinant plasmids produced either a native or a fusion MB3 protein, which were reactive with mouse polyclonal antibodies raised against the wild type counterpart. In shaking flask cultures, engineered P. pastoris yielded about 1-3 mg of expressed protein per gram of pelleted wet cells, or 100-600 mg per liter, which corresponded to 10-15% of the yeast cell suspension or about 3-5% of total cellular proteins (Table 4). Full- length MB3 DNA was cloned into each of four Pichia Expression Vectors developed by Invitrogen. To obtain the expression of monomeric, full size 34 kDa MB3 protein, the intracellular pHIL-D2 vector was used. A map of the pHIL-D2 vector may be found on p. 19 of the Invitrogen Instruction Manual for the Pichia Expression Kit, Version E, the contents of which is hereby incorporated by reference. This construct provided maximal expression levels

(up to 3 mg of MB3 per gram of cells) (Tables 3 and 4 ). The expressed product was not secreted, being mainly (95%) insoluble, and it was tightly associated with cell membranes.

To further increase the possibility for the secretion of expressed MB3, three other vectors with different secretion signals were also used: the vector pHIL-S l , which carries a native Pichia pasloris signal sequence from the acid phosphatase gene, PHOI, and the vectors pPIC9 and pPIC9K, which carry the secretion signal from the S. cerevisiae α-mating factor prepro-peptide. Maps of the pHIL-Sl and pPIC9 vectors may be found on pp. 21 -22 of the Invitrogen Instruction Manual for the Pichia Expression Kit, Version E. It was found that the pHIL-Sl/MB3 construct provided the expression of a MB3- PHOI fusion polypeptide with an apparent molecular weight of 36.5 kDa. which was partly processed to generate mature 34 kDa MB3. About 5-10% of expressed MB3 was secreted to the yeast growth medium, and about 40-50% of the 36.5 kDa fusion polypeptide was cleaved (Table 4). Pichia recombinants transformed by pPIC9/MB3 or pPIC9K/MB3 constructs expressed only MB3 fused with α-factor, yielding a fusion polypeptide of approximately 45 kDa. There was no evidence of any cleavage or processing of that fusion protein.

Preliminary studies on the isolation and purification of recombinant MB3 (pHIL-D2/MB3 containing transformants) suggest that when expressed in P pasloris, MB3 may form trimers under native conditions, and that the native protein is resistant to trypsin digestion. These results are similar to those which have been observed for the wild-type counterpart.

An increase in the yield of expressed MB3 may be obtained by using strains oi Pichia which contain multiple copies of the MB3 expression cassette.

Strains harboring multiple copies exist naturally within transformed cell populations at <10% frequency. These strains may be identified either by directly screening large numbers of transformants for levels of MB3 expression via SDS- PAGE or immunoblotting, or indirectly screening by "dot blot" hybridization to select for clones containing multiple copies of the MB3 gene (Cregg et al ,

Bio/Technology 77:905-910 ( 1993)). Alternatively, such multiple integrated clones may be constructed by using a new pAO815 vector (Invitrogen), which allows cloning of multiple copies of the gene of interest via repeated cassette insertion steps (Ibid, at p. 907). Scale-up procedures using a fermenter will provide higher yeast cell densities and therefore improve the yields of the expressed proteins by at least 5-10 times. Optimization of protein expression (i.e., growth media composition, buffering capacity, casamino acids supplementation, increase of methanol concentration, etc.) may be carried out with routine experimentation. Another way to identify Pichia transformants having multiple copies of

MB3 takes advantage of the fact that the Pichia expression vector pPIC9K carries the kanamycin resistance gene which confers resistance to G418; in other respects, pPIC9K corresponds to pPIC9. Spontaneous generation of multiple insertion events can then be identified by the level of resistance to G418. Pichia transformants are selected on histidine-deficient medium and screened for their level of resistance to G418. An increased level of resistance to G418 indicates multiple copies of the kanamycin resistance gene.

Thus, the present invention relates to a method of expressing an outer membrane meningococcal group B porin protein, in particular, the class 2 and class 3 porin proteins. In one embodiment, the present invention relates to a method of expressing the outer membrane meningococcal group B porin protein in E. coli comprising:

(a) transforming E. coli by a vector comprising a selectable marker and a gene coding for a protein selected from the group consisting of:

(i) a mature porin protein, and

(ii) a fusion protein comprising a mature porin protein fused to amino acids 1 to 20 or 22 of the T7 gene φl O capsid protein; wherein said gene is operably linked to the T7 promoter;

(b) growing the transformed E. coli in a culture media containing a selection agent, and

(c) inducing expression of said protein; wherein the protein so produced comprises more than about 2% of the total protein expressed in the E. coli.

In a preferred embodiment, the meningococcal group B porin protein or fusion protein expressed comprises more than about 5% of the total proteins expressed in E. coli. In another preferred embodiment, the meningococcal group B porin protein or fusion protein expressed comprises more than about 10% of the total proteins expressed in E. coli. In yet another preferred embodiment, the meningococcal group B porin protein or fusion protein expressed comprises more than about 30% of the total proteins expressed in E. coli.

Examples of plasmids which contain the T7 inducible promotor include the expression plasmids pET-17b, pET-l la, pET-24a-d(+) and pET-9a, all of which are commercially available from Novagen (565 Science Drive, Madison,

WI 53711). These plasmids comprise, in sequence, a T7 promoter, optionally a lac operator, a ribosome binding site, restriction sites to allow insertion of the structural gene and a T7 terminator sequence. See, the Novagen catalogue, pages 36-43 (1993). In a preferred embodiment, E. coli strain BL21 (DE3) AompA is employed. The above mentioned plasmids may be transformed into this strain or the wild-type strain BL21(DE3). E. coli strain BL21 (DE3) AompA is preferred as no OmpA protein is produced by this strain which might contaminate the purified porin protein and create undesirable immunogenic side effects.

The transformed E. coli are grown in a medium containing a selection agent, e.g. any β-lactam to which E. coli is sensitive such as ampicillin. The pET expression vectors provide selectable markers which confer antibiotic resistance to the transformed organism. High level expression of meningococcal group B porin protein can be toxic in E. coli. Surprisingly, the present invention allows E. coli to express the protein to a level of at least almost 30% and as high as >50% of the total cellular proteins.

In another embodiment, the present invention relates to a method of expressing an outer membrane meningococcal group B porin protein in yeast comprising:

(a) ligating into a plasmid having a selectable marker a gene coding for a protein selected from the group consisting of :

(i) a mature porin protein, and (ii) a fusion protein comprising a mature porin protein fused to a yeast secretion signal peptide; wherein said gene is operably linked to a yeast promoter;

(b) transforming the plasmid containing the gene into a yeast strain;

(c) selecting the transformed yeast by growing said yeast in a culture medium allowing selection of said transformed yeast;

(d) growing the transformed yeast, and

(e) inducing expression of said protein to give yeast containing said protein.

Transformation of the yeast host may be accomplished by any one of several techniques that are well known by those of ordinary skill in the ail. These techniques include direct or liposome-mediated transformation of yeast cells whose cell wall has been partially or completely destroyed to form spheroplasts, treatment of the host with alkali cations and PEG, and freeze-thawing combined with PEG treatment. (See Weber et al , N unconventional Yeasts Their Genetics and Biotechnologwal Applications, CRC Cm Rev Biolechnol 7- 281 , 31 7

(1988) and the references cited therein, all of which are hereby fully incorporated by reference.)

In another preferred embodiment, the mature porin protein or fusion protein expressed comprises more than about 2% of the total protein expressed in the yeast host. In yet another preferred embodiment, the mature porin protein or fusion protein expressed comprises about 3-5% of the total protein expressed in the yeast host

In another preferred embodiment, the mature porin protein is the Neisseria meningitidis mature outer membrane class 3 protein from serogroup B. In another preferred embodiment, the present invention relates to performing the above method of expressing the outer membrane meningococcal group B porin protein or fusion protein in yeast, wherein said yeast is selected from the group consisting of. Saccharomyces cerevisiae, Schizosaccharomyces pom be, Saccharomyces uvarum, Saccharomyces carlsbergensis, Saccharomyces diastaticus, Candida tropicalis, Candida maltosa, Candida parapsilosis, Pichia pasloris, Pichia far inosa, Pichia pinus, Pichia vanrηu, Pichia fermentans, Pichia guilliermondii, Pichia stipilis, Saccharomyces lelluris, Candida ulilis, Candida guilliermondii, Hansenula henricu, Hansenula capsulata, Hansenula polymorpha, Hansenula saturnus, Lypomyces kononenkoae, Kluyveromyces marxianus. Candida lipolytica, Saccaromycopsis fibuhgera, Saccharomycodes ludwigu, Saccharomyces kluyveri, Tremella mesenlerica, Zygosaccharomyces acidofaciens, Zygosaccharomyces fermentali, Yarrowia lipolytica, and Zygosaccharomyces soja Many of these yeast hosts are available from the American Type Culture Collection. Rockville, Md In another preferred embodiment, the nucleotide sequence of the gene encoding the mature porin protein or fusion protein incorporates codons which are optimized for yeast codon usage. In yet another preferred embodiment, the nucleotide sequence of the gene encoding the mature porin protein which has been optimized for yeast codon usage is the nucleotide sequence SEQ ID NO: 26.

In another preferred embodiment, the yeast secretion signal peptide is selected from the group consisting of the secretion signal of the S. cerevisiae a- ating factor prepro-peptide and the secretion signal of the P. pasloris acid phosphatase gene. In another preferred embodiment, the yeast secretes the protein or fusion protein.

In another preferred embodiment, the yeast promoter to which the gene is operably linked is selected from a group consisting of the AOX I promoter, the GAPDH promoter, the PHO5 promoter, the glyceraldehyde-3-phosphate dehydrogenase (TDH3) promoter, the ADHI promoter, the MFαl promoter, and the GAL 10 promoter. Examples of plasmids which contain the AOXI promoter include the expression plasmids pHIL-D2, pHIL-Sl , pPIC9, and pPIC9K. These plasmids comprise, in sequence, an AOXI promoter, restriction sites to allow insertion of the structural gene, an AOXI transcription termination fragment, an open reading frame encoding HIS4 (histidinol dehydrogenase), an ampicillin resistance gene, and a ColEl origin. In addition, plasmids pPIC9 and pPIC9K comprise the α-factor secretion signal of 5. cerevisiae, and plasmid pHIL-S l comprises the PHOI secretion signal of P. pasloris. pPIC9K also includes the kanamycin resistance gene, which confers resistance to G418 in Pichia. The level of G418 resistance in Pichia transformants can be used to identify cells which have undergone multiple insertion events. This occurs at a frequency of 1-10%. An increased level of resistance to G418 indicates the presence of multiple copies of the kanamycin resistance gene and of the gene of interest. See the Novagene catalogue, Version E, pp. 19-22 (1995). In another preferred embodiment, yeast host strains having a mutation in a suitable marker gene which causes the strain to have specific nutritional requirements are employed. Expression plasmids carrying a functional copy of the mutated gene as well as a copy of the meningococcal group B porin protein or fusion protein are then transformed into the yeast host strain, and transformants are selected on the basis of their ability to grow on medium lacking the required nutrient. Examples of suitable marker genes, followed by their S. cerevisiae notation, include the genes encoding imidazole glycerol phosphate dehydrogenase (HIS3), beta-isopropylmalate dehydrogenase (LEU2), tryptophan synthase (TRP5), argininosuccinate lyase (ARG4), N-(5'-phosphorilosyl) anthranilate isomerase (TRP1), histidinol dehydrogenase (HIS4), orotidine-5- phosphate decarboxylase (URA3). dihydroorotate dehydrogenase (URA1), galactokinase (GAL1), and alpha-aminodipate reductase (LYS2). After transformed yeast host cells are selected on the basis of their ability to grow in medium lacking the appropriate nutrient, the cells are screened for integration of the meningococcal group B porin protein or fusion protein at the correct loci. This screening is performed by methods well known to those of ordinary skill in the art, for example, by selecting for transformants which grow slowly on medium which lacks the nutrient used to confirm transformation and includes methanol in order to induce expression of the outer membrane meningococcal group B porin protein or fusion protein from the AOXI promoter. These transformants are then grown up in glycerol-containing medium, and expression of the meningococcal group B porin protein or fusion protein is then induced by the addition of methanol. In a more preferred embodiment. P. pasloris host strains GS 1 15 or KM71 are employed. These strains have a mutation in the histidinol dehydrogenase gene (his4) which prevents them from synthesizing histidine. The expression plasmids pHIL-D2, pHIL-Sl , pPIC9, and pPIC9K carry the HIS4 gene which complements his4 in the host, allowing selection of transformants on histidine- deficient medium. After transformed P. pasloris host cells are selected in histidine-deficient medium, the cells are screened for integration of the meningococcal group B porin protein or fusion protein at the correct loci by selecting for transformants which grow slowly on his^", methano plates. These transformants, which become mutated at the AOXI locus when the MB3 gene inserts into the host genome, are only capable of slow growth on methanol, as they are metabolizing methanol with the less efficient AOX2 gene product. The transformants are then grown up in glycerol-containing medium, and expression of the meningococcal group B porin protein or fusion protein is then induced by the addition of methanol. In a most preferred embodiment, the present invention relates to performing the above method of expressing the outer membrane meningococcal group B porin protein in yeast, wherein said yeast is Pichia pasloris.

In another preferred embodiment, the present invention relates to a vaccine for inducing an immune response in an animal comprising the outer membrane meningococcal group B porin protein or fusion protein thereof, produced according to the above-described methods, together with a pharmaceutically acceptable diluent, carrier, or excipient, wherein the vaccine may be administered in an amount effective to elicit an immune response in an animal to Neisseria meningitidis. In a preferred embodiment, the animal is selected from the group consisting of humans, cattle, pigs, sheep, and chickens.

In another preferred embodiment, the animal is a human.

In another preferred embodiment, the present invention relates to the above-described vaccine, wherein said outer membrane meningococcal group B porin protein or fusion protein thereof is conjugated to a meningococcal group B capsular polysaccharide (CP). Such capsular polysaccharides may be prepared as described in Ashton, F.E. el al, Microbial Palhog. 6:455-458 (1989); Jennings, H.J. et al, J. Immunol. 734:2651 ( 1985); Jennings, H..1. et al, J. Immunol 737:1708-1713 (1986); Jennings, H.J. et al, J. Immunol. 742:3585- 3591 (1989); Jennings, H.J., "Capsular Polysaccharides as Vaccine Candidates," in Current Topics in Microbiology and Immunology, 750: 105-107 ( 1990); the contents of each of which are fully incorporated by reference herein.

The invention also relates to a vaccine capable of simultaneously inducing an immune response against any one of several N meningitidis serogroups. Thus, in another preferred embodiment, the invention relates to a trivalent vaccine comprising the capsular polysaccharides from each of three different serogroups of N. meningitidis. Specifically, the vaccine of the invention comprises group A meningococcal polysaccharide (GAMP), group B meningococcal polysaccharide (GBMP), and group C meningococcal polysaccharide (GCMP) antigens, together with a pharmaceutically acceptable carrier.

