AU649078C - Purified CDW52-specific antibodies - Google Patents
Purified CDW52-specific antibodiesInfo
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- AU649078C AU649078C AU87294/91A AU8729491A AU649078C AU 649078 C AU649078 C AU 649078C AU 87294/91 A AU87294/91 A AU 87294/91A AU 8729491 A AU8729491 A AU 8729491A AU 649078 C AU649078 C AU 649078C
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Description
Purified CD 52-spec1f1c antibodies.
The present invention relates to a purified preparation of monoclonal aannttiibbooddiieess aaggaaiinnsstt tthhee aannttiiggeenn CD 52, to their use in therapy and to processes for their production.
Antibodies or immunoglobulins are proteinaceous bi-functional molecules. One region which is highly variable between the different antibodies, is responsible for binding to an antigen, for example many different infectious agents that the body may encounter, whilst the second, constant region is responsible for binding to the Fc receptors of cells and also activates complement. In this way antibodies represent a vital component of the immune response of mammals in destroying foreign microorganisms and viruses. Immunisation of an animal with an antigen results in the production of polyclonal antibodies, in ether words, different antibodies with different specificities and affinities. For therapeutic applications it is advantageous to be able to produce antibodies from a single lymphocyte clone - such antibodies are called monoclonal antibodies and are specific to a particular determinant of the original antigen. They can be obtained by the method of Kohler and Mils ein (Nature, 1975, 256. 495-497).
A single antibody molecule of the IgG class is composed of two light chains and two heavy chains that are held together by interchain disulphide bonds. Each light chain is linked to a heavy chain by a disulphide bond and the two heavy chains are linked to each other by disulphide bonds. Each heavy chain has at one end a variable domain followed by a number of constant domains, each light chain has a variable domain at one end and a constant domain at the other end. The light chain variable domain is aligned with the variable domain of the heavy chain. The light chain constant domain is aligned with the first constant domain of the heavy chain. The remaining constant domains of the heavy chains are aligned with each other and form the Fc fragment, after limited cleavage of the polypeptide chain.
The variable domains of each pair of light and heavy chains form the antigen binding site. Together with the first constant domain of the heavy chain and the constant domain of the light chain they form, after limited cleavage of the polypeptide chain, the Fab fragment. The variable domains of each pair of heavy and light chains have the same general structure with each domain comprising a framework of four regions, whose sequences are relatively conserved, connected by three complementarity determining regions (CDRs) . The four framework regions largely adopt a β-sheet conformation and the CDRs form loops connecting, and in some cases comprising part of, the β-sheet structure. The CDRs are held in close proximity by the framework regions and,-with^ he CDRs from the other domain, contribute to the formation of the antigen binding site.
The antigen CD 52 (G.Hale et al, Tissue Antigens 1990 3J5, pp 118-127) is an abundant molecule widely distributed on most, if not all, human lymphocytes. It is also present on the surface of the majority of malignant lymphocytes, but not hae opoietic cells, nor is it expressed on granulocytes, platelets, erythroid or myeloid bone marrow cells. A number of monoclonal antibodies of different isotypes have been raised against this antigen and reported in the literature, (G.Hale jet al Tissue Antigens, 1990, 35., pp 118-127). One of these antibodies, an IgGl antibody, has been humanised (Nature, 1988, 322, 323-327 and EP0328404). This antibody is known as Campath 1H (Campath is a trademark of The Wellcome Foundation Ltd) . A preparation of this antibody has been used to treat patients suffering from Non Hodgkins' lymphoma, (G.Hale et al, Lancet, 1988, pp 1394-1399).
Campath 1H was originally purified in a one-step process on a Protein A Sepharose column (EP0328404) . Protein A is a group specific ligand which binds to the Fc region of immunoglobulin; therefore other immunoglobulins contained in serum present in the culture medium will co-purify with the immunoglobulin of interest thereby contaminating the end product (P. . Underwood et al, Meths. in Enzymol. 121 p. 301-306 (1986), and P.A. Underwood et al, J.Immunol.
