US20060177465A1 - Streptococcus antigens - Google Patents

Abstract

Streptococcus polypeptides and polynucleotides encoding them are disclosed. Said polypeptides may be useful vaccine components for the prophylaxis or therapy of streptococcus infection in animals. Also disclosed are recombinant methods of producing the protein antigens as well as diagnostic assays for detecting streptococcus bacterial infection.

Description

• This application claims the benefit of U.S. provisional application 60/212,683 filed Jun. 20, 2000 which is herein incorporated by reference.
FIELD OF THE INVENTION
• The present invention is related to antigens, epitopes and antibodies directed to these epitopes, more particularly polypeptide antigens of streptococcus pneumoniae pathogen which may be useful for prophylaxis, diagnostic or treatment of streptococcal infection.
BACKGROUND OF THE INVENTION
• S. pneumoniae is an important agent of disease in man especially among infants, the elderly and immunocompromised persons. It is a bacterium frequently isolated from patients with invasive diseases such as bacteraemia/septicaemia, pneumonia, meningitis with high morbidity and mortality throughout the world. Even with appropriate antibiotic therapy, pneumococcal infections still result in many deaths. Although the advent of antimicrobial drugs has reduced the overall mortality from pneumococcal disease, the presence of resistant pneumococcal organisms has become a major problem in the world today. Effective pneumococcal vaccines could have a major impact on the morbidity and mortality associated with S. pneumoniae disease. Such vaccines would also potentially be useful to prevent otitis media in infants and young children.
• Efforts to develop a pneumococcal vaccine have generally concentrated on generating immune responses to the pneumococcal capsular polysaccharide. More than 80 pneumococcal capsular serotypes have been identified on the basis of antigenic differences. The currently available pneumococcal vaccine, comprising 23 capsular polysaccharides that most frequently caused disease, has significant shortcomings related primarily to the poor immunogenicity of some capsular polysaccharides, the diversity of the serotypes and the differences in the distribution of serotypes over time, geographic areas and age groups. In particular, the failure of existing vaccines and capsular conjugate vaccines currently in development to protect young children against all serotypes spurres evaluation of other S. pneumoniae components. Although immunogenicity of capsular polysaccharides can be improved, serotype specificity will still represent a major limitation of polysaccharide-based vaccines. The use of a antigenically conserved immunogenic pneumococcal protein antigen, either by itself or in combination with additional components, offers the possibility of a protein-based pneumococcal vaccine.
• PCT WO 98/18930 published May 7, 1998 entitled “Streptococcus Pneumoniae antigens and vaccines” describes certain polypeptides which are claimed to be antigenic. However, no biological activity of these polypeptides is reported. Similarly, no sequence conservation is reported, which is a necessary species common vaccine candidate.
• PCT WO 00/39299 describes polypeptides and polynucleotides encoding these polypeptides. PCT WO 00/39299 demonstrates that polypeptides designated as BVH-3 and BVH-11 provide protection against fatal experimental infection with pneumococci.
• Therefore there remains an unmet need for Streptococcus antigens that may be used as components for the prophylaxis, diagnostic and/or therapy of Streptococcus infection.
SUMMARY OF THE INVENTION
• An isolated polynucleotide comprising a polynucleotide chosen from;
• (a) a polynucleotide encoding a polypeptide having at least 70% identity to a second polypeptide chosen from: table A, B, D, E or H;
• (b) a polynucleotide encoding a polypeptide having at least 95% identity to a second polypeptide chosen from: table A, B, D, E or H;
• (c) a polynucleotide encoding a polypeptide having an amino sequence chosen from table A, B, D, E or H; or fragments, analogs or derivatives thereof;
• (d) a polynucleotide encoding a polypeptide chosen from: table A, B, D, E or H;
• (e) a polynucleotide encoding a polypeptide capable of generating antibodies having binding specificity for a polypeptide having a sequence chosen from: table A, B, D, E or H;
• (f) a polynucleotide encoding an epitope bearing portion of a polypeptide chosen from table A, B, D, E or H; and
• (g) a polynycleotide complementary to a polynucleotide in (a), (b), (c), (d), (e) or (f).
• In other aspects, there are provided novel polypeptides encoded by polynucleotides of the invention, pharmaceutical or vaccine composition, vectors comprising polynucleotides of the invention operably linked to an expression control region, as well as host cells transfected with said vectors and methods of producing polypeptides comprising culturing said host cells under conditions suitable for expression.
BRIEF DESCRIPTION OF THE DRAWINGS
• FIG. 1 is the DNA sequence of SP64 BVH-3 gene; SEQ ID NO: 1.
• FIG. 2 is a DNA sequence containing the complete SP64 BVH-3 gene at nucleotides 1777 to 4896; SEQ ID NO: 2.
• FIG. 3 is the DNA sequence of SP64 BVH-11 gene; SEQ ID NO: 3.
• FIG. 4 is a DNA sequence containing the complete SP64 BVH-11 gene at nucleotides 45 to 2567; SEQ ID NO: 4.
• FIG. 5 is a DNA sequence containing the complete SP64 BVH-11-2 gene at nucleotides 114 to 2630; SEQ ID NO: 5.
• FIG. 6 is the amino acid sequence of SP64 BVH-3 polypeptide; SEQ ID NO: 6.
• FIG. 7 is the amino acid sequence of SP64 BVH-11 polypeptide; SEQ ID NO: 7.
• FIG. 8 is the amino acid sequence of SP64 BVH-11-2 polypeptide; SEQ ID NO: 8.
• FIG. 9 is the DNA sequence of SP63 BVH-3 gene; SEQ ID NO:9.
• FIG. 10 is the amino acid sequence of SP63 BVH-3 polypeptide; SEQ ID NO: 10.
• FIG. 11 is the amino acid sequence of 4D4.9 polypeptide; SEQ ID NO: 11.
• FIG. 12 is the amino acid sequence of 7G11.7 polypeptide; SEQ ID NO: 12.
• FIG. 13 is the amino acid sequence of 7G11.9 polypeptide; SEQ ID NO: 13.
• FIG. 14 is the amino acid sequence of 4D3.4 polypeptide; SEQ ID NO: 14.
• FIG. 15 is the amino acid sequence of 8E3.1 polypeptide; SEQ ID NO: 15.
• FIG. 16 is the amino acid sequence of 1G2.2 polypeptide; SEQ ID NO: 16.
• FIG. 17 is the amino acid sequence of 10C12.7 polypeptide; SEQ ID NO: 17.
• FIG. 18 is the amino acid sequence of 14F6.3 polypeptide; SEQ ID NO: 18.
• FIG. 19 is the amino acid sequence of B12D8.2 polypeptide; SEQ ID NO: 19.
• FIG. 20 is the amino acid sequence of 7F4.1 polypeptide; SEQ ID NO: 20.
• FIG. 21 is the amino acid sequence of 10D7.5 polypeptide; SEQ ID NO: 21.
• FIG. 22 is the amino acid sequence of 10G9.3 polypeptide, 10A2.2 polypeptide and B11B8.1 polypeptide; SEQ ID NO: 22.
• FIG. 23 is the amino acid sequence of 11B8.4 polypeptide; SEQ ID NO: 23.
• FIG. 24 is the amino acid sequence of Mab H11B-11B8 target epitope; SEQ ID 163.
• FIG. 25 is a schematic representation of the BVH-3 gene as well as location of gene sequences coding for the full length and truncated polypeptides. The relationships between DNA fragments are shown with respect to each other.
• FIG. 26 is a schematic representation of the BVH-11 gene as well as location of gene sequences coding for the full length and truncated polypeptides. The relationships between DNA fragments are shown with respect to each other.
• FIG. 27 is a schematic representation of the BVH-11-2 gene as well as location of gene sequences coding for the full length and truncated polypeptides. The relationships between DNA fragments are shown with respect to each other.
• FIG. 28 is a schematic representation of the BVH-3 protein and the location of internal and surface epitopes recognized by certain monoclonal antibodies.
• FIG. 29 is a schematic representation of the BVH-11-2 protein and the location of protective surface epitopes recognized by certain monoclonal antibodies.
• FIG. 30 is a map of plasmid pURV22.HIS. Kan^R, kanamycin-resistance coding region; cI857, bacteriophage λ cI857 temperature-sensitive repressor gene; lambda pL, bacteriophage λ transcription promotor; His-tag, 6-histidine coding region; terminator, T1 transcription terminator; ori, colE1 origin of replication.
• FIG. 31 depicts the comparison of the amino acid sequences of BVH-3M (sp64) and BVH-3 (Sp63) proteins by using the program Clustal W from MacVector sequence analysis software (version 6.5.3). Underneath the alignment, there is a consensus line where * and . characters indicate identical and similar amino acid residues, respectively.
• FIG. 32 depicts the comparison of the amino acid sequences of BVH-3, BVH-11 and BVH-11-2 proteins by using the program Clustal W from MacVector sequence analysis software (version 6.5.3). Underneath the alignment, there is a consensus line where * and . characters indicate identical and similar amino acid residues, respectively.
• FIG. 33 is the DNA sequence of the NEW43 gene (SEQ ID No 257).
• FIG. 34 is the deduced amino acid sequence of NEW43 polypeptide (SEQ ID No 258).
DETAILED DESCRIPTION OF THE INVENTION
• It was determined that portions of the BVH-3 and BVH-11 polypeptides were internal. Other portions were not present in important strains such as encapsulated s. pneumonia causing disease strains. It would be advantageous to have a polypeptide that comprises a portion that is not internal. When large portions of a polypeptide are internal, these portions are not exposed on the bacteria. However, these portions can be very immunogenic in a recombinant polypeptide and will not confer protection against infections. It would also be advantageous to have a polypeptide that comprises a portion that is present in most strains.
• The present invention is concerned with polypeptides in which undesired portions have been deleted and/or modified in order to obtain a specific immune response.
• In accordance with the present invention, there are also provided polypeptides or polynucleotides encoding such polypeptides comprising protective domains.
• Surprisingly, when the undesired portion of the polypeptides are deleted or modified, the polypeptides have desired biological properties. This is surprising in view of the fact that some of these portions were described as being epitope bearing portion in the patent application PCT WO 98/18930. In other publications such as PCT WO 00/37105, portions identified as histidine triad and coil coiled regions were said to be of importance. The present inventors have found that variants of the polypeptide BVH-3 and BVH-11 in which certain portions were deleted and/or modified and chimeras of these polypeptides have biological properties and generate a specific immune response.
• According to one aspect, the present invention provides an isolated polynucleotide encoding a polypeptide having at least 70% identity to a second polypeptide comprising a sequence as disclosed in the present application, the tables and figures.
• In accordance with one aspect of the present invention, there is provided an isolated polynucleotide comprising a polynucleotide chosen from;
• (a) a polynucleotide encoding a polypeptide having at least 70% identity to a second polypeptide chosen from: table B, E or H;
• (b) a polynucleotide encoding a polypeptide having at least 95% identity to a second polypeptide chosen from: table B, E or H;
• (c) a polynucleotide encoding a polypeptide having an amino sequence chosen from table B, E or H or fragments, analogs or derivatives thereof;
• (d) a polynucleotide encoding a polypeptide chosen from: table B, E or H;
• (e) a polynucleotide encoding a polypeptide capable of generating antibodies having binding specificity for a polypeptide having a sequence chosen from: table B, E or H,
• (f) a polynucleotide encoding an epitope bearing portion of a polypeptide chosen from table B, E or H; and
• (g) a polynycleotide complementary to a polynucleotide in (a), (b), (c), (d), (e) or (f).
• According to one aspect, the present invention provides an isolated polynucleotide encoding a polypeptide having at least 70% identity to a second polypeptide comprising a sequence chosen from table A, B, D, E, G or H or fragments, analogues or derivatives thereof.
• According to one aspect, the present invention provides an isolated polynucleotide encoding a polypeptide having at least 95% identity to a second polypeptide comprising a sequence chosen from table A, B, D, E, G or H or fragments, analogues or derivatives thereof.
• According to one aspect, the present invention relates to polypeptides characterised by the amino acid sequence chosen from table A, B, D, E, G or H or fragments, analogues or derivatives thereof.
• According to one aspect, the present invention provides an isolated polynucleotide encoding a polypeptide having at least 70% identity to a second polypeptide comprising a sequence chosen from table A, B, D, E, G or H.
• According to one aspect, the present invention provides an isolated polynucleotide encoding a polypeptide having at least 95% identity to a second polypeptide comprising a sequence chosen from table A, B, D, E, G or H.
• According to one aspect, the present invention relates to polypeptides characterised by the amino acid sequence chosen from table A, B, D, E, G or H.
• According to one aspect, the present invention provides an isolated polynucleotide encoding a polypeptide having at least 70% identity to a second polypeptide comprising a sequence chosen from table B, E or H or fragments, analogues or derivatives thereof.
• According to one aspect, the present invention provides an isolated polynucleotide encoding a polypeptide having at least 95% identity to a second polypeptide comprising a sequence chosen from B, E or H or fragments, analogues or derivatives thereof.
• According to one aspect, the present invention relates to polypeptides characterised by the amino acid sequence chosen from table B, E or H or fragments, analogues or derivatives thereof.
• According to one aspect, the present invention provides an isolated polynucleotide encoding a polypeptide having at least 70% identity to a second polypeptide comprising a sequence chosen from table B, E or H.
• According to one aspect, the present invention provides an isolated polynucleotide encoding a polypeptide having at least 95% identity to a second polypeptide comprising a sequence chosen from B, E or H.
• According to one aspect, the present invention relates to polypeptides characterised by the amino acid sequence chosen from table B, E or H.
• In accordance with the present invention, all nucleotides encoding polypeptides and chimeric polypeptides are within the scope of the present invention.
• In a further embodiment, the polypeptides or chimeric polypeptides in accordance with the present invention are antigenic.
• In a further embodiment, the polypeptides or chimeric polypeptides in accordance with the present invention are immunogenic.
• In a further embodiment, the polypeptides or chimeric polypeptides in accordance with the present invention can elicit an immune response in an individual.
• In a further embodiment, the present invention also relates to polypeptides which are able to raise antibodies having binding specificity to the polypeptides or chimeric polypeptides of the present invention as defined above.
• In one embodiment, the polypeptides of table A (BVH-3) or table D (BVH-11) comprise at least one epitope bearing portion.
• In a further embodiment, the fragments of the polypeptides of the present invention will comprise one or more epitope bearing portion identified in Table C and F. The fragment will comprises at least 15 contiguous amino acid of the polypeptide of table C and F. The fragment will comprises at least 20 contiguous amino acid of the polypeptide of table C and F.
• In a further embodiment, the epitope bearing portion of the polypeptide of table A(BVH-3) comprises at least one polypeptide listed in Table C.
• In a further embodiment, the epitope bearing portion of the polypeptide of table B(BVH-11) comprises at least one polypeptide listed in Table F.
• An antibody that “has binding specificity” is an antibody that recognises and binds the selected polypeptide but which does not substantially recognise and bind other molecules in a sample, such as a biological sample. Specific binding can be measured using an ELISA assay in which the selected polypeptide is used as an antigen.
• Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety. In case of conflict, the present specification, including definitions, will control. In addition, the materials, methods, and examples are illustrative only and not intended to be limiting.
• In accordance with the present invention, “protection” in the biological studies is defined by a significant increase in the survival curve, rate or period. Statistical analysis using the Log rank test to compare survival curves, and Fisher exact test to compare survival rates and numbers of days to death, respectively, might be useful to calculate P values and determine whether the difference between the two groups is statistically significant. P values of 0.05 are regarded as not significant.
• As used herein, “fragments”, “derivatives” or “analogues” of the polypeptides of the invention include those polypeptides in which one or more of the amino acid residues are substituted with a conserved or non-conserved amino acid residue (preferably conserved) and which may be natural or unnatural. In one embodiment, derivatives and analogues of polypeptides of the invention will have about 70% identity with those sequences illustrated in the figures or fragments thereof. That is, 70% of the residues are the same. In a further embodiment, polypeptides will have greater than 75% homology. In a further embodiment, polypeptides will have greater than 80% homology. In a further embodiment, polypeptides will have greater than 85% homology. In a further embodiment, polypeptides will have greater than 90% homology. In a further embodiment, polypeptides will have greater than 95% homology. In a further embodiment, polypeptides will have greater than 99% homology. In a further embodiment, derivatives and analogues of polypeptides of the invention will have less than about 20 amino acid residue substitutions, modifications or deletions and more preferably less than 10. Preferred substitutions are those known in the art as conserved i.e. the substituted residues share physical or chemical properties such as hydrophobicity, size, charge or functional groups.
• The skilled person will appreciate that analogues or derivatives of the proteins or polypeptides of the invention will also find use in the context of the present invention, i.e. as antigenic/immunogenic material. Thus, for instance proteins or polypeptides which include one or more additions, deletions, substitutions or the like are encompassed by the present invention. In addition, it may be possible to replace one amino acid with another of similar “type”. For instance replacing one hydrophobic amino acid with another hydrophilic amino acid.
• One can use a program such as the CLUSTAL program to compare amino acid sequences. This program compares amino acid sequences and finds the optimal alignment by inserting spaces in either sequence as appropriate. It is possible to calculate amino acid identity or similarity (identity plus conservation of amino acid type) for an optimal alignment. A program like BLASTX will align the longest stretch of similar sequences and assign a value to the fit. It is thus possible to obtain a comparison where several regions of similarity are found, each having a different score. Both types of identity analysis are contemplated in the present invention.
• In an alternative approach, the analogues or derivatives could be fusion proteins, incorporating moieties which render purification easier, for example by effectively tagging the desired protein or polypeptide, It may be necessary to remove the “tag” or it may be the case that the fusion protein itself retains sufficient antigenicity to be useful.
• In an additional aspect of the invention there are provided antigenic/immunogenic fragments of the proteins or polypeptides of the invention, or of analogues or derivatives thereof.