In a preferred embodiment, group A meningococcal polysaccharide (GAMP), group B meningococcal polysaccharide (GBMP), and group C meningococcal polysaccharide (GCMP) antigens are each conjugated to a protein carrier, thus yielding GAMP, GCMP and GBMP polysaccharide antigen conjugates.

Of course, it will be understood by those of ordinary skill that a number of carrier proteins will be suitable to be used in the polysaccharide-protein conjugates included in the vaccine of the invention. A suitable carrier protein will be one which is safe for administration to mammals, and which is immunologically effective as a carrier. Safety includes absence of primary toxicity and minimal risk of allergic complications.

In general, any heterologous protein could serve as a carrier antigen. The protein may be, for example, native toxin or detoxified toxin (also termed toxoid). In addition, genetically altered proteins which are antigenically similar to toxins and yet non-toxic may be produced by mutational techniques well-known to those of skill in the art. Such an altered toxin is termed a "cross reacting material," or CRM. CRM|₉₇ is noteworthy, because it differs from native diphtheria toxin at only one amino acid residue, and is immunologically indistinguishable from the native toxin (Anderson, P.W., Infect. Immun. 39:233-238 (1983)). It will be understood by those of skill in the art that the polysaccharide- protein carrier conjugates of the vaccine may be produced by several different methods. The types of covalent bonds which couple a polysaccharide to a protein carrier, and the means of producing them, are well known to those of skill in the art. Details concerning the chemical means by which the two moieties can be linked may be found in U.S. Patent No. 5,371 ,197, and 4,902,506, the contents of which are herein incorporated by reference in their entirety. One such method is the reductive amination process described in Schwartz and Gray (Arch. Biochim. Biophys. 757:542-549 (1977)). This process involves reacting the reducing capsular polysaccharide fragment and bacterial toxin or toxoid in the presence of cyanoborohydride ions, or another reducing agent. Such a process will not adversely affect the toxin or toxoid or the capsular polysaccharide (U.S. Patent No. 4,902,506). Such a conjugation process is also described in Examples 12-14, below. While tetanus and diphtheria toxins are the prime candidates for carrier proteins, owing to their history of safety, there may be overwhelming reasons, well known to those of ordinary skill in the art. to use another protein. For example, another protein may be more effective as a carrier, or production economics may be significant. Other candidates include toxins or toxoids of pseudomonas, staphylococcus, streptococcus, pertussis and entertoxi genie bacteria, including Escherichia coli. A preferred carrier protein to which the group B meningococcal polysaccharide may be conjugated is the class 3 porin protein (PorB) of group B TV. meningitidis. A preferred protein carrier protein to which GAMP antigen and GCMP antigen may be conjugated is tetanus toxoid.

It is known in the art that the immunogenicity of GBMP is limited in humans, and especially in infant humans, and that direct covalent couplings of the group B polysaccharide to tetanus toxoid yielded a conjugate which failed to induce a significant polysaccharide-specific response in either rabbits (Jennings, H.J. and Lugowski, C., J. Immunol. 727: 101 1 -1018 (1981 )) or mice (Jennings. H J. et al , J Immunol 737:1708-1713 (1986)). This failure prompted interest in the direct chemical modification of the group B polysaccharide. This was done with the idea of creating synthetic epitopes capable of modulating the immune response in such a way as to produce enhanced levels of cross-reactive B polysaccharide-specific antibodies (Jennings, H.J et al , J Immunol 737: 1708-

1713 (1986)).

It will be understood by those of ordinary skill in the art that in selecting possible chemical modifications of the group B polysaccharide (Jennings, H J et al , J Immunol 737:1708-1713 (1986)), two factors should be considered First, the chemical modification should be able to be accomplished with facility and with the minimum of degradation of the polysaccharide Second, in order to produce cross-reactive B polysaccharide-specific antibodies, the antigenicity of the modified polysaccharide to B polysaccharide-specific antibodies should be preserved. It will be understood by those of skill in the art that the ideal chemical modification of group B polysaccharide will retain both the carboxylate and the

N-carbonyl groups (Jennings, H.J et al , J Immunol 137 1 708-171 ( 1986)) The most preferred modification which satisfies the above criteria is a modification wherein the N-acetyl groups of the sialic acid residues of the B polysaccharide are removed by strong base and replaced by N-propionyl groups (see Examples 6 and 14).

In a more preferred embodiment, the N-propionylated GBMP is subsequently conjugated to a carrier protein While any carrier protein which enhances the immunogenicity of N-propionylated GBMP may be used, a preferred protein carrier is the class 3 outer membrane protein of group B N meningitidis (MB3, or PorB).

Thus, in still another preferred embodiment, GBMP antigen is conjugated to PorB after having been N-propionylated.

Preferably, the capsular polysaccharide (CP), which may be group A, B or C meningococcal polysaccharide. is isolated according to Frasch, C E., "Production and Control of Neisseria meningitidis Vaccines" in Bacterial Vaccines, Alan R. Liss, Inc., pages 123-145 (1990), the contents of which are fully incorporated by reference herein, as follows:

Grow organisms in modified Franz medium 10 to 20 hrs 1 Heat kill, 55°C, 10 min Remove inactivated cells by centrifugation

1 Add Cetavlon to O.1% Precipitate CP from culture broth

1 Add calcium chloride to 1 M Dissolve CP then centrifuge to remove cellular debris 1 Add ethyl alcohol to 25%

Remove precipitated nucleic acids by centrifugation

1 Add ethyl alcohol to 80% Precipitate crude CP and remove alcohol

The crude CP is then further purified by gel filtration chromatography after partial depolymerization with dilute acid, e.g. acetic acid, formic acid, and trifluoroacetic acid (0.01-0.5 N), to give a mixture of polysaccharides having an average molecular weight of 10,000-20,000. Where the CP is GBMP, purified GBMP is then N-deacetylated with NaOH in the presence of sodium borohydride and N-propionylated to afford N-Pr GBMP. Thus, the CP that may be employed in the conjugate vaccines of the present invention may be CP fragments, N- deacylated CP and fragments thereof, as well as N-Pr CP and fragments thereof, so long as they induce active immunity when employed as part of a CP-porin protein conjugate (see Examples 6 and 14).

In a further preferred embodiment, the present invention relates to a method of preparing a polysaccharide conjugate comprising: obtaining the above-described outer membrane meningococcal group B porin protein or fusion protein thereof; obtaining a CP from a Neisseria meningitidis organism; and conjugating the protein to the CP. The conjugates of the invention may be formed by reacting the reducing end groups of the CP to primary amino groups of the porin by reductive amination. The reducing groups may be formed by selective hydrolysis or specific oxidative cleavage, or a combination of both. Preferably, the CP is conjugated to the porin protein by the method of Jennings et al, U.S. Patent No.

4,356,170, the contents of which are fully incorporated by reference herein, which involves controlled oxidation of the CP with periodate followed by reductive amination with the porin protein.

The vaccine of the present invention comprises the meningococcal group B porin protein, fusion protein or conjugate vaccine, or the trivalent GAMP.

GBMP and GCMP vaccine, in an amount effective depending on the route of administration. Although subcutaneous or intramuscular routes of administration are preferred, the meningococcal group B porin protein, fusion protein or vaccine of the present invention can also be administered by an intraperitoneal or intravenous route. One skilled in the art will appreciate that the amounts to be administered for any particular treatment protocol can be readily determined without undue experimentation. Suitable amounts might be expected to fall within the range of 2 micrograms of the protein per kg body weight to 100 micrograms per kg body weight. Thus, in a preferred embodiment, the vaccine comprises about 2 μg of the

GAMP, GCMP and GBMP polysaccharide antigen conjugates.

In another preferred embodiment, the vaccine comprises about 5 μg of the GAMP, GCMP and GBMP polysaccharide antigen conjugates.

In yet another referred embodiment, the vaccine comprises about 2 μg of the GAMP and GCMP polysaccharide antigen conjugates, and about 5 μg of the

GBMP polysaccharide antigen conjugate.

The vaccine of the present invention may be employed in such forms as capsules, liquid solutions, suspensions or elixirs for oral administration, or sterile liquid forms such as solutions or suspensions. Any inert carrier is preferably used, such as saline, phosphate-buffered saline, or any such carrier in which the meningococcal group B porin protein, fusion protein or conjugate vaccine have suitable solubility properties. The vaccines may be in the form of single dose preparations or in multi-dose flasks which can be used for mass vaccination programs. Reference is made to Remington's Pharmaceutical Sciences, Mack Publishing Co., Easton, PA, Osol (ed.) (1980); and New Trends and

Developments in Vaccines, Voller et al. (eds.), University Park Press, Baltimore, MD (1978), for methods of preparing and using vaccines.

The vaccines of the present invention may further comprise adjuvants which enhance production of porin-specific antibodies. Such adjuvants include, but are not limited to, various oil formulations such as Freund's complete adjuvant (CFA), stearyl tyrosine (ST, see U.S. Patent No. 4,258,029), the dipeptide known as MDP, saponin, aluminum hydroxide, and lymphatic cytokine.

Freund's adjuvant is an emulsion of mineral oil and water which is mixed with the immunogenic substance. Although Freund's adjuvant is powerful, it is usually not administered to humans. Instead, the adjuvant alum (aluminum hydroxide) or ST may be used for administration to a human. The meningococcal group B porin protein or a conjugate vaccine thereof may be absorbed onto the aluminum hydroxide from which it is slowly released after injection. The meningococcal group B porin protein or group A, B and C meningococcal polysaccharide conjugate vaccine may also be encapsulated within liposomes according to Fullerton, U.S. Patent No. 4,235,877.

In another preferred embodiment, the present invention relates to a method of inducing an immune response in an animal comprising administering to the animal the vaccine of the invention, produced according to methods described, in an amount effective to induce an immune response.

In a further embodiment, the invention relates to a method of purifying the above-described outer membrane meningococcal group B porin protein or fusion protein comprising: lysing the transformed E. coli to release the meningococcal group B porin protein or fusion protein as part of insoluble inclusion bodies; washing the inclusion bodies with a buffer to remove contaminating E. coli cellular proteins; resuspending and dissolving the inclusion bodies in an aqueous solution of a denaturant; diluting the resultant solution in a detergent; and purifying the solubilized meningococcal group B porin protein by gel filtration. The lysing step may be carried out according to any method known to those of ordinary skill in the art, e.g. by sonication, enzyme digestion, osmotic shock, or by passing through a mull press.

The inclusion bodies may be washed with any buffer which is capable of solubilizing the E. coli cellular proteins without solubilizing the inclusion bodies comprising the meningococcal group B porin protein. Such buffers include but are not limited to TEN buffer (50 mM Tris HCl, 1 mM EDTA. 100 mM NaCl, pH

8.0), Tricine, Bicine and HEPES.

Denaturants which may be used in the practice of the invention include 2 to 8 M urea or about 2 to 6 M guanidine HCl, more preferably, 4 to 8 M urea or about 4 to 6 M guanidine HCl, and most preferably, about 8 M urea or about

6 M guanidine HCl.

Examples of detergents which can be used to dilute the solubilized meningococcal group B porin protein include, but are not limited to, ionic detergents such as SDS and cetavlon (Calbiochem); non-ionic detergents such as Tween, Triton X, Brij 35 and octyl glucoside; and zwitterionic detergents such as 3,14-Zwittergent, empigen BB and Champs.

Finally, the solubilized outer membrane meningococcal group B porin protein may be purified by gel filtration to separate the high and low molecular weight materials. Types of filtration gels include but are not limited to Sephacryl-300, Sepharose CL-6B, and Bio-Gel A-l .5m. The column is eluted with the buffer used to dilute the solubilized protein. The fractions containing the porin or fusion thereof may then be identified by gel electrophoresis, the fractions pooled, dialyzed, and concentrated. Finally, substantially pure (>95%) porin protein and fusion protein may be obtained by passing the concentrated fractions through a Q sepharose high performance column.

In another embodiment, the present invention relates to expression of the meningococcal group B porin protein gene which is part of a vector which comprises the T7 promoter, which is inducible. If a promoter is an inducible promoter, then the rate of transcription increases in response to an inducing agent. The T7 promoter is inducible by the addition of isopropyl β-D- thiogalactopyranoside (IPTG) to the culture medium. Alternatively, the Tac promotor or heat shock promotor may be employed. Preferably, the meningococcal group B porin protein gene is expressed from the pET-17 expression vector or the pET-1 la expression vector, both of which contain the T7 promoter.

The cloning of the meningococcal group B porin protein gene or fusion gene into an expression vector may be carried out in accordance with conventional techniques, including blunt-ended or stagger-ended termini for ligation, restriction enzyme digestion to provide appropriate termini, filling in of cohesive ends as appropriate, alkaline phosphatase treatment to avoid undesirable joining, and ligation with appropriate ligases. Reference is made to Sambrook el al, Molecular Cloning: A Laboratory Manual, 2nd ed., Cold Spring Harbor,

New York, Cold Spring Harbor Laboratory Press ( 1989), for general methods of cloning.

The meningococcal group B porin protein and fusion protein expressed according to the present invention must be properly refolded in order to achieve a structure which is immunologically characteristic of the native protein. In yet another embodiment, the present invention relates to a method of refolding the above-described outer membrane protein and fusion protein comprising: lysing the transformed cells to release the meningococcal group B porin protein or fusion protein as part of insoluble inclusion bodies; washing the inclusion bodies with a buffer to remove contaminating cellular proteins: resuspending and dissolving the inclusion bodies in an aqueous solution of a denaturant; diluting the resultant solution in a detergent; and purifying the solubilized meningococcal group B porin protein or fusion protein by gel filtration to give the refolded protein in the eluant. Surprisingly, it has been discovered that the folded trimeric meningococcal group B class 2 and class 3 porin proteins and fusion proteins are obtained directly in the eluant from the gel filtration column.

In another preferred embodiment, the present invention relates to a substantially pure refolded outer membrane meningococcal group B porin protein and fusion protein produced according to the above-described methods. A substantially pure protein is a protein that is generally lacking in other cellular

Neisseria meningitidis components as evidenced by, for example, electrophoresis. Such substantially pure proteins have a purity of >95%, as measured by densitometry on an electrophoretic gel after staining with Coomassie blue or silver stains. The following examples are illustrative, but not limiting, of the method and compositions of the present invention. Other suitable modifications and adaptations of the variety of conditions and parameters normally encountered in this art which are obvious to those skilled in the art are within the spirit and scope of the present invention.

Examples

Example 1. Cloning of the Class 3 Porin Protein from Group B Neisseria meningitidis

Materials and Methods

Organisms: The Group B Neisseria meningitidis strain 8765 (B: 15:P1 ,3) was obtained from Dr. Wendell Zol linger (Walter Reed Army Institute for

Research) and grown on agar media previously described (Swanson, J.L., Infect Immun. 27:292-302 (1978)) in a candle extinction jar in an incubator maintained at 30°C. Escherichia coli strains DME558 (from the collection of S. Benson; Silhavy, T.J. et al, "Experiments with Gene Fusions," Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y., 1984), BRE51 (Bremer, E. et al, FEMS Microbiol. Lett 33: 173-178 (1986)) and BL21 (DE3) were grown on LB agar plates at 37°C.