Meths 6 , 33, 1983). Antibodies which are intended for use in medical therapy may need to be administered repeatedly, so the need to remove foreign immunoglobulins is important as such administration may produce an immune response and induce nephrotoxicity, serum sickness and in severe cases anaphylactic shock. Whole animal serum or serum albumin will contain other proteins, lipids and carbohydrates; these molecules may themselves raise an immune response but pose a greater danger of harbouring pathogens such as the agent which causes Bovine Spongiform Encephalopathy (BSE). Endotoxins may also be present which are undesirable as they produce potentially fatal pyrogenic responses.
Other contaminants in the culture medium containing the expressed antibody, include host cell and viral nucleic acid. Also aggregates of antibodies as they too may act as immunogens and cause an undesirable immune response.
The present invention therefore provides a purified preparation of an anti-CDw52 antibody which exhibits on size exclusion chromatography:
a single peak under non-reducing conditions and two major peaks under denaturing and reducing conditions.
The preparation preferably also exhibits on conventional SDS polyacrylamide gel electrophoresis:
one main band using a non-reduced sample and two main bands using a reduced sample.
Additionally the preparation exhibits on reversed phase HPLC:
a single sharp peak under non-reducing conditions and two major peaks under reducing conditions.
Size exclusion chromatography as its name suggests separates on the basis of the size of proteins. In general separation occurs when
large molecules are excluded from entering the porous stationary phase and are carried straight through the column while progressively smaller molecules are increasingly able to enter the stationary phase and consequently have particularly longer elution times. It is the porosity of the stationary phase which therefore determines the separation achieved. This analytical technique is particularly good for determining levels of aggregate in the purified preparation. The stationary phase is a wide pore silica gel which may be modified with diol groups preferably a gel such as Zorbax GF450-GF250 (Trademark of Dupont) or TSK gel G3000 SWXL or G4000 SWXL. The mobile phase is generally in the pH range 4-8 more preferably 6-7.5 advantageously around pH6.8. This phase is advantageously a mixture of a phosphate such as disodium hydrogen orthophosphate and a sulphate such as sodium or potassium sulphate and water. The molarity of such a mixture is generally 25mM to 1M most preferably around 50mM.
SDS polyacrylamide gel electrophoresis (SDS PAGE) gives information about the number and type of proteins present in a mixture, their relative abundance and a measure of their molecular weights. SDS is an anionic detergent, it is reacted with the proteins before electrophoresis. Most protein SDS complexes are soluble and will migrate through a polyacrylamide gel towards the anode, under the influence of an electrical charge. Rate of migration is generally inversely related to the logarithm of the molecular weight of the protein. It is convenient to carry out the SDS analysis on a gradient gel which may be flat bed or vertical slabs or rods. The gradient is advantageously 10-22% or more preferably 8-18%. The gel is preferably Pharmacia Excel (Trademark) gel.
Reversed phase HPLC separates on the basis of hydrophobicity. As with other HPLC techniques there is a polymeric stationary phase, of for example polystyrene/divinylbenzene. The mobile phase is usually a combination of a weak aqueous buffer or a dilute acid and a water miscible organic solvent. For effective separation of proteins the
mobile phase is generally a gradient system, required to achieve separation and is preferably linear for convenience.
The stationary phase for analysis of immunoglobulin may be an organic polymeric matrix such as Polymer Labs PLRP-S generally of particle size around 8/.M; the pore size is preferably 300 A or 1000 A. The mobile phase is advantageously a mixture of an acid such as formic, acetic or trifluoroacetic acid, water and acetonitrile. The acid and the water are preferably present in the ratio 5:3.
An antibody can be reduced to its component heavy and light chains by reduction of the disulphide bonds under denaturing conditions with for example Guanidinium chloride and dithiothreitol. Subsequent alkylation of the free thiol groups, for example with iodoacetamide iodoacetic acid, assists in preventing the bonds from reforming.