• The fragments of the present invention should include one or more such epitopic regions or be sufficiently similar to such regions to retain their antigenic/immunogenic properties. Thus, for fragments according to the present invention the degree of identity is perhaps irrelevant, since they may be 100% identical to a particular part of a protein or polypeptide, analogue or derivative as described herein. The key issue, once again, is that the fragment retains the antigenic/immunogenic properties.
• Thus, what is important for analogues, derivatives and fragments is that they possess at least a degree of the antigenicity/immunogenic of the protein or polypeptide from which they are derived.
• In accordance with the present invention, polypeptides of the invention include both polypeptides and chimeric polypeptides.
• Also included are polypeptides which have fused thereto other compounds which alter the polypeptides biological or pharmacological properties i.e. polyethylene glycol (PEG) to increase half-life; leader or secretory amino acid sequences for ease of purification; prepro- and pro- sequences; and (poly)saccharides.
• Furthermore, in those situations where amino acid regions are found to be polymorphic, it may be desirable to vary one or more particular amino acids to more effectively mimic the different epitopes of the different streptococcus strains.
• Moreover, the polypeptides of the present invention can be modified by terminal —NH₂ acylation (e.g. by acetylation, or thioglycolic acid amidation, terminal carboxy amidation, e.g. with ammonia or methylamine) to provide stability, increased hydrophobicity for linking or binding to a support or other molecule.
• Also contemplated are hetero and homo polypeptide multimers of the polypeptide fragments, analogues and derivatives. These polymeric forms include, for example, one or more polypeptides that have been cross-linked with cross-linkers such as avidin/biotin, gluteraldehyde or dimethylsuperimidate. Such polymeric forms also include polypeptides containing two or more tandem or inverted contiguous sequences, produced from multicistronic mRNAs generated by recombinant DNA technology.
• Preferably, a fragment, analogue or derivative of a polypeptide of the invention will comprise at least one antigenic region i.e. at least one epitope.
• In order to achieve the formation of antigenic polymers (i.e. synthetic multimers), polypeptides may be utilised having bishaloacetyl groups, nitroarylhalides, or the like, where the reagents being specific for thio groups. Therefore, the link between two mercapto groups of the different peptides may be a single bond or may be composed of a linking group of at least two, typically at least four, and not more than 16, but usually not more than about 14 carbon atoms.
• In a particular embodiment, polypeptide fragments, analogues and derivatives of the invention do not contain a methionine (Met) starting residue. Preferably, polypeptides will not incorporate a leader or secretory sequence (signal sequence) . The signal portion of a polypeptide of the invention may be determined according to established molecular biological techniques. In general, the polypeptide of interest may be isolated from a streptococcus culture and subsequently sequenced to determine the initial residue of the mature protein and therefore the sequence of the mature polypeptide.
• According to another aspect, there are provided vaccine compositions comprising one or more streptococcus polypeptides of the invention in admixture with a pharmaceutically acceptable carrier diluent or adjuvant. Suitable adjuvants include oils i.e. Freund's complete or incomplete adjuvant; salts i.e. AlK(SO₄)₂, AlNa(SO₄)₂, AlNH₄(SO₄)₂, silica, kaolin, carbon polynucleotides i.e. poly IC and poly AU. Preferred adjuvants include QuilA and Alhydrogel. Vaccines of the invention may be administered parenterally by injection, rapid infusion, nasopharyngeal absorption, dermoabsorption, or bucal or oral. Pharmaceutically acceptable carriers also include tetanus toxoid.
• The term vaccine is also meant to include antibodies. In accordance with the present invention, there is also provided the use of one or more antibodies having binding specificity for the polypeptides of the present invention for the treatment or prophylaxis of streptococcus infection and/or diseases and symptoms mediated by streptococcus infection.
• Vaccine compositions of the invention are used for the treatment or prophylaxis of streptococcus infection and/or diseases and symptoms mediated by streptococcus infection as described in P. R. Murray (Ed, in chief), E. J. Baron, M. A. Pfaller, F. C. Tenover and R. H. Yolken. Manual of Clinical Microbiology, ASM Press, Washington, D.C. sixth edition, 1995, 1482p which are herein incorporated by reference. In one embodiment, vaccine compositions of the present invention are used for the treatment or prophylaxis of meningitis, otitis media, bacteremia or pneumonia. In one embodiment, vaccine compositions of the invention are used for the treatment or prophylaxis of streptococcus infection and/or diseases and symptoms mediated by streptococcus infection, in particular S. pneumoniae, group A streptococcus (pyogenes), group B streptococcus (GBS or agalactiae), dysgalactiae, uberis, nocardia as well as Staphylococcus aureus. In a further embodiment, the streptococcus infection is S. pneumoniae.
• In a particular embodiment, vaccines are administered to those individuals at risk of streptococcus infection such as infants, elderly and immunocompromised individuals.
• As used in the present application, the term “individuals” include mammals. In a further embodiment, the mammal is human.
• Vaccine compositions are preferably in unit dosage form of about 0.001 to 100 μg/kg (antigen/body weight) and more preferably 0.01 to 10 μg/kg and most preferably 0.1 to 1 μg/kg 1 to 3 times with an interval of about 1 to 6 week intervals between immunizations.
• Vaccine compositions are preferably in unit dosage form of about 0.1 μg to 10 mg and more preferably 1 μg to 1 mg and most preferably 10 to 100 μg 1 to 3 times with an interval of about 1 to 6 week intervals between immunizations.
• According to another aspect, there are provided polynucleotides encoding polypeptides characterised by the amino acid sequence chosen from table A, B, D, E, G or H or fragments, analogues or derivatives thereof.
• According to another aspect, there are provided polynucleotides encoding polypeptides characterised by the amino acid sequence chosen from table B, E or H or fragments, analogues or derivatives thereof.
• In one embodiment, polynucleotides are those illustrated in table A, B, D, E, G or H which encodes polypeptides of the invention.
• In one embodiment, polynucleotides are those illustrated in table B, E or H which encodes polypeptides of the invention.
• It will be appreciated that the polynucleotide sequences illustrated in the figures may be altered with degenerate codons yet still encode the polypeptides of the invention. Accordingly the present invention further provides polynucleotides which hybridise to the polynucleotide sequences herein above described (or the complement sequences thereof) having 50% identity between sequences. In one embodiment, at least 70% identity between sequences. In one embodiment, at least 75% identity between sequences. In one embodiment, at least 80% identity between sequences. In one embodiment, at least 85% identity between sequences. In one embodiment, at least 90% identity between sequences. In a further embodiment, polynucleotides are hybridizable under stringent conditions i.e. having at least 95% identity. In a further embodiment, more than 97% identity.
• Suitable stringent conditions for hybridation can be readily determined by one of skilled in the art (see for example Sambrook et al., (1989) Molecular cloning: A Laboratory Manual, 2^nd ed, Cold Spring Harbor, N.Y.; Current Protocols in Molecular Biology, (1999) Edited by Ausubel F. M. et al., John Wiley & Sons, Inc., N.Y.).
• In a further embodiment, the present invention provides polynucleotides that hybridise under stringent conditions to either
• • (a) a DNA sequence encoding a polypeptide or
  • (b) the complement of a DNA sequence encoding a polypeptide;
    wherein said polypeptide comprising a sequence chosen from table A, B, D, E, G or H or fragments or analogues thereof.
• In a further embodiment, the present invention provides polynucleotides that hybridise under stringent conditions to either
• • (c) a DNA sequence encoding a polypeptide or
  • (d) the complement of a DNA sequence encoding a polypeptide;
    wherein said polypeptide comprising a sequence chosen from table B, E or H or fragments or analogues thereof.
• In a further embodiment, the present invention provides polynucleotides that hybridise under stringent conditions to either
• • (a) a DNA sequence encoding a polypeptide or
  • (b) the complement of a DNA sequence encoding a polypeptide;
    wherein said polypeptide comprises at least 10 contiguous amino acid residues from a polypeptide comprising a sequence chosen from table A, B, D, E, G or H or fragments or analogues thereof.
• In a further embodiment, the present invention provides polynucleotides that hybridise under stringent conditions to either
• • (c) a DNA sequence encoding a polypeptide or
  • (d) the complement of a DNA sequence encoding a polypeptide;
    wherein said polypeptide comprises at least 10 contiguous amino acid residues from a polypeptide comprising a sequence chosen from table B, E or H or fragments or analogues thereof.
• In a further embodiment, polynucleotides are those encoding polypeptides of the invention illustrated in table A, B, D, E, G or H.
• As will be readily appreciated by one skilled in the art, polynucleotides include both DNA and RNA.
• The present invention also includes polynucleotides complementary to the polynucleotides described in the present application.
• In a further aspect, polynucleotides encoding polypeptides of the invention, or fragments, analogues or derivatives thereof, may be used in a DNA immunization method. That is, they can be incorporated into a vector which is replicable and expressible upon injection thereby producing the antigenic polypeptide in vivo. For example polynucleotides may be incorporated into a plasmid vector under the control of the CMV promoter which is functional in eukaryotic cells. Preferably the vector is injected intramuscularly.
• According to another aspect, there is provided a process for producing polypeptides of the invention by recombinant techniques by expressing a polynucleotide encoding said polypeptide in a host cell and recovering the expressed polypeptide product. Alternatively, the polypeptides can be produced according to established synthetic chemical techniques i.e. solution phase or solid phase synthesis of oligopeptides which are ligated to produce the full polypeptide (block ligation).
• General methods for obtention and evaluation of polynucleotides and polypeptides are described in the following references: Sambrook et al, Molecular Cloning: A Laboratory Manual, 2^nd ed, Cold Spring Harbor, N.Y., 1989; Current Protocols in Molecular Biology, Edited by Ausubel F. M. et al., John Wiley and Sons, Inc. New York; PCR Cloning Protocols, from Molecular Cloning to Genetic Engineering, Edited by White B. A., Humana Press, Totowa, N.J., 1997, 490 pages; Protein Purification, Principles and Practices, Scopes R. K., Springer-Verlag, New York, 3^rd Edition, 1993, 380 pages; Current Protocols in Immunology, Edited by Coligan J. E. et al., John Wiley & Sons Inc., New York which are herein incorporated by reference.
• For recombinant production, host cells are transfected with vectors which encode the polypeptide, and then cultured in a nutrient media modified as appropriate for activating promoters, selecting transformants or amplifying the genes. Suitable vectors are those that are viable and replicable in the chosen host and include chromosomal, non-chromosomal and synthetic DNA sequences e.g. bacterial plasmids, phage DNA, baculovirus, yeast plasmids, vectors derived from combinations of plasmids and phage DNA. The polypeptide sequence may be incorporated in the vector at the appropriate site using restriction enzymes such that it is operably linked to an expression control region comprising a promoter, ribosome binding site (consensus region or Shine-Dalgarno sequence), and optionally an operator (control element). One can select individual components of the expression control region that are appropriate for a given host and vector according to established molecular biology principles (Sambrook et al, Molecular Cloning: A Laboratory Manual, 2^nd ed, Cold Spring Harbor, N.Y., 1989; Current Protocols in Molecular Biology, Edited by Ausubel F. M. et al., John Wiley and Sons, Inc. New York incorporated herein by reference). Suitable promoters include but are not limited to LTR or SV40 promoter, E. coli lac, tac or trp promoters and the phage lambda P_L promoter. Vectors will preferably incorporate an origin of replication as well as selection markers i.e. ampicilin resistance gene. Suitable bacterial vectors include pET, pQE70, pQE60, pQE-9, pbs, pD10 phagescript, psiX174, pbluescript SK, pbsks, pNH8A, pNH16a, pNH18A, pNH46A, ptrc99a, pKK223-3, pKK233-3, pDR540, pRIT5 and eukaryotic vectors pBlueBacIII, pWLNEO, pSV2CAT, pOG44, pXT1, pSG, pSVK3, pBPV, pMSG and pSVL. Host cells may be bacterial i.e. E. coli, Bacillus subtilis, Streptomyces; fungal i.e. Aspergillus niger, Aspergillus nidulins; yeast i.e. Saccharomyces or eukaryotic i.e. CHO, COS.
• Upon expression of the polypeptide in culture, cells are typically harvested by centrifugation then disrupted by physical or chemical means (if the expressed polypeptide is not secreted into the media) and the resulting crude extract retained to isolate the polypeptide of interest. Purification of the polypeptide from culture media or lysate may be achieved by established techniques depending on the properties of the polypeptide i.e. using ammonium sulfate or ethanol precipitation, acid extraction, anion or cation exchange chromatography, phosphocellulose chromatography, hydrophobic interaction chromatography, hydroxylapatite chromatography and lectin chromatography. Final purification may be achieved using HPLC.
• The polypeptide may be expressed with or without a leader or secretion sequence. In the former case the leader may be removed using post-translational processing (see U.S. Pat. No. 4,431,739; U.S. Pat. No. 4,425,437; and U.S. Pat. No. 4,338,397 incorporated herein by reference) or be chemically removed subsequent to purifying the expressed polypeptide.
• According to a further aspect, the streptococcus polypeptides of the invention may be used in a diagnostic test for streptococcus infection, in particular S. pneumoniae infection. Several diagnostic methods are possible, for example detecting streptococcus organism in a biological sample, the following procedure may be followed:
• a) obtaining a biological sample from a patient;
• b) incubating an antibody or fragment thereof reactive with a streptococcus polypeptide of the invention with the biological sample to form a mixture; and
• c) detecting specifically bound antibody or bound fragment in the mixture which indicates the presence of streptococcus.
• Alternatively, a method for the detection of antibody specific to a streptococcus antigen in a biological sample containing or suspected of containing said antibody may be performed as follows:
• a) obtaining a biological sample from a patient;
• b) incubating one or more streptococcus polypeptides of the invention or fragments thereof with the biological sample to form a mixture; and
• c) detecting specifically bound antigen or bound fragment in the mixture which indicates the presence of antibody specific to streptococcus.
• One of skill in the art will recognize that this diagnostic test may take several forms, including an immunological test such as an enzyme-linked immunosorbent assay (ELISA), a radioimmunoassay or a latex agglutination assay, essentially to determine whether antibodies specific for the polypeptide are present in an organism.
• The DNA sequences encoding polypeptides of the invention may also be used to design DNA probes for use in detecting the presence of streptococcus in a biological sample suspected of containing such bacteria. The detection method of this invention comprises:
• a) obtaining the biological sample from a patient;
• b) incubating one or more DNA probes having a DNA sequence encoding a polypeptide of the invention or fragments thereof with the biological sample to form a mixture; and
• c) detecting specifically bound DNA probe in the mixture which indicates the presence of streptococcus bacteria.
• The DNA probes of this invention may also be used for detecting circulating streptococcus i.e. S. pneumoniae nucleic acids in a sample, for example using a polymerase chain reaction, as a method of diagnosing streptococcus infections. The probe may be synthesized using conventional techniques and may be immobilized on a solid phase, or may be labelled with a detectable label. A preferred DNA probe for this application is an oligomer having a sequence complementary to at least about 6 contiguous nucleotides of the streptococcus pneumoniae polypeptides of the invention.
• Another diagnostic method for the detection of streptococcus in a patient comprises:
• a) labelling an antibody reactive with a polypeptide of the invention or fragment thereof with a detectable label;
• b) administering the labelled antibody or labelled fragment to the patient; and
• c) detecting specifically bound labelled antibody or labelled fragment in the patient which indicates the presence of streptococcus.
• A further aspect of the invention is the use of the streptococcus polypeptides of the invention as immunogens for the production of specific antibodies for the diagnosis and in particular the treatment of streptococcus infection. Suitable antibodies may be determined using appropriate screening methods, for example by measuring the ability of a particular antibody to passively protect against streptococcus infection in a test model. One example of an animal model is the mouse model described in the examples herein. The antibody may be a whole antibody or an antigen-binding fragment thereof and may belong to any immunoglobulin class. The antibody or fragment may be of animal origin, specifically of mammalian origin and more specifically of murine, rat or human origin. It may be a natural antibody or a fragment thereof, or if desired, a recombinant antibody or antibody fragment. The term recombinant antibody or antibody fragment means antibody or antibody fragment which was produced using molecular biology techniques. The antibody or antibody fragments may be polyclonal, or preferably monoclonal. It may be specific for a number of epitopes associated with the streptococcus pneumoniae polypeptides but is preferably specific for one.
• A further aspect of the invention is the use of the antibodies directed to the streptococcus polypeptides of the invention for passive immunization. One could use the antibodies described in the present application. Suitable antibodies may be determined using appropriate screening methods, for example by measuring the ability of a particular antibody to passively protect against streptococcus infection in a test model. One example of an animal model is the mouse model described in the examples herein. The antibody may be a whole antibody or an antigen-binding fragment thereof and may belong to any immunoglobulin class. The antibody or fragment may be of animal origin, specifically of mammalian origin and more specifically of murine, rat or human origin. It may be a natural antibody or a fragment thereof, or if desired, a recombinant antibody or antibody fragment. The term recombinant antibody or antibody fragment means antibody or antibody fragment which was produced using molecular biology techniques. The antibody or antibody fragments may be polyclonal, or preferably monoclonal. It may be specific for a number of epitopes associated with the streptococcus pneumoniae polypeptides but is preferably specific for one.
• The following are reference tables summarizing the sequences disclosed in the present application:
• TABLE A, B and C Variants and Epitope of BVH-3