PI Transduction: A PI,,,,, lysate of E. coli strain DME558 was used to transduce a tetracycline resistance marker to strain BRE51 (Bremer, E., et al, FEMS Microbiol. Lett. 33: 173-178 (1986)) in which the entire ompA gene had been deleted (Silhavy, T.J., et al , Experiments with Gene Fusions, Cold Spring

Harbor Laboratory, Cold Spring Harbor, NY ( 1984)). Strain DME558, containing the tetracycline resistance marker in close proximity of the ompA gene, was grown in LB medium until it reached a density of approximately 0.6 OD at 600 nm. One tenth of a milliliter of 0.5 M CaCL was added to the 10 ml culture and 0.1 ml of a solution containing 1 x 10⁹ PFU of Pl _17r. The culture was incubated for 3 hours at 37°C. After this time, the bacterial cell density was visibly reduced. 0.5 ml of chloroform was added and the phage culture stored at 4°C. Because typically 1-2% of the E. coli chromosome can be packaged in each phage, the number of phage generated covers the entire bacterial host chromosome, including the tetracycline resistance marker close to the ompA gene.

Next, strain BRE51 , which lacks the ompA gene, was grown in LB medium overnight at 37°C. The overnight culture was diluted 1 :50 into fresh LB and grown for 2 hr. The cells were removed by centrifugation and resuspended in MC salts. 0.1 ml of the bacterial cells were mixed with 0.05 of the phage lysate described above and incubated for 20 min. at room temperature. Thereafter, an equal volume of 1 M sodium citrate was added and the bacterial cells were plated out onto LB plates containing 12.5 μg/ml of tetracycline. The plates were incubated overnight at 37°C. Tetracycline resistant ( 12 μg/ml) transductants were screened for lack of OmpA protein expression by SDS-PAGE and Western Blot analysis, as described below. The bacteria resistant to the antibiotic have the tetracycline resistance gene integrated into the chromosome very near where the ompA gene had been deleted from this strain. One particular strain was designated BRE-T^R. A second round of phage production was then carried out with the strain

BRE-T^R, using the same method as described above. Representatives of this phage population contain both the tetracycline resistance gene and the OmpA deletion. These phage were then collected and stored. These phage were then used to infect E. coli BL21(DE3). After infection, the bacteria contain the tetracycline resistance marker. In addition, there is a high probability that the

OmpA deletion was selected on the LB plates containing tetracycline.

Colonies of bacteria which grew on the plates were grown up separately in LB medium and tested for the presence of the OmpA protein. Of those colonies selected for examination, all lacked the OmpA protein as judged by antibody reactivity on SDS-PAGE western blots.

SDS-PAGE and Western Blot: The SDS-PAGE was a variation of Laemmli's method (Laemmli, U.K., Nature 227:680-685 (1970)) as described previously (Blake and Gotschlich, J. Exp. Med. 759:452-462 (1984)). Electrophoretic transfer to Immobilon P (Millipore Corp. Bedford, MA) was performed according to the methods of Towbin et al. (Towbin, H.. et al, Proc.

Natl. Acad. Sci. USA 76:4350-4354 (1979)) with the exception that the paper was first wetted in methanol. The Western blots were probed with phosphatase conjugated reagents (Blake, M.S., et al. , Analyl. Biochem. 136: 175- 179 ( 1984)).

Polymerase Chain Reaction: The method described by Feavers et al. (Feavers, I.M., et l, Infect. Immun. 60:3620-3629 (1992)) was used to amplify the gene encoding the PorB. The primers selected were primers 33 (GGG GTA GAT CTG CAG GTT ACC TTG TAC GGT ACA ATT AAA GCA GGC GT) and 34 (GGG GGG GTG ACC CTC GAG TTA GAA TTT GTG ACG CAG ACC AAC) as previously described (Feavers, I.M., el al, lnfecl. Immun 60:3620-3629 ( 1992)). Briefly, the reaction components were as follows: Meningococcal strain 8765 chromosomal DNA (100 ng/μl), 1 μl; 5' and 3 ' primers (1 μM) 2 μl each; dNTP (10 mM stocks), 4 μl each; 10 X PCR reaction buffer (100 mM Tris HCl, 500 mM KC1, pH 8.3), 10 μl; 25 mM MgCl₂, 6 μl; double distilled H₂0, 62 μl; and Taq polymerase (Cetus Corp., 5 u/μl), 1 μl. The reaction was carried out in a GTC-2 Genetic Thermocycler (Precision Inst. Inc,

Chicago, IL) connected to a Lauda 4/K methanol/water cooling system (Brinkman Instruments, Inc., Westbury, NY) set at 0°C. The thermocycler was programmed to cycle 30 times through: 94°C, 2 min.; 40°C, 2 min.; and 72°C, 3 min. At the end of these 30 cycles, the reaction was extended at 72°C for 3 min and finally held at 4°C until readied for analysis on a 1 % agarose gel in TAE buffer as described by Maniatis (Maniatis, T., et al, Molecular Cloning, A Laboratory Manual, Cold Spring Harbor Laboratory, Cold Spring Harbor, NY (1982)).

Subcloning of the PCR product: The pET-17b plasmid (Novagen, Inc.) was used for subcloning and was prepared by double digesting the plasmid with the restriction endonucleases BamWλ and Xhol (New England Biolabs, Inc., Beverly, MA). The digested ends were then dephosphorylated with calf intestinal alkaline phosphatase (Boehringer Mannheim, Indianapolis. IN). The digested plasmid was then analyzed on a 1 % agarose gel, the cut plasmid removed, and purified using the GeneClean kit (BiolOl , La Jolla, CA). The PCR product was prepared by extraction with phenol-chloroform, chloroform, and finally purified using the GeneClean Kit (BiolOl ). The PCR product was digested with restriction endonucleases Bgl l and Λ7røl (New England Biolabs, Inc.). The DNA was then extracted with phenol-chloroform, precipitated by adding 0.1 volumes of 3 M sodium acetate, 5 μl glycogen (20 μg/μl), and 2.5 volumes of ethanol. After washing the DNA with 70% ethanol (vol/vol). it was redissolved in TE buffer. The digested PCR product was ligated to the double digested pET- 17b plasmid described above using the standard T4 ligase procedure at 16°C overnight (Current Protocols in Molecular Biology, John Wiley & Sons, New York (1993)). The ligation product was then transformed into the BL21 (DE3)- AompA described above which were made competent by the method of Chung et al. (Chung, C.T., et al. , Proc. Natl. Acad. Sci. USA 56:2172-2175 ( 1989)). The transformants were selected on LB plates containing 50 μg/ml carbenicillin and 12μg/ml tetracycline. Several transformants were selected, cultured in LB both containing carbenicillin and tetracycline for 6 hours at 30 °C. and plasmid gene expression inducted by the addition of IPTG. The temperature was raised to 37°C and the cultures continued for an additional 2 hrs. The cells of each culture were collected by centrifugation, whole cell lysates prepared, and analyzed by SDS-PAGE and Western Blot using a monoclonal antibody (4D1 1 ) which reacts with all neisserial porins.

Nucleotide Sequence Analysis: The nucleotide sequences of the cloned Class 3 porin gene DNA were determined by the dideoxy method using denatured double-stranded plasmid DNA as the template as described (Current Protocols in Molecular Biology, John Wiley & Sons, New York (1993)). Sequenase II kits (United States Biochemical Corp., Cleveland, OH) were used in accordance with the manufacturer's instructions. The three synthesized oligonucleotide primers (Operon Technologies, Inc., Alameda, CA) were used for these reactions. One for the 5' end, which consisted of 5'TCAAGCTTGGTACCGAGCTC and two for the 3' end, 5'TTTGTTAGCAGCCGGATCTG and 5' CTCAAGACCCGTTTAGAGGCC. Overlapping, nested deletions were made by linearizing the plasmid DNA by restriction endonuclease Bpu\ 1021 and the ends blunted by the addition of Thio-dNTP and Klenow polymerase (Current Protocols in Molecular Biology, John Wiley & Sons, New York ( 1993)). The linearized plasmid was then cleaved with restriction endonuclease Xhol and the exoII/Mung bean nuclease deletion kit used to make 3' deletions of the plasmid

(Stratagene. Inc., La Jolla, CA) as instructed by the supplier. A map of this strategy is shown in Figure 1.

Expression and purification of the PorB gene product: Using a sterile micropipette tip, a single colony of the BL21 (OΕ3)- ompA containing the PorB- pET-17b plasmid was selected and inoculated into 10 ml of LB broth containing 50 μg/ml carbenicillin. The culture was incubated overnight at 30°C while shaking. The 10 ml overnight culture was then sterilely added to 1 liter of LB broth with the same concentration of carbenicillin, and the culture continued in a shaking incubator at 37°C until the OD_6(K) reached 0.6-1.0. Three mis of a stock solution of IPTG ( 100 mM) was added to the culture and the culture incubated for an additional 30 min. Rifampicin was then added (5.88 ml of a stock solution; 34 mg/ l in methanol) and the culture continued for an additional 2 hrs. The cells were harvested by centrifugation at 10,000 rpm in a GS3 rotor for 10 min and weighed. The cells were thoroughly resuspe ded in 3 ml of TEN buffer (50 mM Tris HCl, 1 mM Tris HCl, 1 mM EDTA. 100 mM NaCl, pH 8.0) per gram wet weight of cells. To this was added 8 μl of PMSF stock solution (50 mM in anhydrous ethanol) and 80 μl of a lysozyme stock solution (10 mg/ml in water) per gram wet weight of cells. This mixture was stirred at room temperature for 20 min. While stirring, 4 mg per gram wet weight of cells of deoxycholate was added. The mixture was placed in a 37°C water bath and stirred with a glass rod.

When the mixture became viscous, 20 μl of DNase I stock solution ( 1 mg/ml) was added per gram weight wet cells. The mixture was then removed from the water bath and left at room temperature until the solution was no longer viscous. The mixture was then centrifuged at 15,000 rpm in a SS-34 rotor for 20 min at 4°C. The pellet was retained and thoroughly washed twice with TEN buffer.

The pellet was then resuspended in freshly prepared TEN buffer containing 0.1 mM PMSF and 8 M urea and sonicated in a bath sonicator (Heat Systems, Inc., Plain view. NY). The protein concentration was determined using a BCA kit (Pierce, Rockville, IL) and the protein concentration adjusted to less than 10 mg/ml using the TEN-urea buffer. The sample was then diluted 1 : 1 with 10%

(weight/vol) Zwittergent 3,14 (Calbiochem, La Jolla, CA), sonicated, and loaded onto a Sephacryl S-300 molecular sieve column. The Sephacryl S-300 column (2.5 cm x 200 cm) had previously equilibrated with 100 mM Tris HCl, 200 mM NaCl, 10 mM EDTA, 0.05% Zwittergent 3.14, and 0.02% azide. pH 8.0. The column flow rate was adjusted to 8 ml/hr and 10 ml fractions were collected. The OD_2g0 of each fraction was measured and SDS-PAGE analysis performed on protein containing fractions.

Inhibition ELISA Assays: Microtiter plates (Nunc-Immuno Plate IIF, Nunc, Inc., Naperville, IL) were sensitized by adding 0.1 ml per well of porB (2 μg/ml) purified from the wild type strain 8765, in 0.1 M carbonate buffer, pH 9.6 with 0.02% azide. The plates were incubated overnight at room temperature. The plates were washed five times with 0.9% NaCl, 0.05% Brij 35, 10 M sodium acetate pH 7.0, 0.02% azide. Human immune sera raised against the Type 15 Class 3 PorB protein was obtained from Dr. Phillip O. Livingston, Memorial-Sloan Kettering Cancer Center, New York, N.Y. The human immune sera was diluted in PBS with 0.5% Brij 35 and added to the plate and incubated for 2 hr at room temperature. The plates were again washed as before and the secondary antibody, alkaline phosphatase conjugated goat anti-human IgG (Tago Inc., Burlingame, CA), was diluted in PBS-Brij, added to the plates and incubated for 1 hr at room temperature. The plates were washed as before and

/7-nitrophenyl phosphate (Sigma Phosphatase Substrate 104) (1 mg/ml) in 0.1 diethanolamine, 1 mM MgCL, 0.1 M ZnCL, 0.02% azide, pH 9.8, was added. The plates were incubated at 37 °C for 1 h and the absorbance at 405 nm determined using an Elida-5 microtiter plate reader (Physica. New York, NY). Control wells lacked either the primary and/or secondary antibody. This was done to obtain a titer for each human serum which would give a half-maximal reading in the ELISA assay. This titer for each human serum would be used in the inhibition ELISA. The ELISA microtiter plate would be sensitized with purified wild type PorB protein and washed as before. In a separate V-96 polypropylene microtiter plate (Nunc, Inc.). varying amounts of either purified wild type PorB protein or the purified recombinant PorB protein were added in a total volume of 75 μl. The human sera were diluted in PBS-Brij solution to twice their half maximal titer and 75 μl added to each of the wells containing the PorB or recombinant PorB proteins. This plate was incubated for 2 hr at room temperature and centrifuged in a Sorvall RT6000 refrigerated centrifuge, equipped with microtiter plate carriers (Wilmington, DE) at 3000 rpm for 10 min. Avoiding the V-bottom, 100 μl from each well was removed and transferred to the sensitized and washed ELISA microtiter plate. The ELISA plates are incubated for an additional 2 hr, washed, and the conjugated second antibody added as before. The plate is then processed and read as described. The percentage of inhibition is then processed and read as described. The percentage of inhibition is calculated as follows:

1 - (ELISA value with either PorB or rPorB protein added) (ELISA value without the porB added)

Results

Polymerase Chain Reaction and Subcloning: A method to easily clone, genetically manipulate, and eventually obtain enough pure porin protein from any number of different neisserial porin genes for further antigenic and biophysical characterization has been developed. The first step toward this goal was cloning the porin gene from a Neisseria. Using a technique originally described by

Feavers, et al. (Feavers, I.M., el al. Infect Immun. 60:3620-3629 (1992)), the DNA sequence of the mature porin protein from a class 3, serotype 15 porin was amplified using the chromosome of meningococcal strain 8765 as a template for the PCR reaction. Appropriate endonuclease restriction sites had been synthesized onto the ends of the oligonucleotide primers, such that when cleaved, the amplified mature porin sequence could be directly ligated and cloned into the chosen expression plasmid. After 30 cycles, the PCR products shown in Figure

2 were obtained. The major product migrated between 900bp and 1 OOObp which was in accord with the previous study (Feavers, I.M., et al, Infect. Immun

60:3620-3629 (1992)). However, a higher molecular weight product was not seen, even though the PCR was conducted under low annealing stringencies (40°C; 50 mM KCl).