A measure of purity is provided by the specific activity of the antibody preparation. Specific activity may be determined by the method set out in the Examples. A preparation according to the invention preferably has a specific activity of greater than 0.8 Kilo Units/mg, ideally greater than 0.9 Kilo Units/mg, most preferably around 1.0 Kilo Units/mg.
A purified preparation of an anti-CDW52 antibody according to the invention ideally, is substantially free from host cell contaminants such as host cell proteins, nucleic acids and endotoxins. Specific activity provides information about the levels of host cell protein in the preparation. Endotoxin levels may be measured by the LAL (Limulus Amoebocyte Lysate) method described in Parenteral Quality Control, M.J. Alles et al. : Marcel Dekker Inc., New Yorl"
A preparation according to the invention is also essentially free from aggregate, as measured on size exclusion chromatography. It is desirable for these levels to be less than 2%, ideally less than 0.5%.
Antibodies according to the invention may be prepared using a recombinant expression system, the preferred system is a mammalian expression system using Chinese hamster ovary (CHO) cells. "These may be dihydrofolate reductase (dhfr) deficient and so dependent on thymidine and hypoxanthine for growth (PNAS 77 1980, 4216-4220). The parental dhfr CHO cell line is transfected with the antibody gene and dhfr gene which enables selection of CHO cell transformants of dhfr positive pheπotype. Selection is carried out by culturing the colonies on media devoid of thymidine and hypoxanthine, the absence of which prevents untransformed cells from growing and transformed cells 'from resalvaging the folate pathway and thereby bypassing the selection system. These transformants usually express low levels of the product gene by virtue of co-integration of both transfected genes. The expression levels of the antibody gene may be Increased by amplification using methotrexate (MTX) . This drug is a direct inhibitor of the dhfr enzyme and allows isolation of resistant colonies which amplify their dhfr gene copy number sufficiently to survive under these conditions. Since the dhfr and antibody genes are more closely linked in the original transformants, there is usually concommitant amplification, and therefore increased expression of the desired antibody gene.
Another expression system for use with CHO or myeloma cells is the glutamine synthetase (GS) amplification system described in WO87/04462. This system involves the transfection of a cell with a gene encoding the GS enzyme and the desired antibody gene. Cells are then selected which grow in glutamine free medium. These selected clones are then subjected to inhibition of the GS enzyme using methionine sulphoximine (Msx) . The cells, in order survive, will amplify the GS gene with concomitant amplification of the gene encoding the antibody.
Antibody is preferably obtained in a form in which it is secreted in to the culture medium. The harvested medium may then be filtered and/or concentrated by an ultrafiltration step to obtain an aqueous
solution which is subjected to a purification procedure involving applying an aqueous solution of the antibody to
a) a Protein A column so as to absorb the antibody onto the column, and then eluting the antibody with an acidic solution;
b) applying the acidic eluate to an ion-exchange column of charged particles so as to absorb the antibody, and then eluting the antibody with an aqueous solution of counter-charged ions;
c) applying the aqueous eluate to a size exclusion column of porous particles so as Jro separate according to molecular size and to obtain the desired antibody in selected fractions eluted from the column.
Protein A is a group specific ligand which binds to the Fc region of most IgG. It is synthesised by some strains of staphylococcus aureus and can be isolated from culture supernatants then insolubilised by coupling to agarose beads or silica. An alternative method is to use whole bacteria of a strain which carries large amounts of protein A on the bacterial cell surface. Both types of gel preparation are available commercially. (Protein A - Pharmacia. hole bacteria Calbiochem, IgG sorb). (Alan Johnstone and Robin Thorpe Immunochemistry in practice, Blackwell Scientific Publn. Chpt.lO). An alternative to Protein A is Protein G (Analytical Che . Vol. 61 (13) 1989 1317).
The column which is most preferably used is a Protein A Sepharose column particularly Protein A Seplu ose Fast Flow (Trademark) . Ideally the column is washed with tris or phosphate buffered saline around pH7.0 and the antibody is eluted at acid pH 3.0 - 3.5 advantageously pH 3.0 using an acid such as citric acid for example in a concentration of about 0.1M.