  	TABLE A
  	Family	Polypeptide SEQ ID NO
  	BVH-3
  	New 21	aa 396-1039 of SEQ ID. 6
  	New 25	aa 233-1039 of SEQ ID. 6
  	New 40	aa 408-1039 of SEQ ID. 6

• 	TABLE B
  	Family	Polypeptide SEQ ID NO
  	BVH-3
  	NEW1-mut1**	255
  	NEW35A	256
  	NEW42	349
  	NEW49	350
  	NEW50	351
  	NEW51	352
  	NEW52	353
  	NEW53	354
  	NEW54	355
  	NEW55	356
  	NEW56	357
  	NEW56-mut2**	358
  	NEW56-mut3**	359
  	NEW57	360
  	NEW63	361
  	NEW64	362
  	NEW65	363
  	NEW66	364
  	NEW76	365
  	NEW105	366
  	NEW106	367
  	NEW107	368
  	**silent mutation, i.e. the polypeptide is the same as New1 or New 56

• TABLE C
  Epitopes of BVH-3

  	7G11.7	12
  	7G11.9	13
  	B12D8.2	19
  	7F4.1	20
  	14F6.3	18
  	4D3.4	14
  	10C12.7	17
  	8E3.1	15
  	1G2.2	16

• TABLE D, E and F Variants and Epitope of BVH-11

  	TABLE D
  	Family	Polypeptide SEQ ID NO
  	BVH-11
  	New19	aa 497-838 of Seq. ID 8
  	New24	aa 227-838 of Seq. ID 8

• 	TABLE E
  	Family	Polypeptide SEQ ID NO
  	BVH-11
  	New 43	258
  	NEW60	293
  	NEW61	294
  	NEW62	295
  	NEW80	296
  	NEW81	297
  	NEW82	298
  	NEW83	299
  	NEW84	300
  	NEW85	301
  	NEW88D1	302
  	NEW88D2	303
  	NEW88	304

• TABLE F
  epitopes of BVH-11

  	10D7.5	21
  	10G9.3	22
  	B11B8.1	22
  	10A2.2	22
  	11b8.4	23
  	3A4.1	24

• TABLE G and H Chimeras

  TABLE G
  Family	Polypeptide SEQ ID NO

  Chimeras with BVH-11
  and BVH-3
  New17	M*-NEW5-G*P*-NEW1	(376)
  New20	M*-NEW1-G*P*-NEW5	(377)
  New26	M*-NEW10-G*P*-NEW25	(378)
  New27	M*-NEW19-G*P*-NEW25	(379)
  New28	M*-NEW10-G*P*-NEW1	(380)
  New29	M*-NEW5-G*P*-NEW25	(381)
  New30	M*-NEW4-G*P*-NEW25	(382)
  New31	M*-NEW4-G*P*-NEW1	(383)
  NEW32	M*-NE19-G*P*-NEW1	(384)
  *OPTIONAL AMINO ACID

• 	TABLE H
  	Family	Polypeptide SEQ ID NO.
  	Chimeras with BVH-
  	11 and BVH-3
  	VP 89	369
  	VP 90	370
  	VP 91	371
  	VP 92	372
  	VP 93	373
  	VP 94	332
  	VP 108	333
  	VP 109	334
  	VP 110	335
  	VP 111	336
  	VP 112	337
  	VP 113	338
  	VP 114	339
  	VP 115	340
  	VP 116	341
  	VP 117	342
  	VP 119	343
  	VP 120	344
  	VP 121	345
  	VP 122	346
  	VP 123	347
  	VP 124	348

EXAMPLE 1
• This example describes the bacterial strains, plasmids, PCR primers, recombinant proteins and hybridoma antibodies used herein.
• S. pneumoniae SP64 (serogroup 6) and SP63 (serogroup 9) clinical isolates were provided by the Laboratoire de la Santé Publique du Québec, Sainte-Anne-de-Bellevue; Rx1 strain, a nonencapsulated derivative of the type 2 strain D39 and the type 3 strain WU2 were provided by David E. Briles from University of Alabama, Birmingham and the type 3 clinical isolate P4241 was provided by the Centre de Recherche en Infectiologie du Centre Hospitalier de l'Universite Laval, Sainte-Foy. E. coli strains DH5α (Gibco BRL, Gaithesburg, Md.); AD494 (λDE3) (Novagen, Madison, Wis.) and BL21 (λDE3) (Novagen) as well as plasmid superlinker pSL301 vector (Invitrogen, San Diego, Calif.); PCMV-GH vector (gift from Dr. Stephen A. Johnston, Department for Biochemistry, University of Texas, Dallas, Tex.); pET32 and pET21 (Novagen) and pURV22.HIS expression vectors (FIG. 30) were used in this study. The pURV22.HIS vector contains a cassette of the bacteriophage λ cI857 temperature-sensitive repressor gene from which the functional P_R promoter has been deleted. The inactivation of the cI857 repressor by a temperature increase from the range of 30-37° C. to 37-42° C. results in the induction of the gene under the control of promoter λPL. The PCR primers used for the generation of the recombinant plasmids had a restriction endonuclease site at the 5′end, thereby allowing directional cloning of the amplified product into the digested plasmid vector. The PCR oligonucleotide primers used are listed in the following Table 1. The location of the gene sequences coding for BVH-3, BVH-11 and BVH-11-2 gene products is summarized in the FIG. 25, FIG. 26 and FIG. 27, respectively.

  TABLE 1
  List of PCR oligonucleotide primers

  	SEQ
  	ID		Nucleotide	Restriction
  Primer	NO	Sequence 5′ - 3′	position	sites

  OCRR	25	cagtagatctgtgcctatgcact	SEQ ID 1:	BglII
  479		aaac	61-78
  			SEQ ID 9:
  			1-18
  OCRR	26	gatctctagactactgctattcc	SEQ ID 2:	XbaI
  480		ttacgctatg	4909-4887
  			SEQ ID 9:
  			2528-2519
  OCRR	27	atcactcgagcattacctggata	SEQ ID 1:	XhoI
  497		atcctgt	1525-1506
  OCRR	28	ctgctaagcttatgaaagattta	SEQ ID 1:	HindIII
  498		gat	1534-1548
  OCRR	29	gatactcgagctgctattccttac	SEQ ID 2:	XhoI
  499			4906-4893
  HAMJ	30	gaatctcgagttaagctgctgct	SEQ ID 1:	XhoI
  172		aattc	675-661
  HAMJ	31	gacgctcgagcgctatgaaatca	SEQ ID 1:	XhoI
  247		gataaattc	3117-3096
  HAMJ	32	gacgctcgagggcattacctgga	SEQ ID 1:	XhoI
  248		taatcctgttcatg	1527-1501
  HAMJ	33	cagtagatctcttcatcatttat	SEQ ID 2:	BglII
  249		tgaaaagagg	1749-1771
  HAMJ	34	ttatttcttccatatggacttga	SEQ ID 1:	NdeI
  278		cagaagagcaaattaag	1414-1437
  HAMJ	35	cgccaagcttcgctatgaaatca	SEQ ID 1:	HindIII
  279		gataaattc	3117-3096
  HAMJ	36	cgccaagcttttccacaatataa	SEQ ID 1:	HindIII
  280		gtcgattgatt	2400-2377
  HAMJ	37	ttatttcttccatatggaagtac	SEQ ID 1:	NdeI
  281		ctatcttggaaaaagaa	2398-2421
  HAMJ	38	ttatttcttccatatggtgccta	SEQ ID 1:	NdeI
  300		tgcactaaaccagc	62-82
  HAMJ	39	ataagaatgcggccgcttccaca	SEQ ID 1:	NotI
  313		atataagtcgattgatt	2400-2377
  OCRR	40	cagtagatctgtgcttatgaact	SEQ ID 3:	BglII
  487		aggtttgc	58-79
  OCRR	41	gatcaagcttgctgctaccttta	SEQ ID 4:	HindII
  488		cttactctc	2577-2556
  HAMJ	42	ctgagatatccgttatcgttcaa	SEQ ID 3:	EcoRV
  171		acc	1060-1075
  HAMJ	43	ctgcaagcttttaaaggggaata	SEQ ID 3:	HindIII
  251		atacg	1059-1045
  HAMJ	44	cagtagatctgcagaagccttcc	SEQ ID 3:	BglII
  264		tatctg	682-700
  HAMJ	45	tcgccaagcttcgttatcgttca	SEQ ID 3:	HindIII
  282		aaccattggg	1060-1081
  HAMJ	46	ataagaatgcggccgccttactc	SEQ ID 3:	NotI
  283		tcctttaataaagccaatagtt	2520-2492
  HAMJ	47	catgccatggacattgatagtct	SEQ ID 3:	NcoI
  284		cttgaaacagc	856-880
  HAMJ	48	cgccaagcttcttactctccttt	SEQ ID 3:	HindIII
  285		aataaagccaatag	2520-2494
  HAMJ	49	cgacaagcttaacatggtcgcta	SEQ ID 3:	HindIII
  286		gcgttacc	2139-2119
  			SEQ ID 5:
  			2210-2190
  HAMJ	50	cataccatgggcctttatgaggc	SEQ ID 3:	NcoI
  287		acctaag	2014-2034
  HAMJ	51	cgacaagcttaagtaaatcttca	SEQ ID 3:	HindIII
  288		gcctctctcag	2376-2353
  HAMJ	52	gataccatggctagcgaccatgt	SEQ ID 3:	NcoI
  289		tcaaagaa	2125-2146
  HAMJ	53	cgccaagcttatcatccactaac	SEQ ID 3:	HindIII
  290		ttgactttatcac	1533-1508
  HAMJ	54	cataccatggatattcttgcctt	SEQ ID 3:	NcoI
  291		cttagctccg	1531-1554
  HAMJ	55	catgccatggtgcttatgaacta	SEQ ID 3:	NcoI
  301		ggtttgc	59-79
  HAMJ	56	cgccaagctttagcgttaccaaa	SEQ ID 3:	HindIII
  302		accattatc	2128-2107
  HAMJ	57	gtattagatctgttcctatgaac	SEQ ID 5:	BglII
  160		ttggtcgtcacca	172-196
  HAMJ	58	cgcctctagactactgtatagga	SEQ ID 5:	XbaI
  186		gccgg	2613-2630
  HAMJ	59	catgccatggaaaacatttcaag	SEQ ID 5:	NcoI
  292		ccttttacgtg	925-948
  HAMJ	60	cgacaagcttctgtataggagcc	SEQ ID 5:	HindIII
  293		ggttgactttc	2627-2604
  HAMJ	61	catgccatggttcgtaaaaataa	SEQ ID 5:	NcoI
  294		ggcagaccaag	2209-2232
  HAMJ	62	catgccatggaagcctattggaa	SEQ ID 5:	NcoI
  297		tgggaag	793-812
  HAMJ	63	catgccatggaagcctattggaa	SEQ ID 5:	NcoI
  352		tgggaagc	793-813
  HAMJ	64	cgccaagcttgtaggtaatttgc	SEQ ID 5:	HindIII
  353		gcatttgg	1673-1653
  HAMJ	65	cgccaagcttctgtataggagcc	SEQ ID 5:	HindIII
  354		ggttgac	2627-2608
  HAMJ	66	catgccatggatattcttgcctt	SEQ ID 5:	NcoI
  355		cttagctcc	1603-1624
  HAMJ	67	ttatttcttccatatgcatggtg	SEQ ID 1:	NdeI
  404		atcatttccattaca	1186-1207
  HAMJ	68	gatgcatatgaatatgcaaccga	SEQ ID 1:	NdeI
  464		gtcagttaagc	697-720
  HAMJ	69	gatgctcgagagcatcaaatccg	SEQ ID 1:	XhoI
  465		tatccatc	1338-1318
  HAMJ	70	gatgcatatggatcatttccatt	SEQ ID 1:	NdeI
  466		acattcca	1192-1212
  HAMJ	71	gacaagcttggcattacctggat	SEQ ID 1:	HindIII
  467		aatcctg	1527-1507
  HAMJ	72	catgccatggaagcctattggaa	SEQ ID 5:	NcoI
  352		tgggaagc	793-813
  HAMJ	73	ataagaatgcggccgccgctatg	SEQ ID 1:	NotI
  470		aaatcagataaattc	3096-3117
  HAMJ	168	atatgggcccctgtataggagcc	SEQ ID 5:	Apa I
  471		ggttgactttc	2626-2604
  HAMJ	169	atatgggcccaatatgcaaccga	SEQ ID 1:	Apa I
  472		gtcagttaagc	720-697
  HAMJ	170	atatgggcccaacatggtcgcta	SEQ ID 3:	Apa I
  350		gcgttacc	2139-2119
  HAMJ	171	tcccgggcccgacttgacagaag	SEQ ID 1:	Apa I
  351		agcaaattaag	1414-1437
  HAMJ	172	catgccatgggacttgacagaag	SEQ ID 1:	NcoI
  358		agcaaattaag	1415-1437
  HAMJ	173	tcccgggccccgctatgaaatca	SEQ ID 1:	Apa I
  359		gataaattc	3116-3096
  HAMJ	174	atatgggcccgacattgatagtc	SEQ ID 3:	Apa I
  403		tcttgaaacagc	856-880
  HAMJ	175	cgccaagcttaacatggtcgcta	SEQ ID 3:	Hind III
  361		gcgttacc	2139-2119
  HAMJ	176	atatgggccccttactctccttt	SEQ ID 3:	Apa I
  483		aataaagccaatag	2520-2494

• Molecular biology techniques were performed according to standard methods. See for example, Sambrook, J., Fritsch, E. F., Maniatis, T., “Molecular cloning. A laboratory manual” Vol.1-2-3 (second edition) Cold Spring Harbour Laboratory Press, 1989, New York, which is herein incorporated by reference. PCR-amplified products were digested with restriction endonucleases and ligated to either linearized plasmid pSL301, pCMV-GH, pET or pURV22.HIS expression vector digested likewise or digested with enzymes that produce compatible cohesive ends. Recombinant psL301 and recombinant pCMV-GH plasmids were digested with restriction enzymes for the in-frame cloning in pET expression vector. When pET vectors were used, clones were first stabilized in E. coli DH5a before introduction into E. coli BL21(λDE3) or AD494 (λDE3) for expression of full-length or truncated BVH-3, BVH-11 or BVH-11-2 molecules. Each of the resultant plasmid constructs was confirmed by nucleotide sequence analysis. The recombinant proteins were expressed as N-terminal fusions with the thioredoxin and His-tag (pET32 expression system); as C-terminal fusions with an His-tag (pET21 expression system); or as N-terminal fusions with an His-tag (pURV22.HIS expression system). The expressed recombinant proteins were purified from supernatant fractions obtained after centrifugation of sonicated IPTG- (pET systems) or heat- (pURV22.HIS) induced E. coli using a His-Bind metal chelation resin (QIAgen, Chatsworth, Calif.). The gene products generated from S. pneumoniae SP64 are listed in the following Table 2. The gene fragment encoding BVH-3-Sp63 protein (amino acid residues 21 to 840 on SEQ ID NO: 10) was generated from S. pneumoniae SP63 using the PCR-primer sets OCRR479-OCRR480 and the cloning vector pSL301. The recombinant pSL301-BVH-3Sp63 was digested for the in-frame cloning in pET32 vector for the expression of the BVH-3-Sp63 molecule.