To be able to produce large amounts of the cloned porin protein, the tightly controlled expression system of Studier, et al. (Studier and Moffatt, J. Mol. Biol. 759: 1 13-130 (1986)) was employed, which is commercially available through Novagen Inc. The amplified PCR product was cloned into the BamHl- Xhol site of plasmid pET-17b. This strategy places the DNA sequence for the mature porin protein in frame directly behind the T7 promoter, the DNA sequence encoding for the 9 amino acid leader sequence and 1 1 amino acids of the mature φl O protein. The Studier E. coli strain BL21 lysogenic for the DE3 lambda derivative (Studier and Moffatt, J. Mol. Biol. 189: 1 13- 130 ( 1986)) was selected as the expression host for the pET-17b plasmid containing the porin gene. But because it was thought that the OmpA protein, originating from the E. coli expression host, might tend to co-purify with the expressed meningococcal porin protein, a modification of this strain was made by PI transduction which eliminated the ompA gene from this strain. Thus, after restriction endonuclease digestion of both the PCR product and the pET-17b vector and ligation, the product was transformed into BL21(DE3)-Δo/77/?A and transformants selected for ampicillin and tetracycline resistance. The restriction map of pET-17b is shown in Figure 1 1 A, while the nucleotide sequence between the Bglll and Xhol sites of pET-17b is shown in Figure 1 IB. Of the numerous colonies observed on the selection plate, 10 were picked for further characterization. All ten expressed large amounts of a protein, which migrated at the approximate molecular weight of the PorB protein, when grown to log phase and induced with IPTG. The whole cell lysate of one such culture is shown in Figure 3a. The western blot analysis with the 4D1 1 monoclonal antibody further suggested that the protein being expressed was the PorB protein (Figure 3b). As opposed to other studies, when neisserial porins have been cloned and expressed in E. coli, the host bacterial cells showed no signs of any toxic or lethal effects even after the addition of the IPTG. The E. coli cells appeared viable and could be recultured at any time throughout the expression phase.

Nucleotide sequence analysis: The amount of PorB expressed in these experiments was significantly greater than that previously observed and there appeared to be no adverse effects of this expression on the host £. coli. To be certain that no PCR artifacts had been introduced into the meningococcal porin gene to allow for such high expression, the entire φl O porin fusion was sequenced by double stranded primer extension from the plasmid. The results are shown in Figure 4. The nucleotide sequence was identical with another meningococcal serotype 15 PorB gene sequence previously reported by Heckels, et al. (Ward, M.J., el al, FEMS Microbiol Lett. 73:283-289 (1 92)) with two exceptions which are shown. These two nucleotide differences each occur in the third position of the codon and would not alter the amino acid sequence of the expressed protein. Thus, from the nucleotide sequence, there did not appear to be any PCR artifact or mutation which might account for the high protein expression and lack of toxicity within the E. coli. Furthermore, this data would suggest that a true PorB protein was being produced.

Purification of the expressed porB gene product: The PorB protein expressed in the E. coli was insoluble in TEN buffer which suggested that when expressed, the PorB protein formed into inclusion bodies. However, washing of the insoluble PorB protein with TEN buffer removed most of the contaminating E. coli proteins. The PorB protein could then be solubilized in freshly prepared 8M urea and diluted into the Zwittergent 3,14 detergent. The final purification was accomplished, using a Sephacryl S-300 molecular sieve column which not only removed the urea but also the remaining contaminating proteins. The majority of the PorB protein eluted from the column having the apparent molecular weight of trimers much like the wild type PorB. The comparative elution patterns of both the wild type and the PorB expressed in the E. coli are shown in Figure 5. It is important to note that when the PorB protein concentration in the 8 M urea was in excess of 10 mg/ml prior to dilution into the Zwittergent detergent, the relative amounts of PorB protein found as trimers decreased and appeared as aggregates eluting at the void volume. However, at protein concentrations below 10 mg/ml in the urea buffer, the majority of the PorB eluted in the exact same fraction as did the wild type PorB. It was also determined using a T7-Tag monoclonal antibody and western blot analysis that the 1 1 amino acids of the mature T7 capsid protein were retained as the amino terminus. The total yield of the meningococcal porin protein from one liter of E. coli was approximately 50 mg.

Inhibition ELISA Assays. In order to determine if the purified trimeric recombinant PorB had a similar antigenic conformation as compared to the PorB produced in the wild type meningococcal strain 8765, the sera from six patients which had been vaccinated with the wild type meningococcal Type 15 PorB protein were used in inhibition ELISA assays. In the inhibition assay, antibodies reactive to the native PorB were competitively inhibited with various amounts of either the purified recombinant PorB or the homologous purified wild type PorB.

The results of the inhibition with the homologous purified PorB of each of the six human sera and the mean inhibition of these sera are shown in Figure 6. The corresponding inhibition of these sera with the purified recombinant PorB is seen in Figure 6B. A comparison of the mean inhibition from Figure 6 and 7 are plotted in Figure 8. These data would suggest that the antibodies contained in the sera of these six patients found similar epitopes on both the homologous purified wild type PorB and the purified recombinant PorB. This gave further evidence that the recombinant PorB had regained most if not all of the native conformation found in the wild type PorB. Example 2. Cloning of the Class 2 Porin from Group B Neisseria Meningitidis strain BNCV M986

Genomic DNA was isolated from approximately 0.5g of Group B Neisseria meningitidis strain BNCV M986 (serotype 2a) using previously described methods (Sambrook el al, Molecular Cloning: A Laboratory Manual,

2nd ed., Cold Spring Harbor, New York, Cold Spring Harbor Laboratory Press (1989)). This DNA then served as the template for two class 2 porin specific oligonucleotides in a standard PCR reaction. These oligonucleotides were designed to be complementary to the 5' and 3' flanking regions of the class 2 porin and to contain £coRI restriction sites to facilitate the cloning of the fragment. The sequences of the oligonucleotides were as follows: 5' AGC GGC TTG GAA TTC CCG GCT GGC TTA AAT TTC 3' and 5' CAA ACG AAT GAA TTC AAA TAA AAA AGC CTG 3'. The polymerase chain reaction was then utilized to obtain the class 2 porin. The reaction conditions were as follows: BNCV M986 genomic DNA 200ng, the two oligonucleotide primers described above at 1 μM of each, 200 μM of each dNTP, PCR reaction buffer (10 mM Tris HCl, 50 mM KC1, pH 8.3), 1.5 mM MgCL, and 2.5 units of Taq polymerase. made up to 100 μl with distilled H 0. This reaction mixture was then subjected to 25 cycles of 95° C for 1 min. 50° C for 2 min and 72 °C for 1.5 min. At the end of the cycling period, the reaction mixture was loaded on a 1% agarose gel and the material was electrophoresed for 2h after which the band at 1.3 kb was removed and the DNA recovered using the Gene Clean kit (Bio 101 ). This DNA was then digested with EcoRl, repurified and ligated to EcoRl digested pUC 19 using T DNA ligase. The ligation mixture was used lo transform competent E. coli DH5α. Recombinant plasmids were selected and sequenced. The insert was found to have a DNA sequence consistent with that of a class 2 porin. See, Murakami, K. et al, Infect. Immun. 57:2318-2323 (1989). The plasmid pET-17b (Novagen) was used to express the class 2 porin.

As described below, two plasmids were constructed that yielded two different proteins. One plasmid was designed to produce a mature class 2 porin while the other was designed to yield a class 2 porin fused to 20 amino acids from the T7 gene φl O capsid protein.

Construction of the mature class 2 porin

The mature class 2 porin was constructed by amplifying the pUCl 9-class 2 porin construct using the oligonucleotides: 5'-CCT GTT GCA GCA CAT ATG GAC GTT ACC TTG TAC GGT ACA ATT AAA GC-3' and 5 '-CGA CAG GCT TTT TCT CGA GAC CAA TCT TTT CAG -3'. This strategy allowed the cloning of the amplified class 2 porin into the Nde\ and Xhol sites of the plasmid pET-17b thus producing a mature class 2 porin. Standard PCR was conducted using the pUCl 9-class 2 as the template and the two oligonucleotides described above. This PCR reaction yielded a 1.1 kb product when analyzed on a 1.0% agarose gel. The DNA obtained from the PCR reaction was gel purified and digested with the restriction enzymes TVt el and Xliol. The 1 .1 kb DNA produced was again gel purified and ligated to Nd and Λ7?ol digested pET-17b using T., DNA ligase. This ligation mixture was then used to transform competent E. coli DH5α. Colonies that contained the 1.lkb insert were chosen for further analysis. The DNA from the DH5α clones was analyzed by restriction mapping and the cloning junctions of the chosen plasmids were sequenced. After this analysis, the DNA obtained from the DH5α clones was used to transform E. coli BL21(DE3)- Ao pA. The transformants were selected to LB-agar containing 100 μg/ml of carbenicillin. Several transformants were screened for their ability to make the class 2 porin protein. This was done by growing the clones in LB liquid medium containing 100 μg/ml of carbenicillin and 0.4% glucose at 30°C to OD,_11MI = 0.6 then inducing the cultures with IPTG (0.4 mM). The cells were then disrupted and the cell extract was analyzed by SDS-PAGE. The nucleotide sequence and translated amino acid sequence of the mature class II porin gene cloned into pET- 17b are shown in Figures 9 A and 9B.

Construction of the fusion class 2 porin

The fusion class 2 porin was constructed by amplifying the pUC l 9-class 2 porin construct using the oligonucleotides: 5 '-CCT GTT GCA GCG GAT CCA

GAC GTT ACC TTG TAC GGT AC A ATT AAA GC- 3' and 5'-CGA CAG GCT TTT TCT CGA GAC CAA TCT TTT CAG -3'. This strategy allowed the cloning of the amplified class 2 porin into the BamWl and Xhol sites of the plasmid pET-17b thus producing a fusion class 2 porin containing an additional 22 amino acids at the N-terminus derived from the T7 φl O capsid protein contained in the plasmid. Standard PCR was conducted using the pUCl 9-class 2 as the template and the two oligonucleotides described above. The PCR reaction yielded a 1.1 kb product when analyzed on a 1.0% agarose gel . The DNA obtained from the PCR reaction was gel purified and digested with the reaction enzymes BamWl and -YTrøl. The 1.1 kb product produced was again gel purified and ligated to BamWl and Xhol digested pET-17b using T₄ DNA ligase. This ligation mixture was then used to transform competent E. coli DH5α. Colonies that contained the 1.1 kb insert were chosen for further analysis. The DNA from the DH5α clones was analyzed by restriction enzyme mapping and the cloning junctions of the chosen plasmids were sequenced. The nucleotide sequence and translated amino acid sequence of the fusion class II porin gene cloned into the expression plasmid pET-17b are shown in Figures 10A and 10B. After this analysis, the DNA obtained from the DH5α clones was used to transform E. coli BL21 (DE3)- ompA. The transformants were selected on LB-agar containing 100 μg/ml of carbenicillin. Several transformants were screened for their ability to make the class 2 porin protein. This was done by growing the clones in LB liquid medium containing 100 μg/ml of carbenicillin and 0.4% glucose at 30 °C to OD_6II = 0.6 then inducing the cultures with IPTG (0.4 mM). The cells were then disrupted and the cell extract was analyzed by SDS-PAGE.

Example 3. Cloning and Expression of the Mature class 3 porin from Group B Neisseria meningitidis strain 8765 in E. coli

Genomic DNA was isolated from approximately 0.5 g of Group B Neisseria meningitidis strain 8765 using the method described above (Sambrook et al, Molecular Cloning: A Laboratory Manual, 2nd ed.. Cold Spring Harbor, New York, Cold Spring Harbor Laboratory Press ( 1989)). This DNA then served as the template for two class 3 porin specific oligonucleotides in a standard PCR reaction.

The mature class 3 porin was constructed by amplifying the genomic DNA from 8765 using the oligonucleotides: 5'-GTT GCA GCA CAT ATG GAC GTT ACC CTG TAC GGC ACC-3' and 5'-GGG GGG ATG GAT CCA GAT TAG AAT TTG TGG CGC AGA CCG ACA CC-3'. This strategy allowed the cloning of the amplified class 3 porin into the Ndeλ and BamHl sites of the plasmid pET-24a+ (Figures 13A and 13B), thus producing a mature class 3 porin. Standard PCR was conducted using the genomic DNA isolated from 8765 as the template and the two oligonucleotides described above. The reaction conditions were as follows: 8765 genomic DNA 200 ng, the two oligonucleotide primers described above at 1 μM of each, 200 μM of each dNTP, PCR reaction buffer (10 mM Tris HCl, 50 mM KC1, pH 8.3), 1.5 mM MgCl₂, and 2.5 units of Taq polymerase, and made up to 100 μl with distilled water. This reaction mixture was then subjected to 25 cycles of 95 °C for 1 min, 50°C for 2 min and 72°C for 1.5 min.

This PCR reaction yielded about 930 bp of product, as analyzed on a 1% agarose gel. The DNA obtained from the PCR reaction was gel purified and digested with the restriction enzymes Ndel and BamWl. The 930 bp product was again gel purified and ligated to Nde and BamWl digested pET-24a(+) using T4 ligase. This ligation mixture was then used to transform competent E. coli DH5α. Colonies that contained the 930 bp insert were chosen for further analysis. The DNA from the E. coli DH5α clones was analyzed by restriction enzyme mapping and cloning junctions of the chosen plasmids were sequenced. After this analysis, the DNA obtained from the E. coli DH5α clones was used to transform E. coli BL21(DE3)-Δo/w/λ4. The transformants were selected on LB-agar containing 50 μg/ml of kanamycin. Several transformants were screened for their ability to make the class 3 porin protein. This was done by growing the clones in LB liquid medium containing 50 μg/ml of kanamycin and 0.4% of glucose at 30°C to OD_MK1

= 0.6 then inducing the cultures with IPTG ( 1 mM). The cells were then disrupted and the cell extract was analyzed by SDS-PAGE.

Example 4. Purification and refolding of recombinant class 2 porin

E coli strain BL21(DE3)Δo«?/?A [pNV-5] is grown to mid-log phase (OD

= 0.6 at 600 ran) in Luria broth at 30°C. IPTG is then added (0.4 mM final) and the cells grown an additional two hours at 37°C. The cells were then harvested and washed with several volumes of TEN buffer (50 mM Tris-HCl, 0.2 M NaCl, 10 mM EDTA, pH = 8.0) and the cell paste stored frozen at -75 °C. For purification preweighed cells are thawed and suspended in TEN buffer at a 1 : 15 ratio (g/v). The suspension is passed through a Stansted cell disrupter (Stansted fluid power Ltd.) twice at 8,000 psi. The resultant solution is then centrifuged at 13,000 rpm for 20 min and the supernatant discarded. The pellet is then twice suspended in TEN buffer containing 0.5% deoxycholate and the supernatants discarded. The pellet is then suspended in TEN buffer containing 8 M deionized urea (electrophoresis grade) and 0.1 mM PMSF (3 g/lOml). The suspension is sonicated for 10 min or until an even suspension is achieved. 10 ml of a 10% aqueous solution of 3, 14-zwittergeπ (Calbiochem) is added and the solution thoroughly mixed. The solution is again sonicated for 10 min. Any residual insoluble material is removed by centrifugation. The protein concentration is determined and the protein concentration adjusted to 2 mg/ml with 8 M urea- 10% zwittergen buffer (1 : 1 ratio). This mixture is then applied to a 2.6 x 100 cm column of Sephacryl S-300 equilibrated in 100 mM Tris-HCl, 1 M NaCl, 10 mM EDTA, 20 mM CaCL, 0.05% 3,14-zwittergen, 0.02% sodium azide, pH = 8.0. The flow rate is maintained at 1 ml/min. Fractions of 10 ml are collected. The porin refolds into trimer during the gel filtration. The OD = 280 nm of each fraction is measured and those fractions containing protein are subjected to SDS gel electrophoresis assay for porin. Those fractions containing porin are pooled. The pooled fractions are either dialyzed or diluted 1 :10 in 50 mM Tris HCl pH = 8.0, 0.05% 3,14-zwittergen, 5 mM EDTA, 0.1 M NaCl. The resulting solution is then applied to a 2.6 x 10 cm Q sepharose high performance column (Pharmacia) equilibrated in the same buffer. The porin is eluted with a linear gradient of 0.1 to 1 M NaCl.