Ion-exchange chromatography exploits interactions between charged groups in a stationary phase and the sample which is in a mobile phase. The stationary phase of an ion-exdhange column may be a positively charged cation exchanger or a negatively charged anion exchanger. The charged groups are neutralised by oppositely charged counter ions in the mobile phase, the counter ions being replaced during chromatography by more highly charged sample molecules. It is preferable to use cross-linked columns based for example on agarose for example S-Sepharose Fast Flow (Trademark) cation exchange column -particularly S.Sepharose Fast Flow cation exchange (Trademark). Alternatively a membrane-based column could be employed. The column is usually washed after application of the eluate from the Protein A column, with 20mM HEPES buffer pH 7.5 and the antibody is eluted with the same buffer containing sodium chloride in the range 0.2M to 0.075M.
Size exclusion chromatography as its name suggests separates on the basis of the size of proteins. In general separation occurs when large molecules are excluded from entering the porous stationary phase and are carried straight through the column while progressively smaller molecules are increasingly able to enter the stationary phase and consequently have particularly longer elution times. It is the porosity of the stationary phase which therefore determines the separation achieved. Suitable materials are chemically bonded and provide resistance to compression for example an agarose and/or dextran composition such as Superdex (Trademark) . A preferred column is a Superdex 200 size exclusion medium. The eluate from the ion exchange column is preferably applied to the Superdex column and developed in buffer in the range pH5-8 preferably PBS pH 7.2.
Each column is preferably protected by a filter which may be a 0.2/_ Gelman Aero sterilising filter or in the case of the Protein A column a PALL posidyne SLK 7002 NFZP or a PALL DSLK2 filter (available from Pall Process Filtration Ltd. European House, Havant Street, Portsmouth '301 3PD) and for the other two columns a Millipak filter preferably
Millipak 100 for the ion exchange column and Millipak 20 or 60 for the size exclusion column (available from Millipore, The Boulevard, Blackmore Lane, Watford, Herts. The columns are preferably sanitised before use with an appropriate sanitant for example 0.5M NaOH for 16 hours for any of the columns, or 2% hibitane gluconate in 20% ethanol for the Protein A column or I N NaOH for the other two columns. Sanitants were washed out with the appropriate sterile buffers before applying the protein solution. All solutions used in the process were preferably sterile and endotoxin free.
Additional steps may be added to the purification procedure set out above. Ultrafiltration may be used to further reduce viral and host cell nucleic acid contamination. This may be carried out using commercially available ultrafiltration units such as Viresolve/70' or Viresolve/180' membranes additionally, PLMK regenerated cellulose 300k cut off membrane all available from Millipore, The Boulevard, Blackmore Lane, Watford, Herts. An alternative method to reduce virus contamination is microfiltration using a Nylon membrane in cartridge form for example Nylon 66.0.04M membrane from PALL.
A purification step to remove contaminating DNA may be introduced, for e:: "φle, a wash of the Protein A column using NaCI in the range 1M-3M in uffer at neutral pH preferably PBS at pH7.2. Glycine may be added to the NaCI preferably at about 1.5M in the pH range 8.8-9.0.
An anti-CD 52 antibody of the present invention may be a monoclonal antibody obtained from a hybridoma of murine or rat origin and/or may be obtained using recombinant DNA technology.
Recombinant DNA technology has provided the ability to develop altered antibodies of two basic types. The first type, referred to as chimeric antibodies, is where the rodent constant domains only are replaced by equivalent domains of human origin (Morrison et al. P.N.A.S.. 1984, 81, 6851-6855; Boulianne et al, Nature, 1985, 314. 268-270; and Neuberger et al, Nature. 1985, 1 , 268-270). The second
type is where the murine constant domains and the murine framework regions are all replaced by equivalent domains and regions of human origin. This second type of antibody is referred to as a humanised or CDR-grafted antibody (Jones et al, Nature. 1986, 321, 522-525; and Riechmann et al, Nature. 1988, 332, 323-327). These antibodies more closely resemble human antibodies when administered to a human patient and so do not elicit an anti-antibody response to the same degree. A human antibody could also be used.