  TABLE 2
  Lists of truncated BVH-3, BVH-11, BVH-11-2 and
  Chimeric gene products generated from S. pneumoniae SP64

  			Encoded amino
  	Protein		acids (SEQ ID	Cloning
  PCR-primer sets	designation	Identification	No6)	vector
  OCRR479-OCRR480	BVH-3M	BVH-3 w/o ss	21-1039	pSL301
  OCRR479-OCRR497	BVH-3AD	BVH-3 N′ end w/o ss	21-509	pSL301
  HAMJ248-HAMJ249	L-BVH-3AD	BVH-3 N′ end	1-509	pET-21(+)
  OCRR498-OCRR499	BVH-3B	BVH-3 C′ end	512-1039	pSL301
  OCRR479-HAMJ172	BVH-3C	BVH-3 N′ end w/o ss	21-225	pET-32 c(+)
  OCRR487-OCRR488	BVH-11M	BVH-11 w/o ss	20-840	pCMV-GH
  HAMJ251-OCRR487	BVH-11A	BVH-11 N′ end w/o ss	20-353	pET-32 c(+)
  HAMJ171-OCRR488	BVH-11B	BVH-11 C′ end	354-840	pET-32 a(+)
  HAMJ264-OCRR488	BVH-11C	BVH-11 C′ end	228-840	pET-32 a(+)
  HAMJ278-HAMJ279	NEW1	BVH-3 C′ end	472-1039	pET-21b(+)
  HAMJ278-HAMJ280	NEW2	BVH-3 C′ end	472-800	pET-21b(+)
  HAMJ281-HAMJ279	NEW3	BVH-3 C′ end	800-1039	pET-21b(+)
  HAMJ284-HAMJ285	NEW4	BVH-11 C′ end	286-840	pET-21d(+)
  HAMJ284-HAMJ286	NEW5	BVH-11 internal	286-713	pET-21d(+)
  HAMJ287-HAMJ288	NEW6	BVH-11 internal	672-792	pET-21d(+)
  HAMJ285-HAMJ289	NEW7	BVH-11 C′ end	709-840	pET-21d(+)
  HAMJ284-HAMJ290	NEW8	BVH-11 internal	286-511	pET-21d(+)
  HAMJ286-HAMJ291	NEW9	BVH-11 internal	511-713	pET-21d(+)
  HAMJ160-HAMJ186	BVH-11-2M	BVH-11-2 w/o ss	20-838	pSL301
  HAMJ292-HAMJ293	NEW10	BVH-11-2 C′ end	271-838	pET-21d(+)
  HAMJ293-HAMJ294	NEW11	BVH-11-2 C′ end	699-838	pET-21d(+)
  HAMJ282-HAMJ283	NEW13	BVH-11 C′ end	354-840	pET-21b(+)
  HAMJ286-HAMJ297	NEW14	BVH-11-2 internal	227-699	pET-21d(+)
  HAMJ300-HAMJ313	NEW15	BVH-3 N′ end w/o ss	21-800	pET-21b(+)
  HAMJ301-HAMJ302	NEW16	BVH-11 N′ end w/o ss	20-709	pET-21d(+)
  HAMJ352-HAMJ353	NEW18	BVH-11-2 internal	227-520	pET21d(+)
  HAMJ354-HAMJ355	NEW19	BVH-11-2 C′ end	497-838	pET21d(+)
  HAMJ404-HAMJ279	NEW21	BVH-3 C′ end	396-1039	pET21b(+)
  HAMJ464-HAMJ465	NEW22	BVH-3 internal	233-446	pET-21a(+)
  HAMJ466-HAMJ467	NEW23	BVH-3 internal	398-509	pET-21b(+)
  HAMJ352-HAMJ293	NEW24	BVH-11-2 C′ end	227-838	pET-21d(+)
  HAMJ464-HAMJ470	NEW25	BVH-3 C′ end	233-1039	pET-21b(+)
  HAMJ278-HAMJ279	NEW12	Chimera*	M-NEW 1-KL-	pET 21 b (+)
  (NEW 1) HAMJ282-HAMJ283			NEW 13
  (NEW 13)
  HAMJ284-HAMJ350	NEW17	Chimera*	M-NEW 5-GP-	pET 21 d (+)
  (NEW 5) HAMJ351-HAMJ279			NEW 1
  (NEW 1)
  HAMJ358-HAMJ359	NEW20	Chimera*	M-NEW 1-GP-	pET 21 d (+)
  (NEW 1) HAMJ403-HAMJ361			NEW 5
  (NEW 5)
  HAMJ292-HAMJ471	NEW26	Chimera*	M-NEW 10-GP-	pET 21 d (+)
  (NEW 10) HAMJ472-HAMJ470			NEW 25
  (NEW 25)
  HAMJ355-HAMJ471	NEW27	Chimera*	M-NEW 19-GP-	pET 21 d (+)
  (NEW 19) HAMJ472-HAMJ470			NEW 25
  (NEW 25)
  HAMJ292-HAMJ471	NEW28	Chimera*	M-NEW 10-GP-	pET 21 d (+)
  (NEW 10) HAMJ351-HAMJ279			NEW 1
  (NEW 1)
  HAMJ284-HAMJ350	NEW29	Chimera*	M-NEW 5-GP-	pET 21 d (+)
  (NEW 5) HAMJ472-HAMJ470			NEW 25
  (NEW 25)
  HAMJ284-HAMJ483	NEW30	Chimera*	M-NEW 4-GP-	pET 21 d (+)
  (NEW 4) HAMJ472-HAMJ470			NEW 25
  (NEW 25)
  HAMJ284-HAMJ483	NEW31	Chimera*	M-NEW 4-GP-	pET 21 d (+)
  (NEW 4) HAMJ351-HAMJ279			NEW 1
  (NEW 1)
  HAMJ355-HAMJ471	NEW32	Chimera*	M-NEW 19-GP-	pET 21 d (+)
  (NEW 19) HAMJ351-HAMJ279			NEW 1
  (NEW 1)
  w/o ss: without signal sequence. Analysis of the BVH-3, BVH-11 and BVH-11-2 protein sequences suggested the presence of putative hydrophobic leader sequences.
  *encoded amino acids for the chimeras are expressed as the gene product, additional non essential amino acids residue were added M is methionine, K is lysine, L is leucine, G is glycine and P is proline.

• Monoclonal antibody (Mab)-secreting hybridomas were obtained by fusions of spleen cells from immunized mice and non-secreting, HGPRT-deficient mouse myeloma SP2/0 cells by the methods of Fazekas De St-Groth and Scheidegger (J Immunol Methods 35: 1-21, 1980) with modifications (J. Hamel et al. J Med Microbiol 23: 163-170, 1987). Female BALB/c mice (Charles River, St-Constant, Quebec, Canada) were immunized with either BVH-3M (thioredoxin-His.Tag-BVH-3M fusion protein/ pET32 system), BVH-11M (thioredoxin-His.Tag-BVH-llM fusion protein/pET32 system), BVH-11-2M (thioredoxin-His.Tag-BVH-11-2M fusion protein/pET32 system), BVH-11B (thioredoxin-His.Tag-BVH-11B fusion protein/pET32 system), BVH-3M (His.Tag-BVH-3 fusion protein/pURV22.HIS system) or NEW1 (NEW1-His.Tag fusion protein/pET21 system) gene products from S. pneumoniae strain SP64 to generate the Mab series H3-, H11-, H112-, H11B-, H3V-, and HN1-, respectively. Culture supernatants of hybridomas were initially screened by enzyme-linked-immunoassay (ELISA) according to the procedure described by Hamel et al. (Supra) using plates coated with preparations of purified recombinant BVH-3, BVH-11 and/or BVH-11-2 proteins or suspensions of heat-killed S. pneumoniae cells. The Mab-secreting hybridomas selected for further characterization are listed in Table 3 and Table 4 from the following Example 2. The class and subclass of Mab immunoglobulins were determined by ELISA using commercially available reagents (Southern Biotechnology Associates, Birmingham, Ala.).
• Furthermore, the cloning and expression of chimeric gene(s) encoding for chimeric polypeptides and the protection observed after vaccination with these chimeric polypeptides are described.
• BVH-3 and BVH-11 gene fragments corresponding to the 3′end of the genes were amplified by PCR using pairs of oligonucleotides engineered to amplify gene fragments to be included in the chimeric genes. The primers used had a restriction endonuclease site at the 5′ end, thereby allowing directional in-frame cloning of the amplified product into digested plasmid vectors (Table 1 and Table 2). PCR-amplified products were digested with restriction endonucleases and ligated to linearized plasmid pET21 or pSL301 vector. The resultant plasmid constructs were confirmed by nucleotide sequence analysis. The recombinant pET21 plasmids containing a PCR product were linearized by digestion with restriction enzymes for the in-frame cloning of a second DNA fragment and the generation of a chimeric gene encoding for a chimeric pneumococcal protein molecule. Recombinant pSL301 plasmids containing a PCR product were digested with restriction enzymes for the obtention of the DNA inserts. The resulting insert DNA fragments were purified and inserts corresponding to a given chimeric gene were ligated into pET21 vector for the generation of a chimeric gene. The recombinant chimeric polypeptides listed in Table 2 were as C-terminal fusion with an His-tag. The expressed recombinant proteins were purified from supernatant fractions obtained from centrifugation of sonicated IPTG-induced E. coli cultures using a His-Bind metal chelation resin (QIAgen, Chatsworth, Calif.).
• Groups of 8 female BALB/c mice (Charles River) were immunized subcutaneously two times at three-week intervals with 25 μg of either affinity purified HisTag-fusion protein identifed in presence of 15-20 μg of QuilA adjuvant. Ten to 14 days following the last immunization, the mice were challenged challenged intravenously with 10E5-10E6 CFU of S. pneumoniae type 3 strain WU2. The polypeptides and fragments are capable of eliciting a protective immune response.

  TABLE 2A
  			Days to death post-
  Experiment	Immunogen	Alive:Dead	infection
  1	none	0:8	1, 1, 1, 1, 1, 1, 1, 1
  	NEW 1	2:6	1, 2, 2, 2, 2, 2,
  			>14, >14
  	NEW 13	1:7	1, 1, 3, 3, 4, 5, 5,
  			>14
  	NEW 12	6:2	3, 11, 6X >14
  	BVH-3M	1:7	3, 3, 3, 3, 3, 3, 3,
  			>14
  2	none	0:8	1, 1, 1, 1, 1, 1, 1, 1
  	NEW 17	7:1	4, 7 X >14
  	NEW 12	3:5	3, 3, 3, 4, 5, >14,
  			>14, >14
  3	none	0:8	2, 2, 2, 2, 2, 2, 2, 2
  	NEW 18	1:7	2, 2, 2, 2, 3, 3, 3, 3
  	NEW 19	8:0	8 X >14
  	NEW 10	8:0	8 X >14
  	BVH-11-2	8:0	8 X >14

EXAMPLE 2
• This example describes the identification of peptide domains carrying target epitopes using Mabs and recombinant truncated proteins described in example 1.
• Hybridomas were tested by ELISA against truncated BVH-3, BVH-11 or BVH-11-2 gene products in order to characterize the epitopes recognized by the Mabs. The truncated gene products were generated from S. pneumoniae SP64 strain except for BVH-3-Sp63 which was generated from S. pneumoniae SP63 strain. As a positive control, the reactivity of each antibody was examined with full-length BVH-3, BVH-11 or BVH-11-2 recombinant proteins. In some cases, the Mab reactivity was evaluated by Western immunoblotting after separation of the gene product by SDS-PAGE and transfer on nitrocellulose paper. The reactivities observed is set forth in the following Table 3 and Table 4.

  TABLE 3
  ELISA reactivity of BVH-3-reactive Mabs with a panel of eleven BVH-3 gene
  products and the BVH-11M molecule

  Mabs	Gene products tested

  (IgG

  BVH-

  BVH-

  BVH-

  BVH-

  NEW

  NEW

  NEW

  BVH-3

  BVH-

  isotype)

  3M

  3AD

  3B

  3C

  NEW 1

  NEW 2

  NEW 3

  21

  22

  23

  Sp63

  11M

  H3-4F9 (1)

  +

  +

  −

  +

  −

  −

  −

  −

  −

  −

  +

  +

  H3-4D4 (1)

  +

  +

  −

  +

  −

  −

  −

  −

  −

  −

  +

  +

  H3-9H12 (1)

  +

  +

  −

  +

  −

  −

  −

  −

  −

  −

  +

  +

  H3-7G2 (1)

  +

  +

  −

  −

  −

  −

  −

  −

  +

  −

  −

  −

  H3-10A1 (1)

  +

  +

  −

  −

  −

  −

  −

  +

  −

  +

  +

  −

  H3-4D3 (1)

  +

  −

  +

  −

  +

  −

  +

  +

  −

  −

  +

  −

  H11-6E7 (1)

  +

  +

  −

  +

  −

  −

  −

  NT

  NT

  NT

  +

  +

  H11-10H10

  +

  +

  −

  +

  −

  −

  −

  NT

  NT

  NT

  +

  +

  (2a)

  H11-7G11

  +

  +

  +

  +

  +

  +

  −

  NT

  NT

  NT

  +

  +

  (2b)

  H3V-4F3 (1)

  +

  −

  +

  −

  +

  −

  −

  +

  −

  −

  +

  −

  H3V-2F2 (1)

  +

  −

  +

  −

  +

  +

  −

  +

  −

  −

  +

  −

  H3V-7F4 (1)

  +

  −

  +

  −

  +

  +

  −

  +

  −

  −

  +

  −

  H3V-7H3 (1)

  +

  −

  +

  −

  +

  −

  +

  +

  −

  −

  +

  −

  H3V-13B8

  +

  −

  +

  −

  +

  −

  +

  +

  −

  −

  +

  −

  (1)

  H3V-9C2 (1)

  +

  +

  −

  +/−

  −

  −

  −

  −

  +

  −

  +/−

  +/−

  H3V-9C6 (1)

  +

  +

  −

  −

  −

  −

  −

  −

  +

  −

  −

  −

  H3V-16A7

  +

  +

  −

  −

  −

  −

  −

  +

  −

  +

  −

  −

  (1)

  H3V-15A10

  +

  +

  +

  +/−

  +

  +

  −

  +

  +

  +

  +

  +/−

  (1)

  H3V-6B3

  +

  +

  NT

  NT

  +

  +

  −

  +

  +

  −

  NT

  −

  (1/2)

  HN1-5H3

  +

  −

  +

  NT

  +

  −

  −

  +

  −

  −

  +

  −

  (2b)

  HN1-8E3

  +

  −

  +

  NT

  +

  −

  −

  +

  −

  −

  +

  −

  (2a)

  HN1-14F6

  +

  −

  +

  NT

  +

  −

  −

  +

  −

  −

  +

  −

  (2a)

  HN1-2G2 (1)

  +

  −

  +

  NT

  +

  +

  −

  +

  −

  −

  +

  −

  HN1-12D8

  +

  −

  +

  NT

  +

  +

  −

  +

  −

  −

  +

  −

  (2a)

  HN1-14B2

  +

  −

  +

  NT

  +

  +

  −

  +

  −

  −

  +

  −

  (2a)

  HN1-1G2

  +

  −

  +

  NT

  +

  −

  +

  +

  −

  −

  +

  −

  (2a)

  HN1-10C12

  +

  −

  +

  NT

  +

  −

  +

  +

  −

  −

  +

  −

  (1)

  HN1-3E5 (1)

  +

  +

  −

  −

  +

  +

  −

  +

  −

  +

  +

  −

  NT: not tested

  +/−: very low reactivity but higher than background, possible non-specific Mab binding

• TABLE 4
  ELISA reactivity of BVH-11 and/or BVH-11-2-reactive Mabs with a panel of
  fourteen BVH-11 and BVH-11-2 gene products and the BVH-3M molecule

  Gene products tested

  Mabs

  BVH-

  (IgG

  BVH-

  BVH-

  BVH-

  BVH-

  NEW

  NEW

  NEW

  NEW

  NEW

  NEW

  11-

  BVH-

  isotype)

  11M

  11A

  11B

  11C

  5

  NEW 6

  NEW 7

  NEW 8

  NEW 9

  10

  11

  14

  18

  19

  2-M

  3M

  H3-4F9

  +

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  +

  (1)

  H3-4D4

  +

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  +

  (1)

  H3-9H12

  +

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  +

  (1)

  H11-6E7

  +

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  +

  (1)

  H11-

  +

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  +

  10H10

  (2a)

  H11-7G11

  +

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  +

  (2b)

  H11-1B12

  +

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  −

  (1)

  H11-7B9

  +

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  −

  (2a)

  H11-3H5

  +

  −

  +

  +

  +

  −

  −

  −*

  −

  +

  −

  +

  +

  −

  +

  −

  (1)

  H11-10B8

  +

  −

  +

  +

  +

  −

  −

  −*

  −

  +

  −

  +

  +

  −

  +

  −

  (1)

  H11-1A2

  +

  −

  +

  +

  +

  −

  −

  −*

  −

  +

  −

  +

  +

  −

  +

  −

  (1)

  H112-3A1

  +

  −

  +

  NT

  +

  −

  −

  +

  −

  +

  −

  +

  +

  −

  +

  −

  (1)

  H112-

  +

  +/−

  +

  NT

  +

  −

  −

  +

  −

  +

  −

  +

  +

  −

  +

  −

  13C11

  (1)

  H112-

  +

  +

  −

  NT

  +

  −

  −

  +

  −

  +

  −

  +

  +

  −

  +

  −

  10H10

  (1)

  H112-1D8

  +

  +

  −

  NT

  +

  −

  −

  +

  −

  +

  −

  +

  +

  −

  +

  −

  (2a)

  H112-

  +

  −

  +

  NT

  +

  −

  −

  −

  +

  +

  −

  +

  −

  +

  +

  −

  10G9

  (2b)

  H112-

  +

  −

  +

  NT

  +

  −

  −

  +/−

  +

  +

  −

  +

  −

  +

  +

  −

  10A2 (1)

  H112-3E8

  +

  −

  +

  NT

  +

  −

  −

  +/−

  −

  +

  −

  +

  −

  +

  +

  −

  (2a)

  H112-

  +

  −

  +

  NT

  +

  −

  −

  −

  −

  +

  −

  +

  −

  −

  +

  −

  10D7

  (2a)

  H112-2H7

  +

  +

  −

  NT

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  −

  (2a)

  H112-6H7

  +

  +

  −

  NT

  −

  −

  −

  −

  −

  −

  −

  −

  −

  −

  +

  −

  (1)