Example 5. Purification and refolding of recombinant class 3 porin

E coli strain BL21 (DE3) AompA containing the porB-pET-17b plasmid is grown to mid-log phase (OD = 0.6 at 600 nm) in Luria broth at 30°C. IPTG is then added (0.4 mM final) and the cells grown an additional two hours at 37°C. The cells were then harvested and washed with several volumes of TEN buffer (50 mM Tris-HCl, 0.2 M NaCl, 10 mM EDTA, pH = 8.0) and the cell paste stored frozen at -75 °C. For purification about 3 grams of cells are thawed and suspended in 9 ml of TEN buffer. Lysozyme is added (Sigma, 0.25 mg/ml) deoxycholatc (Sigma, 1.3 mg/ml) plus PMSF (Sigma, μg/ml) and the mixture gently shaken for one hour at room temperature. During this time, the cells lyse and the released DNA causes the solution to become very viscous. DNase is then added (Sigma, 2 μg/ml) and the solution again mixed for one hour at room temperature. The mixture is then centrifuged at 15K rpm in a S-600 rotor for 30 minutes and the supernatant discarded. The pellet is then twice suspended in 10 ml of TEN buffer and the supematants discarded. The pellet is then suspended in 10 ml of 8 M urea

(Pierce) in TEN buffer. The mixture is gently stirred to break up any clumps. The suspension is sonicated for 20 minutes or until an even suspension is achieved. 10 ml of a 10% aqueous solution of 3,14-zwittergen (Calbiochem) is added and the solution thoroughly mixed. The solution is again sonicated for 10 minutes. Any residual insoluble material is removed by centrifugation. The protein concentration is determined and the protein concentration adjusted to 2 mg/ml with 8 M urea- 10% zwittergen buffer (1 : 1 ratio).

This mixture is then applied to a 180 x 2.5 cm column of Sephacryl S-300 (Pharmacia) equilibrated in 100 mM Tris-HCl, 1 M NaCl, 10 mM EDTA, 20 mM CaCl₂, 0.05% 3,14-zwittergen, pH = 8.0. The flow rate is maintained at 1 ml/min. Fractions of 10 ml are collected. The porin refolds into trimer during the gel filtration. The OD_28ϋ nm of each fraction is measured and those fractions containing protein are subjected to SDS gel electrophoresis assay for porin. Those fractions containing porin are pooled. The pooled fractions are dialyzed and concentrated 4-6 fold using Amicon concentrator with a PM 10 membrane against buffer containing 100 mM Tris- HCl, 0.1 M NaCl, 10 mM EDTA, 0.05% 3,14-zwittergen, pH = 8.0. Alternatively, the pooled fractions are precipitated with 80% ethanol and resuspended with the above-mentioned buffer. Six to 10 mg of the material is then applied to a monoQ 10/10 column (Pharmacia) equilibrated in the same buffer. The porin is eluted from a shallow 0.1 to 0.6 M NaCl gradient with a 1.2% increase per min over a 50 min period. The Flow rate is 1 ml/min. The peak containing porin is collected and dialyzed against TEN buffer and 0.05% 3,14-zwittergen. The porin may be purified further by another S-300 chromatography. Example 6. Purification and chemical modification of the polysaccharides

The capsular polysaccharide from both group B Neisseria meningitidis and E. coli Kl consists of α(2-8) polysialic acid (commonly referred to as GBMP or Kl polysaccharide). High molecular weight polysaccharide isolated from growth medium by precipitation (see, Frasch, C.Ε., "Production and Control of Neisseria meningitidis Vaccines" in Bacterial Vaccines, Alan R. Liss, Inc., pages 123-145 (1990)) was purified and chemically modified before being coupled to the porin protein. The high molecular weight polysaccharide was partially depolymerized with 0.1 M acetic acid (7 mg polysaccharide/ml), pH =

6.0 to 6.5 (70°C, 3 hrs) to provide polysaccharide having an average molecular weight of 12,000-16,000. After purification by gel filtration column chromatography (Superdex 200 prep grade, Pharmacia), the polysaccharide was N-deacetylated in the presence of NaBH₄ and then N-propionylated as described by Jennings et al. (J. Immunol. 737: 1808 (1986)) to afford N-Pr GBMP (see

Example 14). Treatment with NaIO₄ followed by gel filtration column purification gave the oxidized N-Pr GBMP having an average molecular weight of 12,000 daltons.

Example 7. Coupling of oxidized N-Pr GBMP to the group B meningococcal class 3 porin protein (PP)

The oxidized N-Pr GBMP (9.5 mg) was added to purified class 3 porin protein (3.4 mg) dissolved in 0.21 ml of 0.2 M phosphate buffer pH 7.5 which also contained 10% octyl glucoside. After the polysaccharide was dissolved, sodium cyanoborohydride (7 mg) was added and the reaction solution was incubated at 37°C for 4 days. The reaction mixture was diluted with 0.15 M sodium chloride solution containing 0.01 % thimerosal and separated by gel filtration column chromatography using Superdex 200 PG. The conjugate (N-Pr GBMP-PP) was obtained as single peak eluting near the void volume. Analysis of the conjugate solution for sialic acid and protein showed that the conjugate consists of 43% polysaccharide by weight. The porin protein was recovered in the conjugate in 44% yield and the polysaccharide in 12% yield. The protein recoveries in different experiments generally occur in the 50-80% range and those of the polysaccharide in the 9-13% range (see also Example 14).

Example 8. Immunogenicity studies

The immunogenicities of the N-Pr GBMP-PP conjugate and those of the N-Pr GBMP-Tetanus toxoid (N-Pr GBMP-TT) conjugate which was prepared by a similar coupling procedure were assayed in 4-6 week old outbread Swiss

Webster CFW female mice. The polysaccharide (2 μg)-conjugate was administered on days 1, 14 and 28, and the sera collected on day 38. The conjugates were administered as saline solutions, adsorbed on aluminum hydroxide, or admixed with stearyl tyrosine. The sera ELISA titers against the polysaccharide antigen and bactericidal titers against N. meningilidis group B are summarized in Table 1.

Example 9. Expression of group B Neisseria meningitidis Outer Membrane (MB 3) Using Yeast Pichia past or is Expression System

Materials and Methods

Strains and Plasmids

Pichia pasloris GS 1 15 (provided by Invitrogen) has a defect in the histidinol dehydrogenase gene (his4) which prevents it from synthesizing histidine. All expression plasmids carry the HIS4 gene which complements his4 in the host, so transformants are selected for their ability to grow on histidine- deficient medium. Until transformed, GS 1 15 will not grow on minimal medium alone.

Expression vectors

Four different expression vectors were used that include the strong, highly-inducible AOXI promoter for expression of foreign protein (Pichia Expression Kit, Invitrogen). One vector, pHIL-D2, is used for intracellular expression, while the other three (pHIL-S 1 , pPIC9, and pPIC9K) are used for secreted expression. Maps of the pHIL-D2, pHIL-Sl , and pPIC9 vectors may be found on pp. 19-22 of the Invitrogen Instruction Manual for the Pichia

Expression Kit, Version E, the contents of which is hereby incorporated by reference. Secretion requires the presence of a signal sequence on the expressed protein to target it to the secretory pathway. To improve the chances for success, two different kinds of vectors are included in the kit. The vector pHIL-S l carries a native Pichia pastor is signal from the acid phosphatase gene, PHOI . The vectors, pPIC9 and pPIC9K (with corrected HIS4 region), both carry the secretion signal from the S. cerevisiae α-mating factor pre-pro peptide. The advantage of expressing secreted proteins is that P. pasloris secretes very low levels of native proteins. Thus, the secreted heterologous protein comprises the vast majority of the total protein in the media and serves as the first step in purification of the protein (Barr et al, Pharm. Eng. 12(2) .48-51 (1992)).

Cloning of the meningococcal B class 3 protein gene (MB 3)

The genomic DNA of Group B Neisseria meningilidis (strain 8765) served as the template for the amplification of class 3 porin (MB3) in a standard PCR. The amplified DNA fragment (930 b.p. long) of the mature porin protein was ligated in Nde I - BamH I cloning sites of the pET-24a cloning/expression vector, originally constructed by Studier et al, J. Mol. Biol. 189: 1 13-130 ( 1986); Melh. Enzymol 755:60-89(1990); J. Mol. Biol 279:37-44 (1991 ), and manufactured by Novagen. The pET vectors were developed for cloning and for expressing target DNA fragments under the strong T7 transcription and translation signals. Expression from the T7 promoter is induced by providing the host cell with a source of T7 RNA polymerase. Newer, more convenient vectors utilizing the T7 expression system are now available from Novagen (Madison, WI 5371 1). The T7 expression system was successfully used for the expression of MB3 in E. coli (see Example 3).

The optimization of the translation elongation rate for the expressed MB3 gene

Codon usage is known to affect the translational elongation rate, and therefore it has been considered an important factor in affecting product yields (Romanos et al, Yeast 5:423-488 (1992)). There is evidence that codon usage may affect both yield and quality of the expressed protein. A number of highly expressed genes show a strong bias toward a subset of codons (Bennetzen el al,

J. 73/o/. Chem. 257:3026-3031 (1982). This "major codon bias," which can vary greatly between organisms, is thought to be a growth optimization strategy. This mechanism allows an organism to be capable of efficient translation of highly expressed genes during rapid growth, as only a subset of tRNAs and aminoacyl- tRNA synthetases need to be present in high concentrations. Kurland et al, TIBS

72: 126-128 (1987). In cases where mRNA contains rare codons, aminoacyl- tRNAs may become limited, increasing the probability of amino acid misincoφorations, and possibly causing ribosomes to drop off. Indeed, a high misincorporation frequency has recently been observed in a foreign protein produced in E. coli (Scorer et al, Nucleic Acids Res. 79:351 1 -3516 (1991)).

Moreover, proteins containing amino acid misincorporations are difficult to purify and may have both impaired activity and antigenicity. The presence of several rare codons has been shown to limit the production of tetanus toxin fragment C in E. coli (Makoff et al, Nucleic Acids Res. 77: 10191-10201 (1989)). In yeast, Hoekema et al. (Mol. Cell Biol. 7: 2914-2924 (1987)) showed that substitution of a large proportion of preferred codons for rare codons in the 5 ' portion of the PGK (phosphoglycerate kinase) gene caused a decrease in expression levels. Recently, the expression of an immunoglobulin kappa chain in yeast has been shown to be increased 50-fold when a synthetic codon- optimized gene is used, although the level of kappa chain mRNA remains the same.

Significant differences between codon usage profiles of Pichia and MB3 were found (Table 5). In order to optimize the translation efficiency, particularly at the beginning of translation elongation, codons optimal for Pichia were introduced into the 5' region of the MB3 gene. When constructing the linker used to clone MB3 into pHIL-Sl , the oligomers were synthesized so that they contained sequence optimized for Pichia expression. A 51 nucleotide long oligomer (51-mer) was synthesized for this purpose. The sequence of the oligomer is:

5'-TCGAGACGTCACTTTGTACGGTACTATTAAGGCTGGTGTTGAGA CTTCCCG-3' A 47 nucleotide oligomer complementary to the 51-mcr was also synthesized. The sequence of this oligomer is:

5'-CGGGAAGTCTCAACACCAGCCTTAATAGTACCGTACAAAGTGAC GTC-3'

These two oligomers, which contain Xhol and Bsr restriction sites, were annealed to serve as a connector, and then ligated to vector pHIL-S 1 , which had been linearized withΛTϊøl digestion. The ligated fragment was then digested with

BamHl, gel purified, and ligated with an MB3 fragment obtained from cutting the pNV 15 vector with both Bsrl and BamHl enzymes. The fragment was then cloned into the Pichia pHIL-Sl expression vector. The new DNA sequence of the 5' region of MB3 was verified by DNA sequencing of pHIL-Sl/MB3 isolated from Pichia. The sequence of the original 5' end of the gene for mature MB3 (from NT 1) is:

gac gtt ace ctg tac ggc ace att aaa gcc ggc gta gaa act tec cgc tct gta ttt cac cag aac ggc D V T L Y G T I K A G V E T S R S V F H Q N G

caa gtt act gaa gtt aca

0 V T E V T

The codon-optimized sequence of the same fragment (replaced nucleotides showed as capital letters), along with its corresponding amino acid sequence is:

gac gtC acT Ttg tac ggT acT att aaG gcT ggT gtT gaG act tec cgc tct gta ttt cac cag aac D V T L Y G T I A G V E T S R S V F H Q N ^"

ggc caa gtt act gaa gtt aca G Q V T E V T

Vector pHIL-Sl/MB3, containing the codon-optimized MB3 DNA. served as the template for the amplification of MB3 in a standard PCR. Oligomers were synthesized to serve as PCR primers. The PCR fragments of

MB3 were inserted into Pichia expression vectors either directly or by using the Original TA Cloning Kit (Invitrogen); details are given below.

For the cloning of MB3 into the EcoRl site of pHIL-D2: Forward primer (39 nt. having an engineered EcoRl site and a sequence (5'ATG) encoding an initiation methionine):

5'-CGAGAATTCATGGACGTCACTTTGTACGGTACTATTAΛG-3' Reverse primer (45 nt, having an engineered EcoRl site and stop codon): 5'-GCTGAATTCTTAGAATTTGTGGCGCAGACCGACACCGCCGGCAGT-3' For the cloning of MB3 into the EcoRl-Avrll sites of pPIC9 and pPIC9: Forward primer (39 nucleotides (nt), having an engineered EcoRl site; no sequence encoding an initiation methionine was necessary because the leader peptide had an initiation methionine): 5'-AGCGAATTCGACGTCACTTTGTACGGTACTATTAAGGCT-3'

Reverse primer (36 nt, having an engineered Avrll site and stop codon): 5'-CACCCTAGGTTAGAATTTGTGACGCAGACCGACACC-3'

For PCR amplification of the complete MB3 gene. Vent"⁸ DNA polymerase (NEB) was used. The fidelity of this polymerase is 5-15-fold higher than that observed for Taq DNA polymerase. To generate an expression cassette plasmid, PCR fragments of MB3 (full length and truncated fragments) were inserted in Pichia expression vectors either directly or using the Original TA Cloning^® Kit (Invitrogen), which includes a pCR™II vector for subcloning of PCR fragments. Direct cloning of DNA amplified by either Vent^® DNA polymerase or Pfu DNA polymerase into the vector pCR™II is difficult, as the cloning efficiency is often very low. This is due to the 3' to 5' exonuclease proofreading activity of Vent* and Pfu, which removes the 3' A overhangs that are necessary for TA cloning, leaving blunt ends. The Original TA Cloning⁰* Kit allows these blunt-ended fragments to be cloned. Use of this method eliminates any enzymatic modifications of the PCR product, and does not require the use of

PCR primers containing restriction sites. To increase the cloning efficiency further, the Invitrogen protocol was modified as follows. Following amplification with Vent⁴ or Pfu (see manual for The Original TA Cloning"" Kit, protocol for the addition of 3'A-overhangs post amplification, p. 19), rather than placing the vial on ice, as recommended in the kit, the mineral oil in the PCR mixture was immediately removed using Parafilm™. This was accomplished by pouring the PCR mixture onto the Parafilm, and zigzagging the drop down the surface of the Parafilm with a gentle rocking motion until all of the oil had adhered to the Parafilm surface. The reaction mixture, now free of oil, was then collected into a fresh tube. The Invitrogen protocol was then resumed with the addition of Taq polymerase. This method allowed the difficult cloning of PCR fragments into large expression vectors.

The expression cassette of the integrating vector (Invitrogen) contains the methanol-induced AOXI promoter and its terminator, flanked by stretches of nucleotides up- and downstream from the AOX 1 gene. The P. pasloris His4 gene served as an auxotrophic marker. These vectors do not contain a yeast ori, hence His⁺ colonies must correspond to integration of the expression cassette. All PCR fragments of MB3 were inserted in frame with a Pichia Kozak consensus sequence (CAAAAAACAA) (Cavenor et al. Nucleic Acids Res. 79:3185-3192 (1991); Kozak Nucleic Acids Res. 75:8125-8148 (1987); Kozak Proc. Nat Acad

Sci. USA 57:8301 -8305 (1990)) to provide the best translation initiation of the MB3 gene. All inserts were placed under the control of the AOXI promoter to d;ϊ e expression of the gene of interest. After the ligation of the MB3 fragment in an appropriate expression vector, chemically competent E. coli cells were transformed (TOP 10F') (F' {pro AB, laql_ψ lacZAMl S. Tn/0 (Tet^R)} mcrA,

A(mrr-hsdRMS-mcr C), φ80 /αcZΔM15. Δ/αcX74, deoR, recAl, araOl39, A(ara-leu)1691, galO, galK, rpsh(S\r^R), endAλ , nupGλ ). Other strains which may be suitable are DH5α F', JM109, or any other strain that carries a selectable F' episome and is recA deficient (endA is preferable) (Pichia Expression Kit Instruction Manual, Invitrogen). Colonies with an MB3 insert were used for the preparation of CsCl purified maxi-prep of a plasmid DNA for Pichia transformation (Sambrook, J. er al, Eds.. Molecular Cloning: A Laboratory Manual. 2nd. Ed., Cold Spring Harbor Press ( 1989), pp. 1.42-1.43). Restriction analysis and DNA sequencing (DNA Sequencing Kit. Version 2 (USB)) confirmed that these constructs were correct.

Modification of the starting MB3 sequence was especially useful for intracellular expression of the porin gene (pHIL-D2/MB3 construct). Because the other constructs (pHIL-Sl/MB3 and pPIC9/MB3) used for MB3 secretion contained codons optimal for Pichia in the leader peptide sequence upstream of the MB3 insert, the initiation of translation was not rate-limiting. In contrast, the pHIL-D2 vector does not include any leader sequence and the initiation of translation must be started from the rare codons of the MB3 insert. The optimization of this sequence is believed to be responsible for the fact that pHIL- D2/MB3 constructs gave the highest level of MB3 expression of any of the clones tested (Tables 3, 4).

Transformation of yeast cells and DNA analysis of integrants

Plasmid DNA was linearized with single or double (for higher integration efficiencies) digestion, and P. pasloris strain GS 1 15 (his4") was transformed to the His⁺ phenotype by the spheroplast method using Zymolyase followed by adsorption of transforming DNA and penetration of this DNA through the spheroplast pores into the Pichia cells in the presence of PEG and Ca'² (Pichia Expression Kit manual, Invitrogen, pp.33-38). By replica plating or patching on Minimal Dextrose (MD: 1.34% yeast nitrogen base (YNB - Difco), 4xl 0^"5% biotin, 2% dextrose) versus Minimal Methanol (MM: 1.34% YNB, 4xl 0^"5% biotin, 0.5% methanol), it was possible to determine which His' transformants also exhibited disruption of the AOXI gene. Transformed spheroplasts were seeded on agarose-containing plates using selective growth medium without histidine (MD). At the end of 4-6 days, white separated colonies of yeast transformants had appeared. These colonies were picked up and were seeded on selective methanol-containing medium (MM) for screening of AOX 1 -disrupted

(Mut^s or Mut^{" "}) transformants (Pichia Expression Kit manual, Invitrogen, p. 60).

Growth of the yeast and methanol induction

Because recombination events can occur in many different ways which affect the level of protein expression (clonal variation), at least 16 verified recombinant clones were screened to determine the level of MB3 expression.

These colonies were grown in 5 ml of glycerol-containing Buffered Glycerol- complex Medium (BMGY: 1% yeast extract, 2% peptone, 100 mM potassium phosphate, pH 6.0, 1.34% YNB, 4xl0^"5% biotin, 1.0% glycerol) (Pichia Expression Kit manual, Invitrogen, p. 61) at 30°C in 50 ml 2098 Bluemax tubes (Falcon) in an Innova incubator shaker (New Brunswick Sci.) ("pilot" expression). After 1-2 days when cultures had reached an OD600 = 5-10, the cells were harvested by centrifugation (4000 rpm for 10 minutes at room temperature) and were resuspended in methanol-containing Buffered Methanol- complex Medium (BMMY: 1% yeast extract, 2% peptone, 100 M potassium phosphate, pH 6.0, 1.34% YNB, 4xl 0^"5% biotin, 0.5% methanol) (Pichia Expression Kit manual, Invitrogen, p. 61 ) for the induction of the AOXI promoter. To replenish exhausted methanol, 0.5% of fresh methanol was added each day to induced cells. Aliquots of the cells were collected every day for 6 days by centrifugation, and stored (pellets and supematants separately) at -70 °C before examining. The most promising clones were examined for the optimization of protein expression and to scale-up the expression protocol to produce more protein.

Lysis o/P. pastoris cells, analysis by SDS-PAGE and Western blot analysis

Cells were broken by agitation in breaking buffer (50 mM sodium phosphate, pH 7.4; 1 mM PMSF(phenylmethylsulfonyl fluoride), 1 mM EDTA and 5% glycerol). Equal volumes of acid-washed glass beads (0.5 mm in diameter) were added. The mixture was vortexed for a total of 4 min, 30 sec mixing each, followed by 30 sec on ice. The soluble fraction was recovered by centrifugation for 10 min at 14000 rpm at 4°C. Supernatant (or cell lysate, or fraction of "soluble" proteins) was removed and stored at -70 °C, and the residual cell pellet was extracted by vortexing with SDS sample buffer (1 % SDS, 5% beta-mercaptoethanol, 10% glycerol, 10 mM EDTA, 0.025% bromophenol blue) followed by boiling for 10 min. Lysates were centrifuged again and the aqueous layer was examined as fraction of "insoluble" or membrane associated proteins. NOVEX pre-cast 8-16% gradient gels were used for separation of proteins according to the procedure of Laemmli (Nature 227:680-685 (1970)). Proteins separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) were stained with Coomassie Brilliant Blue R250, or were transferred to polyvinylidene difluoride (PVDF) membrane using a Transblott apparatus (BioRad Laboratories) according to the company specification.

The Western blot procedure was carried out without detergents, using only blocking procedures, as described by Sheng and Schuster (Bio Technique 73:704-708 (1992)) with some modifications. This method provides high specificity and sensitivity with a low background. For the transfer, both Western transfer membrane and the SDS-PAGE separating gel were equilibrated with transfer buffer (24mM Tris-HCl/192 mM glycine/ 20% methanol) for 20 minutes prior to electrotransfer. The transfer was performed at 90V and 4°C for 3-4 hours. Transfer of proteins to PVDF membranes was monitored by the transfer of prestained molecular weight markers (BRL).

Immunostaining of proteins was carried out as follows. The transfer membrane was rinsed with TBS (TOmM Tris-HCl/.09% NaCl, pH 7.2). The membrane was then incubated in 1% non fat dried milk PBS solution (M-PBS) with .02% sodium azide at 37°C for 3 hours (or at 4°C overnight). The membrane was then washed 3 times with TBS/0.5% BSA (BSA/TBS) and once with TBS. The membrane was then incubated with the primary mouse anti-MB3 antibody (mouse polyclonal antisera against purified OMP class 3) diluted to about 1 :4000 in PBS/1 %BSA (BSA/PBS). and the membrane was again washed 3 times with TBS/0.5% BSA (BSA/TBS) and once with TBS. The membrane was then incubated in 1 % M-PBS at room temperature for 30 minutes with gentle shaking. The membrane was washed 3 times with TBS/0.5% BSA (BSA/TBS) and once with TBS. The membrane was then incubated in the secondary alkaline phosphatase-conjugated anti-mouse antibody (Kirkegaard & Perry Laboratory (KPL), Gaithersburg, MD) diluted 1 :4000 in 1 % BSA/PBS. The membrane was then washed 2 times with 0.5% BSA/TBS and 3 times with .25% Tween 20 in PBS. These washing steps differed from those recommended by Sheng and Schuster; the improved protocol provided less background than did the wash steps of the reference, which utilized 6 washes in 0.5% BSA/PBS. The membrane was then incubated in alkaline phosphatase buffer (0.05% M Tris-HCl, pH 9.5; 10 mM MgCl₂), followed by incubation in BCIP/NBT substrate solution

(KPL). The development was stopped by washing the membrane in PBS/50 mM EDTA. The limit of detection was about 2-5 ng of native MB3 protein.

Results and discussion

The strategy used to insert the cDNA encoding the mature MB3 into expression vectors and the steps using this construct for the transformation of P. pasloris are outlined below. First, the MB3 gene is cloned into one of the 4 Pichia expression vectors. In the next step, the resulting construct is linearized by digestion with Notl or BgHl, and his4 Pichia spheroplasts are transformed with the linearized construct. In the following step, a recombination event occurs in vivo between the 5 ' and 3 AOXI sequences in the vector and in the genome, resulting in replacement of the AOXI gene with the MB3 gene. Next, the Pichia transformants are selected on histidine-deficient medium, on which only cells that have undergone gene replacement can grow. The one-step gene replacement method described for S. cerevisiae (Rothstein. Melh. Enzymol. 707:202-21 1 (1983)) was successfully used by Cregg el al (Biological Research on Industrial Yeast, Vol. II, Stewart el al. eds., CRC Press, Boca Raton, pp.1 -1 8 (1987)) for the replacement of the P. pasloris AOXI structural gene. Transformation of GS1 15 with 10 μg of linearized expression vectors (pH!L-D2, pHIL-Sl , pPlC9, and pPIC9K) with MB3 insert gave more than 100 colonies in each experiment. Thus, the procedure yielded >10² His^' colonies per μg DNA. which is comparable to that reported for the best results of P. pasloris transformations. These transformants have the ability to grow on histidine- deficient medium (MD-minimal dextrose), and so arc His . About 10-40% of these recombinants were "methanol slow" (Muf - "methanol utilization slow"), i.e., demonstrated impaired growth on media such as MM (minimal methanol), which contains methanol as the sole carbon and energy source. These HisVMuf transformants are a result of the replacement of the AOXI structural gene with the MB3 expression cassette containing the His^τ gene via a double crossover event. Recombination events may also occur as integration or insertion (single crossover events) of the expression cassette into the 5' or 3' AOXI region, which leaves the AOXI gene intact. Among the HisVMuf clones, 25-35% were positive, MB3-expressing transformants (Table 2). The reason that the AOX1- deleted transformants grow at all on methanol medium is due to low-level expression of alcohol oxidase activity by the AOX2 gene product. Analysis of DNA isolated from these "positive" recombinants using PCR with 5' AOXI, 3 ' AOXI, 5' MB3, 3' MB3 and other specific primers, indicated that the AOXI structural gene was indeed replaced by the fragment containing the MB3 and HIS4 genes. Analysis of the DNA isolated from HisVMuf transformants indicated that the AOXI structural gene was intact and that the entire vector containing His4 DNA had integrated elsewhere. Among 39 AOXI -disrupted transformants that expressed MB3, no HisVMuf transformants were found, indicating preference for the AOXI replacement mode of integration. The results of immunoblot analysis of 84 Pichia transformants indicated that one may express the MB3 protein using all of the constructed recombinant plasmids, pHIL-D2/MB3, pHIL-Sl/MB3, pPIC9/MB3. and pPIC9K/MB3 (Table 3). Thirty-nine clones were isolated that expressed the MB3 protein. Antigcnic specificity of expressed MB3 protein was examined and was confirmed by Western blot analysis using monoclonal and polyclonal antibodies raised against wild type N. meningitidis OMP class 3. These results led to the conclusion that all of the expression vectors were correctly constructed, and that the transformations of Pichia spheroplasts were properly performed.

The amount of expressed MB3 was determined by densitomet ic scanning of the Coomassie brilliant blue stained protein bands fractionated by SDS-PAGE using a Model GDS-7500 scanning densitometer (UVP Life Sci.) or Model IS-1000 densitometer (Alpha Innotech Corp.). Purified OMP class 3 extracted wild type of N. meningitidis was used as a standard. Based on the results (summarized in Table 3), the level of protein expression was estimated to be moderate to high.

The optimization of the translation elongation rate for the expression of the MB3 gene (see Materials and Methods, above) was very useful. The modification of the starting MB3 sequence was especially effective for intracellular expression of the porin gene (pHIL-D2/MB3 construct). Because other constructs (pHIL-Sl/MB3 and pPIC9/MB3, both used for MB3 secretion) contained codons optimal for Pichia in the leader peptide sequence upstream of the MB3 insert, the initiation of translation of these cassettes was not rate- limiting. In contrast, the pHIL-D2/MB3 construct did not include a leader sequence, and so without codon optimization, translation would have had to have been initiated at rare codons of the MB3 insert. The codon-optimized pHIL-

D2/MB3 construct, when transformed into Pichia chromosomal DNA, provided the highest level of MB3 expression of all the other mentioned MB3 expression constructs (Tables 3 and 4). Thus, this modification of the translation start sequence of MB3 appears to be responsible for the high yield of expressed protein in pHIL-D2/MB3 constructs.