  H112-3A4

  −

  −

  −

  NT

  −

  −

  −

  −

  −

  +

  +

  −

  −

  +

  +

  −

  (2a)

  H112-

  −

  −

  −

  NT

  −

  −

  −

  −

  −

  +

  +

  −

  −

  +

  +

  −

  10C5 (1)

  H112-

  −

  −

  −

  NT

  −

  −

  −

  −

  −

  +

  +

  −

  −

  +

  +

  −

  14H6 (1)

  H112-7G2

  −

  −

  −

  NT

  −

  −

  −

  −

  −

  +

  −

  +

  +

  −

  +

  −

  (1)

  H112-

  −

  −

  −

  NT

  −

  −

  −

  −

  −

  −

  −

  +

  +

  −

  +

  −

  13H10

  (2a)

  H112-7E8

  +/−

  −

  −

  NT

  −

  −

  −

  −

  −

  −

  −

  −

  +/−

  −

  +

  −

  (2b)

  H112-7H6

  +/−

  −

  −

  NT

  −

  −

  −

  −

  −

  +/−

  −

  −

  −

  −

  +

  −

  (1)

  H11B-

  +

  −

  +

  +

  +

  −

  −

  +

  −

  +

  −

  +

  +

  −

  +

  −

  5F10 (1)

  H11B-

  +

  −

  +

  +

  +

  −

  −

  +

  −

  +

  −

  +

  +

  −

  +

  −

  15G2 (1)

  H11B-

  +

  −

  +

  +

  +

  −

  −

  −

  +

  +

  −

  +

  −

  +

  +

  −

  13D5 (2)

  H11B-

  +

  −

  +

  +

  +

  −

  −

  −

  +

  +

  −

  +

  −

  +

  +

  −

  11B8 (1)

  H11B-

  +

  −

  +

  +

  +

  −

  −

  −

  −

  +

  −

  +

  −

  −

  +

  −

  7E11 (1)

  H11B-1C9

  +

  −

  +

  +

  +

  −

  −

  −

  −

  +

  −

  +

  −

  −

  +

  −

  (1)

  H11B-5E3

  +

  −

  +

  +

  −

  −

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  (2)

  H11B-6E8

  +

  −

  +

  +

  −

  −

  +

  −

  −

  −

  −

  −

  −

  −

  −

  −

  (1)

  NT: not tested

  +/−: very low reactivity but higher than background, possible non-specific Mab binding

  *a strong signal was detected when tested by Western immunoblotting

• The deduced locations of the epitopes are summarized in FIG. 28 and FIG. 29. As can be seen from the data in Table 3, BVH-3-reactive Mabs can be divided into two groups: BVH-3A- and BVH-3B-reactive Mabs with the exception of Mabs H11-7G11 and H3V-15A10 which reacted with both, BVH-3A and BVH-3B molecules. The BVH-3A-reactive Mabs can be subdivided in two subgroups of antibodies depending of their reactivity or lack of reactivity with BVH-3C recombinant protein. Mab reactive with BVH-3C protein recognized epitopes shared by both, BVH-3 and BVH-11 proteins. As can be seen in Table 4, these BVH-3- and BVH-11-cross-reactive Mabs were also reactive with BVH-11A and BVH-11-2M recombinant proteins. BVH-3B-reactive Mabs can be subdivided into three subgroups according to their reactivity with NEW1, NEW2 and NEW3 recombinant proteins. Some Mabs were only reactive with the NEW1 protein while other Mabs were reactive with either, NEW1 and NEW2 or NEW1 and NEW3 recombinant proteins. Mabs H11-7G11 and H3V-15A10 react with epitopes in more than one position on BVH-3. The reactivity of H11-7G11 with BVH-3AD, BVH-3B, BVH-3C, BVH-11A and BVH-11-2M molecules suggests that H11-7G11 epitope might comprised HXXHXH sequence. This sequence is repeated, respectively, 6 and 5 times in BVH-3 and BVH-11/BVH-11-2 protein sequences. The lack of reactivity of Mab H11-7G11 with NEW 10 molecule suggests that the epitope includes the HGDHXH sequence. Multiple-position mapping of H3V-15A10 epitope on BVH-3 is suggested by the reactivity of the Mab with two BVH-3 fragments that do not overlap.
• Interestingly, Mabs H3-7G2, H3V-9C6 and H3V-16A7 were not reactive with BVH-3 Sp63 thus allowing the location of their corresponding epitopes on a 177-amino acid fragment comprised between amino acids 244 and 420 on BVH-3 molecule of S. pneumoniae SP64 (FIG. 31).
• As can be seen from the data in Table 4, the Mabs that are reactive with BVH-11- and/or BVH-11-2 and that do not recognize BVH-3 molecules can be divided into three groups according to their reactivities with BVH-11A and NEW10 recombinant proteins. Some Mabs reacted exclusively with either BVH-11A or NEW10 protein while other Mabs were reactive with both, BVH-11A and NEW10 recombinant proteins.
EXAMPLE 3
• This example describes the construction of BVH-3 and BVH-11-2 gene libraries for the mapping of epitopes.
• BVH-3 and BVH-11-2 gene libraries were constructed using recombinant PCMV-GH and PSL301 plasmid DNA containing respectively, BVH-3 gene sequence spanning nucleotides 1837 to 4909 (SEQ ID NO: 2) or BVH-11-2 gene sequence spanning nucleotides 172 to 2630 (SEQ ID NO: 5) and the Novatope® library construction and screening system (Novagen). The recombinant plasmids containing BVH-3 or BVH-11-2 gene fragment were purified using QIAgen kit (Chatsworth, Calif.) and digested with the restriction enzymes BglII and XbaI respectively. The resulting BglII-XbaI DNA fragments were purified using the QIAquick gel extraction kit from QIAgen and digested with Dnase I for the generation of randomly cleaved DNA. DNA fragments of 50 to 200 bp were purified, treated with T4 DNA polymerase to blunt the target DNA ends and add a single 3′dA residue, and ligated into pSCREEN-T-Vector (Novagen) following the procedures suggested by the manufacturer (Novatope® System, Novagen). The gene libraries of E. coli clones, each of which expressing a small peptide derived from BVH-3 or BVH-11-2 genes were screened by standard colony lift methods using Mabs as immunoprobes. The colony screening was not successful with Mabs producing very high backgrounds on colony lifts. Moreover, in some cases, Mabs failed to detect epitope-expressing-colonies. The lack of reactivity can possibly be explained by the small amount of recombinant proteins produced or the recognition of conformation-dependent epitopes consisting of different protein domains. Sequencing of DNA inserts from positive clones determined the location of the segment that encodes the target epitope. The data are presented in Table 5. The peptides encoded by DNA inserts into the recombinant PSCREEN-T vector can be purified and used as immunogens as described below in Example 6.
• The peptide sequences obtained from the screening of BVH-3 and BVH-11-2 gene libraries with the Mabs are in agreement with the Mab ELISA reactivities against the truncated gene products. As expected, the amino acid sequences obtained from H11-7G11 contained the sequence HGDHXH. These findings provide additional evidence for the location of epitopes recognized with the Mabs. Interestingly, although the Mabs H112-10G9, H112-10A2 and H11B-11B8 were reactive against the same peptide sequence (amino acid residues 594 to 679 on BVH-11-2 protein sequence), clones corresponding to the sequence spanning from amino acid residues 658 to 698 were only picked up by Mab H11B-11B8 thus revealing the location of H11B-11B8 epitope between amino acid residues 658 to 679 (SEQ ID NO: 163). Mabs H112-10G9, H112-10A2, and H11B-11B8 are directed against 3 distinct non overlapping epitopes located closely on the peptide sequence corresponding to amino acid residues 594 to 679 (SEQ ID NO: 22).

  TABLE 5
  Peptide sequences obtained from the screening of BVH-3 and BVH-11-2 gene
  libraries with Mabs

  	Clone/				SEQ
  	Protein	Nucleotide	Amino acid		ID
  Mab	designation	position	position	Amino acid sequence	NO

  H3-4D4	4D4.9	SEQ ID 1:	SEQ ID 6:	DQGYVTSHGDHYHYYNGKVPYDALFSEELLMKDPNYQLKDA	11
  		226-509	76-169	DIVNEVKGGYIIKVDGKYYVYLKDAAHADNVRTKDEINRQK
  				QEHVKDNEKVNS
  H11-	7G11.7	SEQ ID 1:	SEQ ID 6:	GIQAEQIVIKITDQGYVTSHGDHYHYYNGKVPYDALFSEELL	12
  7G11		193-316	64-105
  H11-	7G11.9	SEQ ID 1:	SEQ ID 6:	TAYIVRHCDHFHYIPKSNQIGQPTLPNNSLATPSPSLPI	13
  7G11		1171-1284	390-428
  H3-4D3	4D3.4	SEQ ID 1:	SEQ ID 6:	TSNSTLEEVPTVDPVQEKVAKFAESYGMKLENVLFN	14
  		2565-2670	855-890
  HN1-	8E3.1	SEQ ID 1:	SEQ ID 6:	MDGTIELRLPSGEVIKKNLSDFIA	15
  8E3		3004-3120	1016-1039
  HN1-	1G2.2	SEQ ID 1:	SEQ ID 6:	YGLGLDSVIFNMDGTIELRLPSGEVIKKNLSDFIA	16
  1G2		3017-3120	1005-1039
  HN1-	10C12.7	SEQ ID 1:	SEQ ID 6:	PALEEAPAVDPVQEKLEKFTASYGLGLDSVIFNMDGTIELR	17
  10C12		2936-3120	983-1039	LPSGEVIKKNLSDFIA
  HN1-	14F6.3	SEQ ID 1:	SEQ ID 6:	KVEEPKTSEKVEKEKLSETGNSTSNSTLEEVPTVDPVQEK	18
  14F6		2501-2618	833-872
  HN1-	B12D8.2	SEQ ID 1:	SEQ ID 6:	MKDLDKKIEEKIAGIMKQYGVKRESIVVNKEKNAIIYPHGD	19
  12D8		1433-1767	512-589	HHHADPIDEHKPVGIGHSHSNYELFKPEEGVAKKEGN
  H3V-	7F4.1	SEQ ID 1:	SEQ ID 6:	AIIYPHGDHHHADPIDEHKPVGIGHSHSNYELFKPEEGVAK	20
  7F4		1633-1785	545-595	KEGNKVYTGE
  H112-	10D7.5	SEQ ID 5:	SEQ ID 8:	IQVAKLAGKYTTEDGYIFDPRDITSDEGD	21
  10D7		1685-1765	525-553
  H112-	10G9.3	SEQ ID 5:	SEQ ID 8:	DHQDSGNTEAKGAEAIYNRVKAAKKVPLDRMPYNLQYTVEV	22
  10G9		1893-2150	594-679	KNGSLIIPHYDHYHNIKFEWFDEGLYEAPKGYSLEDLLATV
  				KYYV
  H112-	10A2.2	SEQ ID 5:	SEQ ID 8:	DHQDSGNTEAKGAEAIYNRVKAAKKVPLDRMPYNLQYTVEV	22
  10A2		1893 -2150	594-679	KNGSLIIPHYDHYHNIKFEWFDEGLYEAPKGYSLEDLLATV
  				KYYV
  H11B-	B11B8.1	SEQ ID 5:	SEQ ID 8:	DHQDSGNTEAKGAEATYNRVKAAKKVPLDRMPYNLQYTVEV	22
  11B8		1893-2150	594-679	KNGSLIIPHYDHYHNIKFEWFDEGLYEAPKGYSLEDLLATV
  				KYYV
  H11B-	11B8.4	SEQ ID 5:	SEQ ID 8:	GLYEAPKGYSLEDLLATVKYYVEHPNERPHSDNGFGNASDH	23
  11B8		2085-2217	658-698
  H112-	3A4.1	SEQ ID 5:	SEQ ID 8:	VENSVINAKIADAEALLEKVTDPSIRQNANETLTGLKSSLL	24
  3A4		2421-2626	769-837	LGTKDNNTISAEVDSLLALLKESQPAPI

EXAMPLE 4
• This example describes the immunization of animals with recombinant proteins for the generation of antibody reactive with BVH-3, BVH-11 and/or BVH-11-2.
• NZW rabbits (Charles River Laboratories, St-Constant, Québec, Canada) were immunized subcutaneously at multiple sites with 50 μg or 100 μg of the purified BVH-3M, L-BVH-3AD, NEW1, NEW13, or L-BVH-11 recombinant protein in presence of 80 μg of QuilA adjuvant (Cedarlane Laboratoratories Ltd, Hornby, Canada). The rabbits were boosted two times at three-week intervals with the same antigen and blood samples were collected before each immunization and 6 to 28 days following the last immunization. The sera samples were designated preimmune, post 1^st, post 2^nd or post 3^rd injection. The rabbit immune response to immunization was evaluated by ELISA using recombinant BVH-3M (BVH-3M-His.Tag fusion protein/pET21 system) or BVH-11M (BVH-11M-His.Tag fusion protein/pET21 system) proteins or suspensions of heat-killed S. pneumoniae Rx-1 cells as coating antigens. ELISA titer was defined as the reciprocal of the highest sera dilution at which absorbance A₄₁₀ value was 0.1 above the background value. Antibodies reactive with BVH-3 and/or BVH-11 epitopes were elicited following immunization in all animals as shown in the following Table 6. Antibody reactive with recombinant or pneumococcal antigens was not present in the preimmune sera. The immune response to immunization was detectable in the sera of each rabbit after a single injection of recombinant antigen. The antibody response following the second injection with either antigen tested was characterized by a strong increase in antibody titer. Interestingly, good titers of antibody reactive with S. pneumoniae cells, with an average titer of 52,000 after the third immunization, were obtained, thus establishing that native pneumococcal epitopes are expressed on the recombinant E. coli gene products. These data support the potential use of BVH-3, BVH-11 and/or BVH-11-2 gene products and the antibody raised to BVH-3, BVH-11 and/or BVH-11-2 gene products as vaccines for the prevention and the treatment of pneumococcal disease, respectively.

  TABLE 6
  Rabbit Antibody response to immunization with BVH-3
  and BVH-11 gene products

  	ELISA Titer with coating
  	antigen

  	Immu-	Sera		BVH-	S.
  Rabbit	nogen	sample	BVH-3M	11M	pneumoniae

  #

  15	BVH-3M	Preimmune	NT	NT	200
  	(50 μg)	Post-1st	NT	NT	1,600
  		Post-2nd	NT	NT	20,000
  		Post-3rd	512,000	NT	40,000
  #16	BVH-3M	Preimmune	NT	NT	200
  	(100 μg)	post 1st	NT	NT	1,600
  		post 2nd	NT	NT	40,000
  		post 3rd	106	NT	80,000
  #112	L-BVH-	Preimmune	<100	NT	NT
  	3AD
  	(50 μg)	post 1st	16,000	NT	NT
  		post
  2nd	512,000	NT	NT
  		post
  3rd	2 × 106	NT	32,000
  #113	New 1	Preimmune	<100	NT	NT
  	(50 μg)	post 1st	16,000	NT	NT
  		post
  2nd	512,000	NT	NT
  		post
  3rd	106	NT	64,000
  #114	New 13	Preimmune	NT	<100	NT
  	(50 μg)	post 1st	NT	16,000	NT
  		post
  2nd	NT	64,000	NT
  		post
  3rd	NT	256,000	32,000
  #116	L-BVH-11	Preimmune	NT	<100	NT
  	(50 μg)	post 1st	NT	64,000	NT
  		post
  2nd	NT	106	NT
  		post
  3rd	NT	2 × 106	64,000
  NT: not tested

EXAMPLE 5
• This example describes the protection of animals against fatal experimental pneumococcal infection by administration of antibody raised to BVH-3, BVH-11 or BVH-11-2 gene products.
• High-titer Mab preparations were obtained from ascites fluid of mice inoculated intraperitoneally with Mab-secreting hybridoma cells according to the method described by Brodeur et al (J Immunol Methods 71 :265-272, 1984). Sera samples were collected from rabbits immunized with BVH-3M as described in Example 4. The rabbit sera collected after the third immunization and ascites fluid were used for the purification of antibodies by precipitation using 45 to 50% saturated ammonium sulfate. The antibody preparations were dissolved and dialyzed against phosphate-buffered saline (PBS).
• CBA/N (xid) mice (National Cancer Institute, Frederick, Mass.) were injected intraperitoneally with either 0.1 ml of purified rabbit antibodies or 0.2 ml of ascites fluid before intravenous challenge with approximately 200 CFU of the type 3 S. pneumoniae strain WU2. Control mice received sterile PBS or antibodies purified from preimmune rabbit sera or sera from rabbits immunized with an unrelated N. meningitidis recombinant protein antigen. One group of mice was challenged with S. pneumoniae before the administration of anti-BVH-3 antibody. Samples of the S. pneumoniae challenge inoculum were plated on chocolate agar plates to determine the number of CFU and verify the challenge dose. The CBA/N mice were chosen because of their high susceptibility to S. pneumoniae infection. The LD₅₀ of WU2 injected intravenously to CBA/N mice is estimated to be ≦10 CFU. Deaths were recorded at 24-h intervals for a period of at least 7 days.
• The protection data obtained from mice injected with rabbit anti-BVH-3 antibody are set forth in the following Table 7. Nine out of 10 mice receiving the anti-BVH-3 antibody survived the challenge in contrast to none of 10 mice injected with control antibody or PBS buffer. The observation that antibody raised to the BVH-3-M molecule passively protected even when administered after the challenge demonstrated the ability of anti-BVH-3 antibody to prevent death even from an already established infection.