The level of MB3 expression by the best clones (Pichia transformed with the pHIL-D2/MB3 construct) was in the range of 0.1-0.6 g per IL of cell suspension, or 1 -3 mg per g of cell pellet (Table 3, Fig. 12). Such efficiency of expression in yeast has been reported for many of the following manufactured proteins: hepatitis B surface antigen (0.3 g/L), superoxide dismutase (0.75 g/L), bovine and human lysozyme (0.3 and 0.7 g/L, respectivel) ). human and mouse epidermal growth factors (0.5 and 0.45 g/L respectively), human insulin-like growth factor (0.5 g/L), human interleukin-2 (1.0 g/L), aprotinin analog (0.8 g/L), Kunitz protease inhibitor (1.0 g/L). etc. (Cregg el al, Biotechnology, 77:903-906, Table 1 ( 1993)). It should be emphasized that all of the previously listed levels of expression for manufactured proteins are the result of production of these proteins during fermentation in high cell density fermentors. MB3 was expressed utilizing only shake flask cultures which, as a rule, provide much lower expression levels than does fermentation. Recently reported observations lead one to expect a much higher yield (a 5-10 fold or greater increase) of MB3 in a fermenter (Cregg et al, 1993). P. pasloris adapts well to being scaled up from shake flask to high density fermentor cultures. In addition, where AOX-d eted Pichia strains are used for fermentation, production of foreign proteins can be optimized by first causing rapid growth, and then adding methanol to induce protein production while minimizing additional cell growth. The long amount of time needed to produce proteins when Pichia is growing on methanol can be reduced by applying one of several mixed-feed fermentation strategies (Siegel et al, Biotechnol. Bioeng. 34:403-404 (1989); Brieriey et al. Int. Patent Application No. WO 90/03431 (1989); Brierly et al , Biochem. Eng. 559:350-362 (1990);

Siegel et al, Int. Patent Application No. WO 90/10697 (1990)).

Another promising aspect of the expression levels of MB3 protein in Pichia is that the results were similar for all examined clones. As other investigators have found that in shake flask induction the level of expression is proportional to the number of copies of inserted gene of interest (Clare el al .

1991 ), it can be deduced that all of the MB3 clones tested were single-copy chromosomal integrants, and thus that no Pichia recombinants with multiple integrated copies of the MB3 fragment were isolated.

An important factor in obtaining high levels of expression using P. pasloris is the ability to obtain recombinants with multicopy transplacement or integration (Romanos et al, Vaccine 9:901 -906 (1991 ); Clare et al , Bio/Technology 9:455-460 (1991 ); Clare et al, Gene 705:205-121 (1991 )). . Multicopy transformants have been found to be surprisingly stable over multiple generations during growth and induction in high cell density fermentations. Since this multiple gene insertion event occurs at a low frequency during spheroplast transformation, a special dot blot screening of a number of recombinants is used (Scorrer et al, Bio/Technology 72: 181 -184 (1993)). An alternative to screening for spontaneous multiple insertion events is to insert multiple copies of the gene(s) of interest into Pichia expression vector pAO815, which has recently been constructed by Invitrogen for this purpose.

Before attempting to express MB3, the protein was evaluated to determine if any of the factors believed to reduce expression levels were present. One of the factors which can reduce expected high-level accumulation of a protein is proteolytic stability. It is now known that highly expressed proteins are devoid of good PEST sequences. PEST sequences contain proline (P), glutamic acid (E), serine (S) and threonine (T), and are found in all rapidly degraded eukaryotic proteins of known sequence; such proteins have been implicated as favored substrates for calcium-activated proteases (Rogers et al . Science 234:364-369 (1986)). Proteins that are expressed at high levels in yeast do not contain a so- called "good" PEST sequence (having a score >5 as calculated by the algorithm developed by Rogers et al. (1986)), which leads to susceptibility to proteolysis, nor do they contain the pentapeptide sequences XFXRQ or QRXFX (X=any amino acid), which are selective for degradation of cytoplasmic proteins by the lysosomal pathway (Dice, J.F., Fed. Am.Soc. Exp. Biol. (FASEB) J. 7:349-357 (1987)). Proteins that are expressed at high levels in yeast do not contain these pentapeptide sequences. Computer analysis of the MB3 sequence identified a "poor" but not "good" PEST region (13-32aa) having the sequence (ETSRSVFHQNGQVTEVTIAT. According Rogers el al. (1986) such a poor PEST sequence weakly influences the proteolytic stability of eukaryotic proteins. Thus, one of the factors which leads to proteolysis is not present in MB3.

MB3 also does not contain the highly conserved pentapeptide sequences mentioned above. The sequence ROSFI (75-79aa) is present in MB3: this sequence displays some homology to the degradation pentapeptide QRXFX, but is not believed to greatly destabilize MB3. The nature of the NH₂-terminal amino acid residue can also be an important factor in the susceptibility of a protein to degradation. Varshavsky et al. have demonstrated that the presence of certain amino acids at the NH₂- terminus provide a stabilizing effect against rapid degradation by ubiquitin- mediated pathways (the N-end rule pathway) (Varshavsky et al. Yeast Genetic-

Engineering, Butterworths, pp. 109-143 (1989)). Most proteins that are expressed at high levels in yeast have a stabilizing amino-terminus amino acid residue (A, C, G, M, S, T or V). Examples of such proteins include human superoxide dismutase, human tumor necrosis factor, phosphoglycerate kinase from S. cerevisiae, invertase from S. cerevisiae, alcohol oxidase from P. pasloris, and extracellular alkaline protease from Y. lipolytica (Sreekrishna el al, Biochemistry 25:41 17-4125 (1989)). Although MB3 is expressed well in yeast, the NH₂-terminal aspartic acid (D) of MB3 does not provide a stabilizing effect against rapid degradation by ubiquitin-mediated pathways. It is possible that the NH₂-terminal aspartic acid of MB3 will play a role in the level of MB3 produced from Pichia in large scale production. Replacing the first amino acid of MB3 with one of the amino acids known to stabilize the NH₂-terminus of proteins, mentioned above, could improve the level of MB3 production. It was decided to proceed with experiments attempting to express MB3 in yeast, as most of the factors known to reduce expression levels were not present in MB3.

The best expression of MB3 was provided by Pichia clones transformed with the pHIL-D2/MB3 expression cassette (Tables 3 and 4). This pHIL-D2 vector generated intracellular expression of complete, monomeric, non-fusion, non-secreted MB3 with an expected MW of about 34 kDa. These clones provided the highest level of expression of MB3. up to 600 mg/L or 3 mg per g of wet cell pellet (Table 4). About 90-95% of this product was insoluble, membrane-associated material, i.e. , material which sediments upon centri- fugation for 5 min at 10,000g, and that can be extracted by treatment with SDS- containing buffer (PAGE sample buffer) followed by boiling. The protein can then be renatured to a conformation that can be easily recognized by an anti- meningococcal OMP class 3 antibody.

Induction of pHIL-D2/MB3 constructed clones with methanol resulted in the rapid expression and fast accumulation of intracellular MB3. After 24 hours of a methanol induction, the level of expressed MB3 was estimated at not less than 80% of maximal, which was reached after 5-6 days.

The pHIL-D2/MB3-containing Pichia recombinant is the most promising for commercial production. This clone provides relatively high levels of expression which could be significantly improved by using multiple-copy recombinants, and by producing the protein in a fermentor. The fact that MB3 is rapidly produced also provides an advantage for large scale manufacture.

MB3 expressed in an intracellular form was purified by a denaturation/renaturation protocol, followed by gel filtration and ion exchange chromatography. The resultant purified protein exhibits an elution profile on size exclusion chromatography that resembles the recombinant class 3 protein overexpressed in E. coli. MB3 expressed by either E. coli or P. pasloris co-elutes with the native wild-type counterpart, indicating that MB3 expressed by either E. coli or P. pasloris refolds and oligomerizes, achieving full native conformation (Figs. 14A and 14B).

Both the native (Pichia) secretion signal (PHOI ) and the alpha-factor signal sequence from S. cerevisiae were tested for targeting expressed porin to the secretary pathway. Unexpectedly, the shorter PHOI leader was more effective for causing MB3 secretion. The pHIL-S l Pichia transfer vector includes a sequence encoding the 2.5 kDa PHO 1 leader peptide, a secretion signal peptide of P. pasloris. In the pHIL-S l/MB3 construct, the sequence encoding MB3 was inserted downstream of the PHOI leader sequence. 40-50% of the 36.5 kDa expressed fusion protein PHO1/MB3 produced by pHIL-S I /MB3 clones was properly cleaved to generate a 34 kDa MB3 monomer (Tables 2 and 3), and 5-10% of expressed soluble porin was secreted. The pPIC9 and pPIC9K Pichia transfer vectors include a sequence encoding the 10 kDa alpha-factor leader derived from S. cerevisiae. Pichia clones transformed by pPIC9/MB3 or pPIC9K/MB3 did not secrete porin. These recombinants expressed a 44 kDa alpha-factor prepro/MB3 fusion protein well, but no evidence of correct cleavage and processing was observed. Improved secretion of expressed MB3 was not obtained by using its 3' truncated fragment fused with either PHO I leader or alpha-factor leader peptides.

Example 10. Isolation, purification and characterization of MB3 protein expressed as a secretory protein

Yeast cells cultures harboring the expression vector containing the gene for MB3 (pHIL-Sl-pNV3I 8) were configured to isolate the protein as soluble secreted material). The supernatant was clarified by precipitation with 20% ethanol (v/v) to remove contaminating yeast culture impurities. The supernatant was then precipitated with 80% ethanol (v/v). The resulting pellet was washed with TEN buffer (Tris HCl, pH 8.0, 100 mM NaCl and 1 mM EDTA), in order to remove other hydrosoluble contaminating secreted proteins. The pellet containing MB3 was dissolved in an aqueous solution of detergent (solubilizing buffer), comprised of TEN buffer with 5% Z 3-14. The solution was applied to a Hi-Trap Q Sepharose ion exchange column (1 ml) (Pharmacia) equilibrated in 50 mM Tris, 0.2 M NaCl and 1.0 mM EDTA (pH 8.0). A gradient of 0.2-1.0 M

NaCl was applied, and MB3 protein eluted as a single peak.

Example 11. Isolation, purification and characterization of MB3 protein expressed as an insoluble- membrane bound protein

Yeast cells cultures harboring the expression vector containing the gene for MB3 (pHILD-2--pNV322) (see Table 3) were resuspended in breaking buffer (i.e., 50 mM sodium phosphate buffer, pH 7.4, 1 mM EDTA, and 5% glycerol), to a concentration equivalent to 50-100 ODs. The suspension was added to the same volume of acid treated glass beads. The suspension was lysed using a Minibead-Beater (Biospec Products, Bartlesville, OK), in 8 consecutive cycles of 1 min each, followed by 1 min on ice, between each cycle. As an alternative procedure, the lysis process was facilitated by the addition of Zymolase to the breaking buffer. The suspension was transferred to a glass sintered filter to separate the glass beads, and the cell suspension was collected in the filtrate. The beads were further washed and the filtrates combined. The suspension was then centrifuged at 12,000 rpm for 15 min at 4°C. A series of consecutive washing steps was applied to the resultant pellet, consisting of the following: (a) TEN (Tris HCl, pH 8.0, 100 mM NaCl, and 1 mM EDTA) containing 0.5% deoxycholate; (b) TEN containing 0.1% SDS and 1% Nonidet, after which the suspension was rotated for 30 min at 25 °C; (c) washing with TEN buffer; and (d) washing with TEN buffer containing 5% Z 3-14, under rotation overnight at

4°C. Each washing step was followed by centrifugation at 12,000 rpm for 10 min at 4°C to collect the pellet for the following step. As an alternative method of washing the pellet, the suspension was passed through an 18 gauge needle in lieu of rotation in steps (b) and (d). Finally, the MB3 was extracted with 8M urea, or 6M guanadiniu HCl, and the extract was sonicated for 10 min, using a water bath sonicator. The extract was clarified by centrifugation (12.000 rpm, for 10 min at 4°C), the same volume of a 10% aqueous solution of 3,14-zwittergen (Calbiochem) was added and the solution thoroughly mixed. The solution was again sonicated for 10 min. Any residual material was removed by centrifugation. This mixture was then applied to a Sephacryl S-300 (5x100 cm) column (Pharmacia) equilibrated in a buffer comprised of 0.1 M Tris-HCl, 0.2 M NaCl, 10 mM EDTA, 20 mM CaCl₂ and 0.05% Z 3-14 (pH 8.0). Fractions containing class 2 protein were identified by SDS-PAGE, pooled, and applied to a Hi-Trap Q Sepharose ion exchange column (1 ml) (Pharmacia) equilibrated in 50 mM Tris, 0.2 M NaCl and 1.0 mM EDTA (pH 8.0). A gradient of 0.2-1.0 M NaCl was applied and MB3 protein eluted as a single peak. Figures 14A, 14B and 15 depict the elution profile of purified MB3 in a Sepharose 12 (Pharmacia) connected to an HPLC (Hewlett Packard, model 1090). Based on the comparison with the native wild-type class 3 protein, as well as calibration using molecular weight standards, the elution profile is indicative of trimeric assembly.

Example 12. Preparation of GAMP- TT Conjugate

12.1 Preparation of NMA polysaccharide for conjugation. N meningitidis group A (NMA) strain 604 A was grown in modified Franz medium (Franz, I. D., J. Bad 73:151-161 (1942). Precipitation of the polysaccharide as a cationic detergent complex followed by fractional precipitation with ethanol provided the high molecular NMA capsular polysaccharide. The high molecular weight polysaccharide was further purified by ultra filtration. Partial hydrolysis of the polysaccharide with 100 mM sodium acetate buffer pH 5.0 at 70°C yielded a low molecular weight polysaccharide in the range of 10,000-20,000 daltons. The free reducing terminal residue of the polysaccharide was reduced with

NaBH₄ in the cold to preserve O-acetyl substituents and then oxidized with sodium periodate to generate terminal aldehyde groups. The oxidized polysaccharide was the purified and fractionated by size exclusion chromatography to provide activated group A meningococcal polysaccharide (GAMP) of average molecular weight about 13,000 daltons.

12.2 Preparation of GAM P-TT conjugate. Tetanus toxoid (Serum Statens Institute, Denmark) was first purified to its monomeric form (mw 150,000) by size exclusion chromatography using a Superdex G-200 column (Pharmacia). Freeze-dried tetanus toxoid monomer (1 part by weight) and oxidized GAMP (2.5 part by weight) were dissolved in 0.2 M phosphate buffer pH 7.5. Recrystallized NaBH₃CN ( 1 part) was added and the reaction mixture incubated at 37°C for 4 days. The conjugate was purified from the free components by size exclusion chromatography using a Superdex G-200 column (Pharmacia), and PBS containing 0.01% thimerosal as an eluent. Purified GAMP-tetanus toxoid conjugate was stored at 4°C in this buffer. The polysaccharide content of the conjugate based on phosphorus analysis (Chen assay) was about 18-20% by weight.

Example 13. Preparation of GCMP-TT Conjugate

13.1 Preparation of NMC polysaccharide for conjugation. The capsular polysaccharide was isolated from the growth medium of Neisseria meningitidis group C (NMC) strain C 1 1. This strain was grown in modified Franz medium. The NMC polysaccharide (group C meningococcal polysaccharide (GCMP)) was isolated from the culture medium by cetavlon precipitation as described for the GAMP. Native GCMP was O-deacetylated with base and depolymerized by oxidative cleavage with NaIO₄ to an average molecular weight of 10,000-20,000. The cleaved polysaccharide was sized and purified by gel filtration chromatography to provide a highly purified product of average molecular weight about 12,000 daltons and having aldehyde groups at both termini.