  TABLE 7
  Protective effects of rabbit antibody to BVH-3-M gene
  in CBA/N mice challenged i.v. with WU2 pneumococci

  Antibody	Time of antibody		Days to death
  preparation	administration	Alive:Dead	post-infection
  Anti-BVH3M	1 h before	5:0	>14, >14, >14,
  	infection		>14, >14
  Anti-N. meningitidis	1 h before	0:5	2, 2, 2, 2, 2
  	infection
  Anti-BVH-3M	0.5 h post-	4:1	2, >14, >14,
  	infection		>14, >14
  None (PBS)	1 h before	0:5	1, 2, 2, 2, 2
  	infection

• CBA/N mice were infected with 1000 CFU of WU2 S. pneumoniae before or after intraperitoneal administration of 0.1 ml of rabbit antibody.
• In an other experiment, 0.1 ml of rabbit antibody prepared from preimmune and immune sera were administered intraperitoneally to CBA/N mice four hours before intranasal challenge with 280 CFU of S. pneumoniae P4241 type 3 strain. As seen in the following Table 8, all immunized mice survived the challenge while none of 9 mice receiving preimmune sera antibody or buffer alone were alive on day 6 post-infection. S. pneumoniae hemocultures on day 11 post-challenge were negative for all surviving mice. Furthermore, 100% protection was observed in mice receiving monoclonal antibodies H112-10G9 or a mixture of H112-10G9 and H11B-7E11 which are directed against BVH-11/BVH-11-2.

  TABLE 8
  Protective effects of passive transfer of rabbit
  antibody to BVH-3-M gene product or anti-BVH-11/BVH-11-2
  specific Mabs in CBA/N mice challenged i.n. with P4241
  pneumococci

  	Antibody		Days to death
  	preparation	Alive:Dead	post-infection
  	Anti-BVH-3M	5:0	>11, >11, >11, >11,
  			>11
  	Antibody from	0:5	3, 3, 3, 6, 6
  	preimmune sera
  	H112-10G9	4:0	>11, >11, >11, >11
  	H112-10G9 + H11B-	5:0	>11, >11, >11, >11,
  	7E11		>11
  	None (PBS)	0:4	3, 3, 3, 3

• Altogether, the results from Table 7 and Table 8 clearly establish that immunization of animals with a BVH-3 gene product such as BVH-3M elicited protective antibodies capable of preventing experimental bacteremia and pneumonia infections.
• The protection data obtained for mice injected with ascites fluid are set forth in the following Table 9. Administration of a volume of 0.2 ml of ascites fluid of 0.2 ml of some sets of ascites fluid prevented death from experimental infection. For example, H112-3A4+H112-10G9 and H112-10G2+H112-10D7 sets of 2 Mabs conferred complete protection against experimental infection. These data indicated that antibody targetting BVH-11and/or BVH-11-2 epitopes gave efficient protection. The Mabs H112-3A4, H112-10G9, H112-10D7, H112-10A2, H112-3E8, H112-10C5, H11B-11B8, H11B-15G2, H11B-1C9, H11B-7E11, H11B-13D5 and H11-10B8 were present in at least one protective pair of Mabs and were said to be protective and reactive against protective epitopes. The locations of protection-conferring epitopes on BVH-11-2 molecules are summarized in Table 10 and FIG. 29. Protective Mabs H112-3A4, H112-10G9, H112-10D7, H112-10A2, H112-3E8, H112-10C5, H11B-11B8, H11B-15G2, H11B-1C9, H11B-7E11, H11B-13D5 and H11-10B8 were all reactive with New 10 protein corresponding to amino acid residues 271 to 838 on the BVH-11-2 molecule. Six out of these 12 Mabs were directed against epitopes present in the NEW 19 protein and 3 protective Mabs recognized NEW 14. Interestingly, Mab H112-3A4 and H112-10C5 reacted with distinct epitopes exclusive to BVH-11-2 located at the carboxyl end comprised between amino acid residues 769 and 837. Also, Mabs H11-7G11, H11-6E7 and H3-4F9 reactive with epitopes shared by pneumococcal BVH-3, BVH-11 and BVH-11-2 molecules did not succeed to protect even if given in combination with protective H112-10G9 or H112-11B8 Mab. These Mabs recognized epitopes located at the amino end of the BVH-3, BVH-11 and BVH-11-2 molecules comprising, respectively, the first 225, 228 and 226 amino acid residues. The comparison of the BVH-3, BVH-11 and BVH-11-2 protein sequences revealed that a large number of amino acids were conserved in the amino end portion comprising these 225-228 residues with a global 72.8% identity (FIG. 32).
• Altogether the data set forth in Table 9 and Table 10 suggest that the protection eliciting BVH-11- and BVH-11-2-epitopes is comprised in the carboxy terminal product containing amino acids 229 to 840 and 227 to 838, on BVH-11 and BVH-11-2 proteins, respectively.

  TABLE 9
  Passive immunization with BVH-11- and/or BVH-11-2-
  specific Mabs can protect mice from lethal experimental
  pneumococcal infection.

  Ex-			Days to death
  periment	Mab	Alive:Dead	post-infection
  1	H112 3A4 + H112-10G9	6:0	6 X >10
  	H112-3A4 + H112-10D7	5:1	4, 5X >10
  	None	0:6	2, 2, 2, 2, 2, 6
  2	H112-10 A2 + H112-10D7	5:1	3, 5X >10
  	H112-3E8 + H112-10G9	6:0	6 X >10
  	None	0:6	2, 2, 2, 2, 2, 2
  3	H112-10D7 + H11B-11B8	6:0	6 X >10
  	H112-10G9 + H11B-15G2	3:3	2, 6, 6, 3 X >10
  	None	0:6	2, 2, 2, 2, 2, 2
  4	H112-10G9 + H112-10D7	5:0	5 X >11
  	None	0:5	2, 2, 2, 2, 2
  5	H112-10G9 + H11-10B8	4:1	8, 4 X >14
  	H112-10G9 + H11B-7E11	5:0	5 X >14
  	None	0:3	1, 2, 2
  6	H112-10G9 + H11B-1C9	4:1	4, 4 X >14
  	None	0:3	2, 2, 2
  7	H112-10C5 + H11B-13D5	5:0	5 X >14
  	None	3:3	2, 2, 2
  CBA/N mice were injected intraperitoneally with a total of 0.2 ml of ascites fluid 4 hours before intravenous challenge with S. pneumoniae WU2.

• TABLE 10
  Deduced locations of protection-conferring
  epitopes on BVH-11-2 molecules.

  			Gene products carrying Mab-
  	Mabs	Protection	epitope
  	H112-3A4	+	NEW 19 and NEW 11
  	H112-10G9	+	NEW 19
  	H112-10D7	+	NEW 14 and NEW 10
  	H112-10A2	+	NEW 19
  	H112-3E8	+	NEW 19
  	H11B-11B8	+	NEW 19
  	H11B-15G2	+	NEW 18
  	H11B-7E11	+	NEW 14 and NEW 10
  	H11-10B8	+	NEW 18
  	H11B-1C9	+	NEW 14 and NEW 10
  	H112-3A1	−	NEW 18 and NEW 8
  	H112-10H10	−	NEW 18 and NEW 8
  	H112-2H7	−	BVH-11-2M
  	H112-6H7	−	BVH-11-2M
  	H11-7G11	−	BVH-11A and BVH-3C
  	H11-6E7	−	BVH-11A and BVH-3C
  	H112-10C5	+	NEW 19, NEW11 and 3A4.1
  	H11B-13D5	+	NEW 19
  	H112-7G2	−	NEW 18
  	H112-7E8	−	BVH-11-2M
  	H3-4F9	−	BVH-11A and BVH-3C

• Altogether the data presented in this example substantiate the potential use of antibodies raised to BVH-3, BVH-11 or BVH-11-2 molecules as therapeutic means to prevent, diagnose or treat S. pneumoniae diseases.
EXAMPLE 6
• This example describes the localization of surface-exposed peptide domains using Mabs described in Example 1.
• S. pneumoniae type 3 strain WU2 was grown in Todd Hewitt (TH) broth (Difco Laboratories, Detroit Mich.) enriched with 0.5% Yeast extract (Difco Laboratories) at 37° C. in a 8% CO₂ atmosphere to give an OD₆₀₀ of 0.260 (˜10⁸ CFU/ml). The bacterial suspension was then aliquoted in 1 ml samples and the S. pneumoniae cells were pelletted by centrifugation and resuspended in hybridoma culture supernatants. The bacterial suspensions were then incubated for 2 h at 4° C. Samples were washed twice in blocking buffer [PBS containing 2% bovine serum albumin (BSA)], and then 1 ml of goat fluorescein (FITC)-conjugated anti-mouse IgG+IgM diluted in blocking buffer was added. After an additional incubation of 60 min at room temperature, samples were washed twice in blocking buffer and fixed with 0.25% formaldehyde in PBS buffer for 18-24 h at 4° C. Cells were washed once in PBS buffer and resuspended in 500 μl of PBS buffer. Cells were kept in the dark at 4° C. until analyzed by flow cytometry (Epics® XL; Beckman Coulter, Inc.). Ten thousands (10,000) cells were analyzed per sample and the results were expressed as % Fluorescence and Fluorescence index (FI) values. The % Fluorescence is the number of fluorescein-labelled S. pneumoniae cells divided by 100 and the FI value is the median fluorescence value of pneumococci treated with Mab supernatant divided by the fluorescence value of pneumococci treated with the conjugate alone or with a control unrelated Mab. A FI value of 1 indicated that the Mab has not been detected at the surface of the bacteria whereas a FI value higher than 2 was considered positive when at least 10% of the pneumococcal cells were labelled and indicated that the Mab was reactive with cell-surface exposed epitopes. The following Table 11 summarized the data obtained with the Mabs tested by flow cytometry.
• Flow cytometric analysis revealed that the Mabs reactive with BVH-3C and/or BVH-11A molecules did not bind to the cell surface. In contrast, with the exception of Mabs H3V-9C6 and H3V-16A7, the Mabs reactive with NEW 1, NEW 2, NEW 3, NEW 22 or NEW 23 BVH-3 gene products were detected at the surface of pneumococci. These data indicated that the first 225 amino acid residues located at the amino end of BVH-3 are internal. The lack of binding of Mabs H3V-9C6 and H3V-16A7 suggest some portions of the sequence corresponding to the 177-amino acids absent from the BVH-3 molecule of S. pneumoniae SP63 appears not to be accessible to antibodies.
• Results from BVH-11- and/or BVH-11-2-reactive Mabs revealed that there is a good correlation between surface-exposure and protection. All Mabs reactive with internal epitopes as determined by the flow cytometry assay were not protective whereas all the protective Mabs described in Example 5 gave a positive signal in flow cytometry. Although an FI value of 9.0 and a % Fluorescence of 81.2 were obtained with Mab H11-7G11, this Mab was not shown to protect. Additional assays can be used to further evaluate whether this Mab and its corresponding epitope might participate in anti-infectious immunity.

  TABLE 11
  Results from the binding of Mabs at the surface of
  S. pneumoniae by flow cytometry analysis

  	%			Gene products carrying
  Mab	Fluorescence	FI	Binding	Mab-epitope

  H3-4F9	3.4	1.2	−	BVH-3C and BVH-11A
  H3-4D4	3.4	1.2	−	BVH-3C and BVH-11A
  H3-9H12	2.5	1.1	−	BVH-3C and BVH-11A
  H3-7G2	66.2	6.3	+	NEW 22
  H3-10A1	58.8	5.6	+	NEW 23
  H3-4D3	33.2	3.5	+	NEW 3
  H3V-4F3	24.4	2.9	+	NEW 1
  H3V-2F2	15.6	2.4	+	NEW 2
  H3V-7F4	58.7	5.6	+	NEW 2
  H3V-7H3	68.8	6.9	+	NEW 3
  H3V-13B8	75.0	7.7	+	NEW 3
  H3V-9C2	66.4	6.2	+	NEW 22
  H3V-9C6	2.9	1.0	−	NEW 22
  H3V-16A7	6.6	1.7	−	NEW 23
  H3V-	58.7	5.7	+	NEW 22 and NEW 23
  15A10
  HN1-5H3	43.4	5.3	+	NEW 1
  HN1-8E3	57.4	6.6	+	NEW 1
  HN1-14F6	57.8	6.7	+	NEW 1
  HN1-2G2	54.8	6.3	+	NEW 2
  HN1-12D8	14.3	3.0	+	NEW 2
  HN1-14B2	11.5	2.7	+	NEW 2
  HN1-1G2	59.9	7.0	+	NEW 3
  HN1-	13.6	2.8	+	NEW 3
  10C12
  H11-6E7	4.9	1.2	−	BVH-3C and BVH-11A
  H11-	6.5	1.6	−	BVH-3C and BVH-11A
  10H10
  H11-7G11	81.2	9.0	+	BVH-3C and NEW 2
  H11-1B12	3.1	1.2	−	BVH-11A
  H11-7B9	2.4	1.1	−	BVH-11A
  H11-10B8	81.1	9.1	+	NEW 18 and NEW 8
  H11-1A2	84.4	10	+	NEW 18 and NEW 8
  H11-3H5	84.0	9.8	+	NEW 18 and NEW 8
  H112-	49.3	5.9	+	NEW 18 and NEW 8
  13C11
  H112-	0.4	1.0	−	BVH-11A and NEW 18
  10H10
  H112-1D8	0.4	1.0	−	BVH-11A and NEW 18
  H112-	78.9	10.4	+	NEW 19
  10G9
  H112-	75.5	9.6	+	NEW 19
  10A2
  H112-3E8	62.5	7.5	+	NEW 19
  H112-	64.5	7.7	+	NEW 14
  10D7
  H112-2H7	0.7	1.1	−	BVH-11A
  H112-6H7	0.3	1.0	−	BVH-11A
  H112-3A4	70.1	8.9	+	NEW 11
  H112-	86.3	9.2	+	NEW 11 AND 3A4.1
  10C5
  H112-	89.6	11	+	NEW 11
  14H6
  H112-	0.8	1.4	−	NEW 11
  14H6
  H112-7G2	4.7	2.0	−	NEW 18
  H112-	0.5	1.0	−	NEW 18
  13H10
  H112-7E8	0.4	1.0	−	BVH-11-2M
  H112-7H6	0.2	1.0	−	BVH-11-2M
  H11B-	3.1	1.1	−	NEW 18
  5F10
  H11B-	60.2	5.7	+	NEW 18 and NEW 8
  15G2
  H11B-	75.7	8.3	+	NEW 19
  13D5
  H11B-	78.4	8.3	+	NEW 19
  11B8
  H11B-	32.3	3.5	+	NEW 14
  7E11
  H11B-1C9	57.3	5.5	+	NEW 14
  H11B-5E3	1.8	1.0	−	NEW 7
  H11B-6E8	2.4	1.0	−	NEW 7

EXAMPLE 7
• This example describes the immunization of animals with peptide epitopes of BVH-3 and BVH-11-2.
• The recombinant PSCREEN-T vector (Novagen, Madison, Wis.) containing DNA fragment (nucleotides 2421 to 2626 on SEQ ID NO: 5) encoding the Mab 3A4-epitope (SEQ ID NO: 24) was transformed by electroporation (Gene Pulser II apparatus, BIO-RAD Labs, Mississauga, Canada) into E. coli Tuner (λDE3) pLysS [BL21 (F′ ompT hsdSB (rB⁻mB⁻) gal dcm lacYI pLysS (Cm^r)] (Novagen). In this strain, the expression of the fusion protein is controlled by the T7 promoter which is recognized by the T7 RNA polymerase (present on the XDE3 prophage, itself under the control of the lac promoter inducible by isopropyl-β-D-thiogalactopyranoside (IPTG). The pLysS plasmid reduces the basal fusion protein expression level by coding for a T7 lysozyme, which is a natural inhibitor of the T7 RNA polymerase.
• The transformants were grown at 37° C. with 250 RPM agitation in LB broth (peptone 10 g/l, yeast extract 5 g/l, NaCl 5 g/l) supplemented with 50 mM glucose, 100 μg/ml carbenicillin and 34 μg/ml chloramphenicol, until the absorbance at 600 nm reached a value of 0,7. The overexpression of T7gene 10 protein-His.Tag-3A4.1 fusion protein was then induced by the addition of IPTG to a final concentration of 1 mM and further incubation at 25° C. with 250 RPM agitation for 3 hours. Induced cells from a 800-ml culture were pelleted by centrifugation and frozen at −70° C. The fusion protein was purified from the soluble cell fraction by affinity chromatography based on the binding of a six histidine residues sequence (His-Tag) to divalent cations (Ni²⁺) immobilized on a metal chelation Ni-NTA resin (Qiagen, Mississauga, Canada). Briefly, the pelleted cells were thawed and resuspended in Tris buffered sucrose solution (50 mM Tris, 25% (w/v) sucrose) and frozen at −70° C. for 15 minutes. Cells were incubated 15 minutes on ice in the presence of 2 mg/ml lysozyme before disruption by sonication. The lysate was centrifuged at 12000 RPM for 30 minutes and Nickel charged Ni-NTA resin (QIAgen) was added to the supernatant for an overnight incubation at 4° C., with 100 RPM agitation. After washing the resin with a buffer consisting of 20 mM Tris, 500 mM NaCl, 20 mM imidazole pH 7,9, the fusion 3A4.1 protein was eluted with the same buffer supplemented with 250 mM imidazole. The removal of the salt and imidazole was done by dialysis against PBS at 4° C. The protein concentration was determined with BCA protein assay reagent kit (Perce, Rockford, Ill.) and adjusted to 760 μg/ml.
• To evaluate whether immunization with an epitope peptide sequence could confer protection against disease, groups of 6 female CBA/N (xid) mice (National Cancer Institute) are immunized subcutaneously three times at three-week intervals with affinity purified T7gene10 protein-His.Tag-3A4.1 fusion protein or, as control, with QuilA adjuvant alone in PBS. Twelve to fourteen days following the third immunization, the mice are challenged intravenously with S. pneumoniae WU2 strain or intranasally with P4241 strain. Samples of the S. pneumoniae challenge inoculum are plated on chocolate agar plates to determine the number of CFU and to verify the challenge dose. The challenge dose are approximalety 300 CFU. Deaths are recorded daily for a period of 14 days and on day 14 post-challenge, the surviving mice are sacrificed and blood samples tested for the presence of S. pneumoniae organisms. The 3A4.1 protein or other tested protein is said protective when the number of mice surviving the infection or the median number of days to death is significantly greater in the 3A4.1-immunized group compared to the control mock-immunized group.
EXAMPLE 8
• This example illustrates the improvement of the antibody response to pneumococci using BVH-3 fragments and variants thereof.
• The combined results obtained from studies of Mab reactivity with truncated gene products, epitope-expressing colonies and live intact pneumococci presented in examples 2, 3 and 6, allowed to delineate between surface-exposed and internal epitopes. The epitopes detected by Mabs that efficiently bound to pneumococci cells mapped to a region comprised between amino acid residues 223 to 1039 of BVH-3 described in SEQ ID NO 6. The existence of protective epitopes in the BVH-3-carboxyl half was confirmed by demonstrating that mice immunized with NEW1 molecule were protected from fatal infection with P4241 strain.
• Gene sequence comparison revealed that in some strains, the region of BVH-3 encoding for amino acids 244 to 420 as described in SEQ ID N06 is absent thus suggesting the lack of utility of this sequence in vaccine to prevent disease caused by such strains (SEQ ID NO: 9 versus SEQ ID NO: 1). Further BVH-3 fragments or variants thereof were designed in the purpose to develop a universal highly effective vaccine that would target the immune response to ubiquitous surface-exposed protective epitopes. BVH-3 gene fragments designated NEW1 (encoding amino acid residues 472 to 1039 from SEQ ID NO: 6) and NEW40 (encoding amino acid residues 408 to 1039 from SEQ ID NO: 6) were amplified from the S. pneumoniae strain SP64 by PCR using pairs of oligonucleotides engineered for the amplification of the appropriate gene fragment. Each of the primers had a restriction endonuclease site at the 5′end, thereby allowing directional in-frame cloning of the amplified product into the digested plasmid vector. PCR-amplified products were digested with restriction endonucleases and ligated to linearized plasmid pET21 (Novagen) expression vector digested likewise. Oligonucleotide primers HAMJ489 (ccgaattccatatgcaaattgggcaaccgactc; NdeI) and HAMJ279 (cgccaagcttcgctatgaaatcagataaattc; HindIII) were used for the NEW 40 construction. Clones were first stabilized in E. coli DH5α before introduction into E. coli BL21 (λDE3) for expression of the truncated gene products. Variants from NEW1 and NEW40 were generated by mutagenesis using the Quickchange Site-Directed Mutagenesis kit from Stratagene and the oligonucleotides designed to incorporate the appropriate mutation. The presence of 6 histidine tag residues on the C-terminus of the recombinant molecules simplified the purification of the proteins by nickel chromatography. The following tables 12 and 13 describe the sequences of the primers used for the mutagenesis experiments and the variant gene products generated, respectively. Mutagenesis experiments using primer sets 39, 40, 46, 47 or 48 resulted in silent changes and were performed in the purpose of improving the expression of the desired gene or gene fragment since it was observed that during the course of expression, BVH-3 gene and fragments of, shorter secondary translation initiation products were coexpressed.

  TABLE 12
  List of PCR oligonucleotide primer sets used for site-directed mutagenesis on
  BVH-3 gene truncates

  Primer	Primer	SEQ	Primer SEQUENCE
  set	identification	ID No		5′ - - - > 3′

  9	HAMJ513	177	GAATCAGGTTTTGTCATGAGTTCCGGAGACCACAATCATTATTTC
  	HAMJ514
  	178	GAAATAATGATTGTGGTCTCCGGAACTCATGACAAAACCTGATTC
  10	HAMJ515	179	GTCATGAGTTCCGGAGACTCCAATCATTATTTCTTCAAGAAGG
  	HAMJ516
  	180	CCTTCTTGAAGAAATAATGATTGGAGTCTCCGGAACTCATGAC
  11	HAMJ517	181	ATGAGTTCGGAGACTCCAATTCTTATTTCTTCAAGAAGGACTTG
  	HAMJ518	182	CAAGTCCTTCTTGAAGAAATAAGAATTGGAGTCTCCGGAACTCAT
  14	CHAN51	183	GCGATTATTTATCCGTCTGGAGATCACCATCATGC
  	CHAN52	184	GCATGATGGTGATCTCCAGACGGATAAATAATCGC
  17	CHAN53	185	CCGTCTGGAGATGGCCATCATGCAGATCCG
  	CHAN54	186	CGGATCTGCATGATGGCCATCTCCAGACGG
  19	CHAN47	187	CCGCAGGGAGATAAGCGTCATGCAGATCCGATTG
  	CHAN48	188	CAATCGGATCTGCATGACGCTTATCTCCCTGCGG
  20	CHAN55	189	CCGTCTGGAGATGGCACTCATGCAGATCCGATTG
  	CHAN56	190	CAATCGGATCTGCATGAGTGCCATCTCCAGACGG
  22	CHAN57	191	CCGTCTGGAGATGGCACTTCTGCAGATCCGATTGATG
  	CHAN58	192	CATCAATCGGATCTGCAGAAGTGCCATCTCCAGACGG
  23	HAMJ523	193	CCGCATGGAGATGGCCATCATGCAGATCCG
  	HAMJ524
  	194	CGGATCTGCATGATGGCCATCTCCATGCGG
  24	HAMJ526	195	GTCATGAGTCACGGAGACTCCAATCATTATTTCTTCAAGAAGG
  	HAMJ527	196	CCTTCTTGAAGAAATAATGATTGGAGTCTCCGTGACTCATGAC
  25	HAMJ528	197	ATGAGTCACGGAGACCACAATTCTTATTTCTTCAAGAAGGACTTG
  	HAMJ529	198	CAAGTCCTTCTTGAAGAAATAAGAATTGTGGTCTCCGTGACTCAT
  29	HAMJ569	199	TACCTCATTATGACTCTTACTCTAACATCAAATTTGAGTGGTTTG
  	HAMJ570
  	200	CAAACCACTCAAATTTGATGTTAGAGTAAGAGTCATAATGAGGTA
  30	HAMJ571	201	TACCTTCTTATGACCATTACTCTAACATCAAATTTGAGTGGTTTG
  	HAMJ572	202	AAACCACTCAAATTTGATGTTAGAGTAATGGTCATAAGAAGGTA
  31	HAMJ573	203	AACGGTAGTTTAATCATACCTTCTAAAGACCATTACCATAACATC
  	HAMJ574	204	GATGTTATGGTAATGGTCTTTAGAAGGTATGATTAAACTACCGTT
  32	HAMJ575	205	CGGTAGTTTAATCATACCTCATAAGGACTCTTACCATAACATCAAA
  	HAMJ576	206	TTTGATGTTATGGTAAGAGTCCTTATGAGGTATGATTAAACTACCG
  33	HAMJ577	207	AACGGTAGTTTAATCATACCTGACCATTACCATAACATCAAATTTG
  	HAMJ578	208	CAAATTTGATGTTATGGTAATGGTCAGGTATGATTAAACTACCGTT
  34	HAMJ579	209	AACGGTAGTTTAATCATACCTTACCATAACATCAAATTTGAGTGG
  	HAMJ580	210	CCACTCAAATTTGATGTTATGGTAAGGTATGATTAAACTACCGTT
  35	HAMJ581	211	ACCGGTAGTTTAATCATACCTAACATCAAATTTGAGTGGTTTGAC
  	HAMJ582	212	GTCAAACCACTCAAATTTGATGTTAGGTATGATTAAACTACCGTT
  37	HAMJ536	213	CCTATGTAACTCCACATATAACCCATAGCCACTGG
  	HAMJ537	214	CCAGTGGCTATGGGTTATATGTGGAGTTACATAGG
  39	HAMJ550	215	CGTGAAAGTATTGTCGTAAATAAAGAAAAAAATGCG
  	HAMJ551	216	CGCATTTTTTTCTTTATTTACGACAATACTTTCACG
  40	HAMJ586	217	CATGAAGAAGATGGTTACGGTTTCGATGCTAACCGTATTATCGCTGAAG
  	HAMJ587	218	CTTCAGCGATAATACGGTTAGCATCGAAACCGTAACCATCTTCTTCTG
  41	HAMJ588	219	GAATCAGGTTTTGTCATGAGTGACCACAATCATTATTTCTTC
  	HAMJ589	220	GAAGAAATAATGATTGTGGTCACTCATGACAAAACCTGATTC
  42	HAMJ590	221	GAAGATGAATCAGGTTTTGTCATGAGTAATCATTATTTCTTCAAG
  	HAMJ591	222	CTTGAAGAAATAATGATTACTCATGACAAAACCTGATTCATCTTC
  43	HAMJ592	223	GAAGATGAATCAGGTTTTGTCATGAGTTATTTCTTCAAGAAGGAC
  	HAMJ593
  	224	GTCCTTCTTGAAGAAATAACTCATGACAAAACCTGATTCATCTTC
  44	HAMJ594	225	AAAATGCGATTATTTATCCGCACCATCATGCAGATCCGATTG
  	HAMJ595	226	CAATCGGATCTGCATGATGGTGCGGATAAATAATCGCATTTT
  45	HAMJ600	227	AAAATGCGATTATTTATCCGGCAGATCCGATTGATGAACATAAAC
  	HAMJ601	228	GTTTATGTTCATCAATCGGATCTGCCGGATAAATAATCGCATTTT
  46	HAMJ604	229	GATGCTAACCGTATAATCGCCGAAGACGAATCAGGTTTTGTCATG
  	HAMJ605	230	CATGACAAAACCTGATTCGTCTTCGGCGATTATACGGTTAGCATC
  47	HAMJ606	231	CGCCGAAGACGAATCCGGCTTTGTAATGAGTCACGGAGACTCC
  	HAMJ607	232	GGAGTCTCCGTGACTCATTACAAAGCCGGATTCGTCTTCGGCG
  48	HAMJ608	233	CATCTCATGAACAGGATTATCCCGGCAACGCCAAAGAAATGAAAG
  	HAMJ609	234	CTTTCATTTCTTTGGCGTTGCCGGGATAATCCTGTTCATGAGATG

• TABLE 13
  Lists of truncated variant BVH-3 gene products generated
  from S. pneumoniae SP64

  	Gene/
  Protein	Protein		PCR primer set	Gene used for
  designation	SEQ ID NO	Protein Identification*	(ref. table 12)	mutagenesis
  NEW1-	255	NEW1	39	NEW1
  mut1**
  NEW35A	256	NEW1 550-SGDGTS-555	14, 17, 20, 22	NEW1
  NEW42	349	NEW40 55-SGDSNS-60 144-SGDGTS-149	9, 10, 11, 14,	NEW40
  17, 20, 22
  NEW49	350	NEW40 55-SGDHNH-60	9	NEW40
  NEW50	351	NEW40 55-SGDSNH-60	10	NEW49
  NEW51	352	NEW40 55-SGDHNH-60 144-SGDHHH-149	14	NEW49
  NEW52	353	NEW40 55-SGDSNH-60 144-SGDGHH-149	10, 17	NEW51
  NEW53	354	NEW40 55-HGDHNH-60 144-SGDHHH-149	14	NEW40
  NEW54	355	NEW40 55-SGDHNH-60 144-SGDGHH-149	17	NEW53
  NEW55	356	NEW1 550-HGDGHH-555	23	NEW1
  NEW56	357	NEW40 55-HGDSNH-60 144-SGDHHH-149	24	NEW53
  NEW56-	358	NEW56	40	NEW56
  mut2**
  NEW56-	359	NEW56	46, 47, 48	NEW56
  mut3**
  NEW57	360	NEW40 55-HGDHNS-60 144-SGDHHH-149	25	NEW53
  NEW63	361	NEW40 55-HGDSNH-60 144-HGDHHH-149	24	NEW40
  NEW64	362	NEW40 55-HGDHNS-60 144-HGDHHH-149	25	NEW40
  NEW65	363	NEW40 55-HGDSNH-60 144-HGDGHH-149	23	NEW63
  NEW66	364	NEW40 55-HGDHNS-60 144-HGDGHH-149	23	NEW64
  NEW76	365	NEW40 55-HGDHNS-60 144-SGDGHH-149	17	NEW64
  NEW105	366	NEW40 55-   -60	41, 42, 43	NEW40
  NEW106	367	New40 144-   -149	44, 45	NEW40
  NEW107	368	NEW40 55-   -60 144-   -149	44, 45	NEW105
  * The underlined amino acid residues represent the modification in protein sequence. Nucleotides/amino acid residues are deleted in NEW105, NEW106 and NEW107 constructs.
  ** silent mutation, i.e. the polypeptide is the same as New1.

• Groups of 7 or 8 female BALB/c mice (Charles River) immunized as described earlier in example 1 were used for protection experiments against intranasal challenge with virulent S. pneumoniae P4241 strain. The mice were observed for 10 to 14 days post-infection. Data from Table 15 clearly indicate that the NEW35A molecule was equivalent to the parental NEW1 in term of protection. Interestingly, high survival rates where obtained for NEW40- and NEW56-immunized groups with 7 and 8 survivors out of 8 animals, respectively. Similarly, NEW25 comprising amino acid residues 233 to 1039 protected 7 out of 8 animals from lethal infection.

  TABLE 14
  Protection mediated by BVH-3 fragments or variants
  thereof in experimental pneumonia

  Ex-
  peri-	Immu-
  ment	nogen	Alive:Dead	Days to death post-infection
  1	Quil A	0:8	4, 4, 4, 4, 4, 4, 4, 4
  	NEW 1	5:3	5, 7, 7, >14, >14, >14, >14, >14
  	NEW 35A	5:2	9, 10, >14, >14, >14, >14, >14
  	NEW 40	7:1	13, >14, >14, >14, >14, >14, >14, >14
  	BVH-3M	4:4	7, 8, 10, 12, >14, >14, >14, >14
  2	Quil A	0:8	3, 3, 4, 4, 4, 4, 4, 4
  	NEW 52	4:4	7, 7, 8, 9, >10, >10, >10, >10
  	NEW56	8:0	8 X >10
  	NEW 40	7:1	6, >10, >10, >10, >10, >10, >10, >10
  3	QuilA	0:8	3, 3, 4, 4, 4, 4, 4, 4
  	NEW25	7:1	6, >13, >13, >13, >13, >13, >13, >13

• Additionally, flow cytometry analyses of the binding capacity of the sera antibodies from the vaccinated animals revealed that NEW40 and NEW56 antibodies labelled live intact pneumococci more efficiently than antibodies raised to BVH-3M (Table 15).

  TABLE 15
  Binding of mouse sera antibodies at the surface of S. pneumoniae
  type
  3 strain WU2 as measured by flow cytometry.