13.2 Preparation of GCMP-TT conjugate. Tetanus toxoid monomer (1 part) and solid oxidized GCMP (1 part) were dissolved in 0.2 M phosphate buffer pH 7.5 and incubated at 37°C with 1 part of recrystallized NaBH₃CN for 4 days. The conjugate was purified from its free components by gel filtration chromatography on Superdex G-200 using PBS containing 0.01% thimerosal as eluent. The purified conjugate was stored at 4°C prior to being formulated for animal studies. The content of the polysaccharide in the conjugate was 33% based on its sialic acid content as measured by the Svennerholm resorcinol assay (Biochim. Biophys. Ada 244:604-61 1 (1957). Example 14. Preparation of N-Propionyl Group B Meningococcal

Polysacch aride-rPorB Conjugate

14.1 Preparation of Neisseria rPorB. Expression of class 3 N. meningitidis porin protein (PorB) in E. coli and purification of porin gene products is described supra. The recombinant rPorB protein was purified by using a sephacryl S-300 molecular sieve column equilibrated with 100 mM Tris- HCl, 200 nM NaCl, 10 mM EDTA, 0.05% Zwittergen 3, 14 (Calbiochem. La Jolla, CA), 0.02% sodium azide pH 8.0. The protein fractions as measured by their OD₂₈₀ eluting with an apparent molecular weight of trimers were pooled and diafiltered against 0.25 M HEPES. 0.25 M NaCl, 0.05% Zwittergen 3, 14 pH 8.5. to a concentration of 10-12 mg/ml.

14.2 Preparation of N-propionylated Group B Meningococcal Polysaccharide (GBMP). The N-propionylated GBMP and its oxidized form were prepared as described in U.S. Patent No. 4,727,136 and EPO 0504202 , both of which are fully incorporated by reference herein.

14.3 Preparation of N-Pr-GBMP-rPorB conjugate. To 10 mg of oxidized N-Pr-GBMP of average molecular weight 12,000 was added 33 μl of a 12 mg/ml of rPorB protein in 0.25 M HEPES, 0.25% M NaCl. 0.05% Zwittergen 3. 14, pH 8.5. The solution was mixed until all solid dissolved and 6.5 mg of recrystallized NaBH₃CN was added. The solution was incubated at 37°C for 4 days and the conjugate was purified from the mixture by using a Superdex G-200 column (Pharmacia) equilibrated with PBS -0.0% thimerosal. Protein fractions were combined and stored at 4°C. The conjugates were analyzed for their sialic acid content by the resorcinol assay and for protein with the Pierce Coomassie Plus assay. The resulting conjugate had a polysaccharide content of about 20-

25% and is devoid of any pyrogens as measured by the LAL and rabbit pyrogenicity tests. Example 15. Analysis of Conjugates by Capillary Electrophoresis

15.1 System and method. Analysis was performed by Capillary Zone Electrophoresis on a Beckman 2000 Series CE system (Beckman Instruments Inc., Fullerton, CA) using an untreated fused silica capillary of dimensions 47 cm total length (40 cm effective length) by 50 μm i.d. (375 μm o.d.) and 0.4N borate buffer, pH 10.2 as electrolyte (Hewlett Packard, Palo Alto, CA). System control and data acquisition was performed using Beckman Gold system software. The voltage was set at 25 KV and the detector was set to 200 nm detection wavelength. The capillary temperature was set to 20°C. The capillary was conditioned between runs with a high pressure rinse for 2.0 minutes with 0.1 M sodium hydroxide followed by 2.0 minutes with deionized water. All samples were pressure injected. All buffer and sample media were filtered through an appropriate 0.2 μm membrane filter and degassed prior to use.

15.2 Analysis of Conjugates. After purification the conjugates were concentrated by ultrafiltration through an Amicon Centricon-3 concentrator

(Amicon, Inc., Beverly, MA). Meningococcal polysaccharide and tetanus toxoid monomer calibration samples were prepared in deionized water at a concentration of 0.25 mg/ml and 0.28 mg/ml, respectively. The method was determined to be selective for the glycoprotein and conjugate components with adjacent components being completely separated (Rs>1.5), as demonstrated in the electropherograms of the polysaccharides and protein spiked glycoprotein conjugates (Fig. 20 and Fig. 21 ). Fig. 20 shows the GAMP-TT conjugate spiked with GAMP and TT-monomer conjugate components, while Fig. 21 shows the GCMP-TT conjugate spiked with GCMP and TT-monomer conjugate components. The lower limit of detection (LLD) for the i^'ree form polysaccharide and protein components for the method was determined to be in the subnanogram level. A lower limit of quantitation (LLQ) of approximately 0.6 ng was obtained for the free form of each component. A linear response was obtained for the selected total mass of each component. A linear response was obtained for the selected total mass range of 0.6-2.6 ng and 0.6-2.4 ng for the polysaccharide and protein, respectively, with a coefficient of determination of 0.99 for both curves. Using this CZE based assay, analysis of a meningococcal polysaccharide-tetanus toxoid conjugate indicated a free polysaccharide content of less than about 5% and a free protein content of less than about 2%.

Example 16. Immunization and Immunoassays

16.1 Trivalent conjugate vaccine formulation. Each individual conjugate component (A, B, C) was absorbed onto Aluminum hydroxide (Al(OH)₃) Alhydrogel (Superfos, Denmark) at a final Al concentration of 1 mg/ml of the trivalent vaccine. Three vaccines were formulated in which the doses of each conjugated polysaccharide varied. Formulations had either about 2 μg of each A, B, and C conjugated polysaccharide; or about 2 μg A conjugated polysaccharide, about 5 μg B conjugated polysaccharide and about 2μg C conjugated polysaccharide; or about 5 μg of each A, B, and C conjugated polysaccharide per dose of 0.2 ml of PBS, 0.01% thimerosal.

16.2 Immunization. Female Balb/c mice (Charles River Laboratories) 4-6 weeks old, were injected i.p. at days 0, 28. and 42. Bleeds were performed al days 0. 14, 28. and 42. and mice were finally exsanguinated at day 52. Sera were stored at -70°C prior to serological analysis. 16.3 Immunoassays:

ELISAs: Antibody titers to each A, N-propionyiated B and C polysaccharides were determined by ELISA using the corresponding HSA conjugates as coating antigen (Figs. 22, 23, and 24). Antibody titer was defined as the x-axis intercept of the linear regression curve of absorbance vs. absorbance x dilution factor. Bactericidal Assays: Bactericidal assays were performed using baby rabbit serum as a source of complement and N. meningilidis strains H 44/76 (Serotype 15), Cl l and Al respectively used as group B meningococcal, group C meningococcal, and group A meningococcal organisms in this assay (Figs. 25, 26, and 27). Bactericidal titer was defined as the serum dilution producing 50% reduction in viable counts.

Having now fully described this invention, it will be understood by those of ordinary skill in the art that the invention can be practiced within a wide and equivalent range of conditions, formulations and other parameters without affecting the scope of the invention or any embodiment thereof. All patents and publications cited herein are fully incorporated by reference herein in their entirety.

Table 1. ELISA and Bactericidal Titers of Group B Meningococcal Conjugate Vaccines (N-Pr GBMP-Protein)

'ST = Stearyl tyrosine.

²CFA = Complete Freund's Adjuvant Table 2. Efficacy of a transformation of yeast (Pichia) cells

Table 3. Expression of MB3 porin protein with recombinant Pichia pastoris

Table 4. The expression of MB3 by recombinant clones with different expression cassettes. The main characteristic of the best clones.

Table 5. Codon Usage for Pichia pastoris and MB3

Claims

What Is Claimed Is:

1. A method for the high level expression of the outer membrane meningococcal group B porin protein or a fusion protein thereof in yeast, comprising: (a) ligating into a plasmid having a selectable marker a gene coding for a protein selected from the group consisting of: (i) a mature porin protein

(ii) a fusion protein which is a mature porin protein fused to a yeast secretion signal peptide; wherein said gene is operably linked to a yeast promoter;

(b) transforming said plasmid containing said gene into a yeast strain;

(c) selecting the transformed yeast by growing said yeast in a culture medium allowing selection of said transformed yeast; (d) growing the transformed yeast, and

(e) inducing expression of said protein to give yeast containing said protein; wherein the protein so expressed comprises more than about 2% of the total protein expressed in said yeast.

2. The method according to claim 1 , wherein the protein so expressed comprises about 3-5% of the total protein expressed in said yeast.

3. The method according to claim 1. wherein said mature porin protein is the Neisseria meningitidis mature outer membrane class 3 protein from serogroup B.

4. The method according to claim 1 , wherein said yeast promoter is the AOXI promoter.

5. The method according to claim 1 , wherein said yeast secretion signal peptide is selected from the group consisting of the secretion signal of the S. cerevisiae α-mating factor prepro-peptide and the secretion signal of the P pastoris acid phosphatase gene.

6. The method according to claim 1 , wherein said plasmid is selected from the group consisting of pHIL-D2, pHIL-S l , pPIC9 and pPIC9K.

7. The method according to claim 1 , wherein said gene comprises a nucleotide sequence that incorporates codons optimized for yeast codon usage.

8. The method according to claim 7, wherein said codons optimized for yeast codon usage are in the 5' region of said gene.

9. The method according to claim 8, wherein said 5 ^' region of said gene is the nucleotide sequence:

5'-gac gtC acT Ttg tac ggT acT att aaG gcT ggT gtT gaG act tec cgc tct gta ttt cac cag aac ggc caa gtt act gaa gtt aca-3'.

10. The method according to claim 8, wherein said yeast is P. pasloris.

1 1. The method of claim 1 wherein said yeast secretes said protein or fusion protein into a growth medium.

12. The method of claim 1 1 wherein said plasmid is selected from the group consisting of pHIL-Sl, pPIC9, and pPIC9K.

13. A method of purifying the outer membrane meningococcal group B porin protein or fusion protein thereof obtained according to the method of claim 1 comprising:

(a) lysing said yeast obtained in step (d) to release said protein or fusion protein as an insoluble membrane bound fraction;

(b) washing said insoluble membrane bound fraction obtained in step (a) with a buffer to remove contaminating yeast cellular proteins;

(c) suspending and dissolving said insoluble membrane bound fraction obtained in step (b) in an aqueous solution of a denaturant;

(d) diluting the solution obtained in step (c) with a detergent; and

(e) purifying said protein or fusion protein by gel filtration and ion exchange chromatography.

14. A method of purifying the outer membrane meningococcal group B porin protein or fusion protein thereof obtained according to the method of claim 1 1 comprising:

(a) centrifuging said yeast culture which has expressed the protein to isolate the protein as soluble secreted material;

(b) removing contaminating yeast culture impurities from the soluble secreted material obtained in step (a) by precipitating said impurities with about 20% ethanol, wherein the soluble secreted material remains in the soluble fraction; (c) precipitating the secreted material from the soluble fraction of step (b) with about 80% ethanol;

(d) washing the precipitated material obtained in step (c) with a buffer to remove contaminating yeast secreted proteins; (e) suspending and dissolving the precipitated material obtained in step (d) in an aqueous solution of detergent; and (f) purifying the protein by ion exchange chromatography.

15. A yeast host cell that contains a gene coding for a protein selected from the group consisting of: (a) a mature porin protein

(b) a fusion protein which is a mature porin protein fused to a yeast secretion signal peptide.

16. The yeast host cell of claim 15, wherein said yeast contains more than one copy of said gene.

17. The yeast host cell of claim 15 wherein said mature porin protein is the Neisseria meningitidis mature outer membrane class 3 protein from serogroup B.

18. The yeast host cell of claim 17 wherein said plasmid is selected from the group consisting of pHIL-D2, pHIL-Sl , pPIC9, pPIC9K and pAO815.

19. The yeast host cell of claim 15, wherein said yeast is P. pasloris.

20. The yeast host cell of claim 15. wherein the 5' region of the gene encoding said protein is encoded by the nucleotide sequence: 5'-gac gtC acT Ttg tac ggT acT att aaG gcT ggT gtT gaG act tec cgc tct gta ttt cac cag aac ggc caa gtt act gaa gtt aca-3'.

21. A nucleotide sequence coding for an outer membrane meningococcal group B porin protein, wherein at least one codon has been changed to optimize yeast codon usage.

22. The nucleotide sequence of claim 21 , wherein said porin protein is the mature outer membrane class 3 protein from serogroup B, and said codon changes are selected from the group of changes consisting of: (GTT to GTC at positions 4-6 of the native sequence), (ACC to ACT at positions 7-9 of the native sequence), (CTG to TTG at positions 10-12 of the native sequence), (GGC to

GGT at positions 16-18 of the native sequence), (ACC to ACT at positions 19-21 of the native sequence), (ATC to ATT at positions 22-24 of the native sequence), (AAA to AAG at positions 25-27 of the native sequence), (GCC to GCT at positions 28-30 of the native sequence), (GGC to GGT at positions 31-33 of the native sequence), (GTA to GTT at positions 34-36 of the native sequence), (GAA to GAG at positions 37-39 of the native sequence); wherein said positions are numbered from the first nucleotide of the native nucleotide sequence encoding said protein.

23. A vaccine comprising group A meningococcal polysaccharide (GAMP), group B meningococcal polysaccharide (GBMP), and group C meningococcal polysaccharide (GCMP) antigens, together with a pharmaceutically acceptable carrier.

24. The vaccine of claim 23, wherein said group A meningococcal polysaccharide (GAMP), group B meningococcal polysaccharide (GBMP), and group C meningococcal polysaccharide (GCMP) antigens are each conjugated to a protein carrier.

25. The vaccine of claim 24, wherein said protein carrier to which said GBMP antigen is conjugated is class 3 N meningilidis porin protein (PorB).

26. The vaccine of claim 24, wherein said protein carrier to which said GAMP antigen and said GCMP antigen are conjugated is tetanus toxoid.

27. The vaccine of claim 25, wherein said GBMP antigen is N- propionylated prior to being conjugated to PorB.

28. The vaccine of claim 24 wherein said vaccine comprises about 2 μg of the GAMP, GCMP and GBMP polysaccharide antigen conjugates.

29. The vaccine of claim 24, wherein said vaccine comprises about 5 μg of the GAMP, GCMP and GBMP polysaccharide antigen conjugates.

30. The vaccine of claim 24. wherein said vaccine comprises about 2 μg of the GAMP and GCMP polysaccharide antigen conjugates, and about 5 μg of the GBMP polysaccharide antigen conjugate.

31. A method of inducing an immune response in a mammal, comprising administering a vaccine comprising group A meningococcal polysaccharide (GAMP), group B meningococcal polysaccharide (GBMP). and group C meningococcal polysaccharide (GCMP) antigens, together with a pharmaceutically acceptable carrier, in an amount sufficient to induce an immune response in a mammal.

32. The method of claim 31 , wherein said group A meningococcal polysaccharide (GAMP), group B meningococcal polysaccharide (GBMP), and group C meningococcal polysaccharide (GCMP) antigens are each conjugated to a protein carrier.

33. The method of claim 31 , wherein said mammal is a human.