  Fluorescene index

  				Mean ±
  Antisera	Experiment	1	Experiment 2	Experiment 3	SE

  BVH-3M	9.2	11.4	14.5	11.7 ± 1.5
  NEW1	11.5	10.1	nd*	10.8 ± 0.7
  NEW35A	14.3	12.9	nd	13.6 ± 0.7
  NEW40	20.4	19.1	20.2	19.9 ± 0.4
  NEW56	nd	16.7	20.2	18.5 ± 1.8
  NEW52	nd	16.6	19.3	18.0 ± 1.4
  Adjuvant	1.9	1.6	1.2	1.6 ± 0.2
  alone
  *nd: not done

• Cytometry results are expressed as fluorescence index value where the fluorescence index is the median fluorescence value of pneumococci treated with test sera divided by the background fluorescence value of pneumococci treated with the fluorescein conjugate alone. In these flow cytometric assays, all sera were used at a dilution of 1:50 and the sera from mice immunized with BVH-3C fragment or QuilA adjuvant alone gave a value similar to the background value.
• Altogether the protection and pneumococci antibody binding data indicate that vaccination using NEW1 or NEW40 molecules and variants thereof, directs the immune response to conserved protective surface-exposed epitopes.
EXAMPLE 9
• This example describes the cloning and expression of a chimeric deletant BVH-11-2 gene encoding for a chimeric polypeptide corresponding to BVH-11-2 conserved protective surface-exposed epitopes present in most if not all S. pneumoniae strains.
• BVH-11-2 gene fragments corresponding to 4 gene regions, were amplified by PCR using pairs of oligonucleotides engineered to amplify fragments originating from SEQ ID NO :5 spanning nucleotides 1662 to 1742, 1806 to 2153, 2193 to 2414 and 2484 to 2627 from S. pneumoniae strain Sp64 BVH-11-2 gene.
• The primers used, HAMJ490-491, HAMJ492-HAMJ493, HAMJ494-HAMJ495, HAMJ496-HAMJ354 had a restriction endonuclease site at the 5′ end, thereby allowing directional in-frame cloning of the amplified product into the digested pET21b(+) plasmid vector (Table 16). PCR-amplified products were digested with restriction endonucleases and ligated to linearized plasmid pSL301 vector digested likewise except for the PCR-amplified fragment obtained with the primer pair HAMJ490-HAMJ491. The HAMJ490-HAMJ491 PCR-amplified product was purified from agarose gel using a QIAquick gel extraction kit from QIAgen (Chatsworth, Calif.) and ligated into PGEM-T plasmid vector without any prior restriction endonuclease digestion. The resultant plasmid constructs were confirmed by nucleotide sequence analysis. The recombinant plasmids containing each of the four were digested with restriction endonucleases corresponding with the 5′ end of each primer pair used for the PCR-amplification. The fragments were purified from agarose gel like described earlier and were all ligated to linearized plasmid pET21b (+) digested with the restriction enzymes NdeI and HindIII for the in-frame cloning of the four different regions of the BVH11-2 gene. Clones were first stabilized in E. coli DH5α before introduction into E. coli BL21 (λDE3) for expression of a chimeric pneumococcal protein molecule.
• The resulting NEW43 gene sequence (SEQ ID No 257) is described in FIG. 33.
• The deduced amino acid sequence of NEW43 protein (SEQ ID No 258). is described in FIG. 34.

  TABLE 16
  List of PCR oligonucleotide primers used to construct
  the NEW43, VP43S and NEW86

  	SEQ		Nucleotide	Restriction
  Primer	ID NO	Sequence 5′ - 3′	position	sites

  HAMJ490	259	ccgaattccatatgcaaat	SEQ ID 5:	NdeI
  		tacctacactgatgatg	1662-1683
  HAMJ491	260	ggactagtatcaaagatat	SEQ ID 5:	SpeI
  		aaccgtcttc	1742-1722
  HAMJ492	261	ggactagttggattaaaaa	SEQ ID 5:	SpeI
  		agatagtttgtctg	1806-1830
  HAMJ493	262	ttcccgcggttcgacatag	SEQ ID 5:	SacII
  		tacttgacagtcg	2153-2131
  HAMJ494	263	ttcccgcggaacgctagtg	SEQ ID 5:	SacII
  		accatgttcg	2193-2212
  HAMJ495	264	cggggtaccaggaatttca	SEQ ID 5:	KpnI
  		gcctcatctgtg	2414-2393
  HAMJ496	265	cccggtacccctagtatta	SEQ ID 5:	KpnI
  		gacaaaatgctatggag	2484-2510
  HAMJ	65	cgccaagcttctgtatagg	SEQ ID 5:	HindIII
  354		agccggttgac	2627-2608
  HAMJ	266	ggatcccgggaggtatgat	SEQ ID 5:	SmaI
  583		taaactaccg	2039-2021
  HAMJ	267	catgcccgggaacatcaaa	SEQ ID 5:	SmaI
  584		tttgagtggtttgac	2058-2081
  HAMJ	268	cttgatcgacatatgttgg	SEQ ID 5:	NdeI
  610		caggcaagtacacaacag	1701-1722

• TABLE 17
  List of truncated BVH-11-2 gene fragments generated
  from S. pneumoniae SP64 for the construction of NEW43

  		Corresponding
  		amino acid
  	Gene	residues
  	fragment	on SEQ ID	Cloning
  PCR-primer sets	designation	NO: 8	vector
  HAMJ490-HAMJ491	NEW43a	517-543	pGEM-T
  HAMJ492-HAMJ493	NEW43b	565-680	pSL301
  HAMJ494-HAMJ495	NEW43c	694-767	pSL301
  HAMJ496-HAMJ354	NEW43d	791-838	pSL301

• TABLE 18
  Properties of NEW86 and VP43S genes
  generated from NEW43 gene

  	Gene/
  	Protein
  PCR-primer sets	designation	Identification
  HAMJ610-HAMJ354	VP43S	NEW43 C′ end corresponding to
  		residues 15-272) (SEQ ID NO:
  		374)
  HAMJ490-HAMJ583	NEW86	NEW43 109-_PG_-114
  HAMJ584-HAMJ354		(SEQ ID NO: 375)

• NEW43-derived molecules designated VP43S and NEW86 were generated from gene amplification and cloning experiments using PCR primers described in Tables 16 and 18 and pET21 expression plasmid vector. Variants from NEW43 were generated by mutagenesis using the Quickchange Site-Directed Mutagenesis kit from Stratagene and the oligonucleotides designed to incorporate the appropriate mutation. The presence of 6 histidine tag residues on the C-terminus of the recombinant molecules simplified the purification of the proteins by nickel chromatography. The following tables 19 and 20 describe the sequences of the primers used for the mutagenesis experiments and the NEW43 variant gene products generated, respectively.

  TABLE 19
  List of PCR oligonucleotide primer sets used for site-
  directed mutagenesis on NEW43 gene

  Primer	Primer	SEQ	Primer SEQUENCE
  set	identification	ID NO		5′ - - - 3′

  1	HAMJ497	269	AACGGTAGTTTAATCATACCTTCTTATGACCATTACCATAACATC
  	HAMJ498	270	GATGTTATGGTAATGGTCATAAGAAGGTATGATTAAACTACCGTT
  2	HAMJ499	271	AATCATACCTTCTTATGACTCTTACCATAACATCAAATTTGAGTG
  	HAMJ500	272	CACTCAAATTTGATGTTATGGTAAGAGTCATAAGAAGGTATGATT
  3	HAMJ501	273	TACCTTCTTATGACTCTTACTCTAACATCAAATTTGAGTGGTTTG
  	HAMJ502	274	CAAACCACTCAAATTTGATGTTAGAGTAAGAGTCATAAGAAGGTA
  26	HAMJ530	275	AATCATACCTCATTATGACTCTTACCATAACATCAAATTTGAGTG
  	HAMJ531	276	CACTCAAATTTGATGTTATGGTAAGAGTCATAATGAGGTATGATT
  27	HAMJ532	277	TACCTCATTATGACCATTACTCTAACATCAAATTTGAGTGGTTTG
  	HAMJ533	278	CAAACCACTCAAATTTGATGTTAGAGTAATGGTCATAATGAGGTA
  29	HAMJ569	279	TACCTCATTATGACTCTTACTCTAACATCAAATTTGAGTGGTTTG
  	HAMJ570
  	280	CAAACCACTCAAATTTGATGTTAGAGTAAGAGTCATAATGAGGTA
  30	HAMJ571	281	TACCTTCTTATGACCATTACTCTAACATCAAATTTGAGTGGTTTG
  	HAMJ572	282	AAACCACTCAAATTTGATGTTAGAGTAATGGTCATAAGAAGGTA
  31	HAMJ573	283	AACGGTAGTTTAATCATACCTTCTAAAGACCATTACCATAACATC
  	HAMJ574
  	284	GATGTTATGGTAATGGTCTTTAGAAGGTATGATTAAACTACCGTT
  32	HAMJ575	285	CGGTAGTTTAATCATACCTCATAAGGACTCTTACCATAACATCAAA
  	HAMJ576	286	TTTGATGTTATGGTAAGAGTCCTTATGAGGTATGATTAAACTACCG
  33	HAMJ577	287	AACGGTAGTTTAATCATACCTGACCATTACCATAACATCAAATTTG
  	HAMJ578	288	CAAATTTGATGTTATGGTAATGGTCAGGTATGATTAAACTACCGTT
  34	HAMJ579	289	AACGGTAGTTTAATCATACCTTACCATAACATCAAATTTGAGTGG
  	HAMJ580	290	CCACTCAAATTTGATGTTATGGTAAGGTATGATTAAACTACCGTT
  35	HAMJ581	291	ACCGGTAGTTTAATCATACCTAACATCAAATTTGAGTGGTTTGAC
  	HAMJ582	292	GTCAAACCACTCAAATTTGATGTTAGGTATGATTAAACTACCGTT

• TABLE 20
  List of NEW43 variant gene products
  generated from S. pneumoniae SP64

  	Polypep-		PCR primer	Gene used
  Polypeptide	tide	Polypeptide	set (ref.	for
  designation	SEQ ID NO	identification*	table 22)	mutagenesis

  NEW60	293	NEW43 109-SYDHYH-114	1	NEW43
  NEW61	294	NEW43 109-HYDSYH-114	26	NEW43
  NEW62	295	NEW43 109-HYDHYS-114	27	NEW43
  NEW80	296	NEW43 109-SYDSYH-114	2	NEW60
  NEW81	297	NEW43 109-SYDSYS-114	3	NEW80
  NEW82
  	298	NEW43 109-HYDSYS-114	29	NEW61
  NEW83
  	299	NEW43 109-SYDHYS-114	30	NEW60
  NEW84
  	300	NEW43 109-SKDHYH-114	31	NEW60
  NEW85
  	301	NEW43 109-HKDSYH-114	32	NEW61
  NEW88D1	302	NEW43 109-  DHYH-114	33	NEW43
  NEW88D2
  	303	NEW43 109-    YH-114	34	NEW88D1
  NEW88	304	NEW43 109-      -114	35	NEW88D2
  *The underlined amino acid residues represent the modification in protein sequence. Nucleotides/amino acid residues are deleted in NEW88D1, NEW88D2 and NEW88 constructs.

• Groups of 7 or 8 female BALB/c mice (Charles River) immunized as described earlier in example 1 were used for protection experiments against intranasal challenge with virulent S. pneumoniae P4241 strain. Data from Table 21 clearly indicate that NEW 19, NEW43 and variants thereof provided protection against experimental pneumonia.

  TABLE 21
  Protection mediated by NEW19 and NEW43 fragments or
  variants thereof in experimental pneumonia

  Experiment	Immunogen	Alive:Dead	Median day alive
  1	Quil A	0:8	4, 4, 4, 4, 4, 4, 4, 5
  	NEW 19	7:1	5, 7X >14
  	NEW 43	8:0	8X >14
  2	Quil A	0:8	4, 4, 4, 4, 4, 5, 5, 5
  	NEW 43	7:1	8, 7X >14
  	NEW 80	6:2	5, 6, 6 X >14
  	NEW 83	6:2	8, 10, 6 X >14
  3	Quil A	0:8	4, 4, 4, 4, 5, 5, 5, 5
  	NEW 43	7:1	5, 7X >8
  	NEW 88D1	5:3	5, 6, 6, 6 X >8
  	NEW 88D2	5:3	6, 6, 6, 6 X >8
  	NEW 88	7:1	6, 7X >8
  3	Quil A	0:8	4, 4, 4, 5, 5, 5, 5, 6
  	NEW 60	8:0	8 X >8
  	NEW 84	8:0	8 X >8
  	NEW 85	5:3	5, 7, 7, 5 X >8
  	NEW 86	5:3	5, 6, 6, 5 X >8

EXAMPLE 10
• This example describes the cloning and expression of chimeric genes encoding for a chimeric protein corresponding to the carboxy-terminal region of BVH-3 or variants thereof in fusion, at either the carboxyl end or the amino end, to NEW43 or variants thereof. The chimeric genes comprising a BVH-3 truncate variant gene and a NEW43 or NEW43 variant gene have been designed following the procedure described in example 1. The polypeptides encoded by these chimeric genes are listed in the table 22. Briefly, gene fragments to be included in a chimeric gene were amplified by PCR using pairs of oligonucleotides engineered so that the primers had a restriction endonuclease site at the 5′ end, thereby allowing directional in-frame cloning of the amplified product into digested plasmid vectors (Table 23 and Table 24). PCR-amplified products were digested with restriction endonucleases and ligated to linearized plasmid pSL301 vector. The resultant plasmid construct were confirmed by nucleotide sequence analysis. The recombinant pSL301 plasmids containing a PCR product were redigested with the same endonuclease restriction enzyme for the obtention of the DNA inserts. The resulting insert DNA fragments were purified and inserts corresponding to a given chimeric gene were ligated into pURV22-NdeI vector for the generation of a chimeric gene. The expressed recombinant proteins were purified from supernatant fractions obtained from centrifugation of sonicated heat-induced E. coli cultures using multiple chromatographic purification steps.

  TABLE 22
  List of polypeptides encoded by chimeric genes
  comprising a BVH-3 truncate variant gene and
  a NEW43 or NEW43 variant gene

  	Polypeptide
  	designation	SEQ ID NO	Identification
  	VP89	369	M-New56-GP-New43*
  	VP90	370	M-New43-GP-New56
  	VP91	371	M-New52-GP-New43
  	VP92	372	M-New43-GP-New52
  	VP93	373	M-New56-GP-New60
  	VP94	332	M-New60-GP-New56
  	VP108	333	M-New56-GP-New88
  	VP109	334	M-New88-GP-New56
  	VP110	335	M-New60-GP-New105
  	VP111	336	M-New60-GP-New107
  	VP112	337	M-New88-GP-New105
  	VP113	338	M-New88-GP-New107
  	VP114	339	M-New80-GP-New105
  	VP115	340	M-New80-GP-New107
  	VP116	341	M-New83-GP-New105
  	VP117	342	M-New83-GP-New107
  	VP119	343	M-New43S-GP-New105
  	VP120	344	M-New43S-GP-New107
  	VP121	345	M-New80S-GP-New105
  	VP122	346	M-New80S-GP-New107
  	VP123	347	M-New88S-GP-New105
  	VP124	348	M-New88S-GP-New107
  	*Encoded amino acids for the chimeras are expressed as the gene product, additional amino acid residues were added. M is methionine, G is glycine and P is proline.

• TABLE 23
  List of PCR oligonucleotide primer pairs designed
  for the generation of the chimeric genes encoding
  the polypeptides listed in Table 22.

  			Corresponding
  			position of the
  		Gene used for	gene fragment on
  Primer	PCR-primer	PCR	the chimeric
  set	identification	amplification	protein molecule
  49	HAMJ490-HAMJ471	Variant New43	N-terminal
  50	HAMJ564-HAMJ556	Variant New43	C-terminal
  51	HAMJ489-HAMJ359	Variant New40	N-terminal
  52	HAMJ559-HAMJ557	Variant New40	C-terminal
  53	HAMJ610-HAMJ471	Variant New43S	N-terminal

• TABLE 24
  List of PCR oligonucleotide primers designed for
  the generation of the chimeric genes encoding the
  polypeptides listed in Table 22.

  	SEQ
  	ID		Restriction
  Primer	NO	Sequence	5′ - 3′	site

  HAMJ490	259	ccgaattccatatgcaaattaccta	NdeI
  		cactgatgatg
  HAMJ471	168	atatgggcccctgtataggagccgg	ApaI
  		ttgactttc
  HAMJ564	327	atatgggccccaaattacctacact	ApaI
  		gatgatgagattcagg
  HAMJ556	328	ataagaatgcggccgcctactgtat	NotI
  		aggagccggttgactttc
  HAMJ489	329	ccgaattccatatgcaaattgggca	NdeI
  		accgactc
  HAMJ359	173	tcccgggccccgctatgaaatcaga	ApaI
  		taaattc
  HAMJ559	330	atatgggccccaaattgggcaaccg	ApaI
  		actc
  HAMJ354	65	cgccaagcttctgtataggagccgg	HindIII
  		ttgac
  HAMJ610	268	cttgatcgacatatgttggcaggca	NdeI
  		agtacacaacag
  HAMJ557	331	ataagaatgcggccgcttacgctat	NotI
  		gaaatcagataaattc
  HAMJ279	35	cgccaagcttcgctatgaaatcaga	HindIII
  		taaattc

Claims (7)

1-34. (canceled)

35. A polynucleotide encoding a polypeptide having the amino acid sequence of SEQ ID NO. 332 or a polynucleotide that hybridizes under stringent conditions to the complement of a polynucleotide encoding a polypeptide having the amino acid sequence of SEQ ID NO. 332, wherein the polypeptide elicits an immune response when administered to an individual.

36. A polynucleotide encoding a polypeptide which has the amino acid sequence of SEQ ID NO. 332.

37. A polynucleotide that hybridizes under stringent conditions to the complement of polynucleotide encoding a polypeptide having the amino acid sequence of SEQ ID NO. 332.

38. A polynucleotide encoding a polypeptide having the amino acid sequence of SEQ ID NO. 332 or a polypeptide having at least 85% sequence similarity to SEQ ID NO. 332, wherein the polypeptide elicits an immune response when administered to an individual.

39. A vector comprising the polynucleotide of claim 32.

40. A method of immunizing an individual against streptococcus infection comprising administering the vector of claim 39 to the individual, wherein the polypeptide is expressed and elicits an immune response.

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