Accordingly the purified anti-CDw52 antibody of the invention may be a -rat, mouse or iiumaπ antibody wherein the amino acid sequences of the heavy and light chains are homologous with those sequences of antibody produced by the species lymphocytes in vivo or in vitro by hybridomas. Preferably the anti-CDw52 antibody is an altered antibody such as a hybrid antibody in which the heavy and light chains are homologous to a natural antibody but are • combined in a way that would not occur naturally. The antibody may be chimaeric antibody which has variable regions from one antibody and constant regions from another. Thus, chimaeric antibodies may be species/species chimaeras or class/class chi aeras. Such chimaeric antibodies may have one or more further modifications to improve antigen binding ability or to alter effector functioning. Another form of altered antibody is a humanised or CDR-grafted antibody including a composite antibody, wherein parts of the hypervariable regions in addition to the CDRs are transferred to the human framework. Additional amino acids in the framework or constant regions of such antibodies may be altered. Thus within the scope of the invention is included, any anti-CDw52 altered antibody in which the amino acid sequence is not one which exists in nature. However, CDR-grafted antibodies are most preferred of which Campath IH (Trademark of The Wellcome Foundation Ltd.) is an example. The antibody chain DNA sequences including the CDRs of Campath IH are set out in EP0328404, the disclosure of which is hereby incorporated by reference. The invention therefore includes a purified preparation of an anti-CDw52 antibody wherein the antibody comprises one or more of the CDR sequences set out in EP0328404.
Purified anti-CDw52 antibodies are useful in medical therapy for treating numerous human disorders, generally as immunosuppressives more particularly for example T-cell mediated disorders including severe vasculitis, rheumatoid arthritis, systemic lupis, also autoimmune disorders such as multiple sclerosis, graft vs host disease, psoriarsis, juvenile onset diabetes, Sjogrens' disease, thyroid disease, myasthenia gravis, transplant rejection and asthma. These antibodies are also useful in treating cancers such as Non-Hodgkins lymphoma and leukemias.
The invention therefore provides the use of a purified preparation of an anti-CDw52 antibody in the manufacture of a medicament for the treatment of any of the aforementioned disorders. Also provided is a method of treating a human being having any such disorder comprising administering to said individual a therapeutically effective amount of a purified preparation of an anti-CDw52 antibody.
The dosages of such antibodies will vary with the condition being treated and the recipient of the treatment, but will be in the range 1 to about 100 mg for an adult patient, preferably 1 - 10 mg, usually administered daily for a period between 1 and 30 days. A two part dosing regime may be preferable wherein 1 - 5 mg are administered for 5 - 10 days followed by 6 - 15mg for a further 5 - 10 days.
Also included within the invention are formulations containing a purified preparation of an anti CDw52 antibody. Such formulations preferably include, in addition to antibody, a physiologically acceptable diluent or carrier possibly in admixture with other agents such as other antibodies an antibiotic. Suitable carriers include but are not limited to physiological saline, phosphate buffered saline, phosphate buffered saline glucose and buffered saline. Alternatively, the antibody may be lyophilised (freeze-dried) and reconstituted for use when needed, by the addition of an aqueous buffered solution as described above. Routes of administration are routinely parenteral
including intravenous, intramuscular, subcutaneous and intraperitoneal injection or delivery.
The accompanying drawings show:
Figure 1.
(a) the LD9 construct containing expression cassettes for the 'crippled' dhfr selection/amplification marker and the Campath-IH light chain cDNA. The small box with the dashed arrow is the weakened SV40 promoter; the larger dotted box with an arrow is- the /3-actin promoter; polyA refers -to - respectively sourced polyadenylation and termination signals; the small box with ori contains the SV40 origin of replication;
(b) the pNH316 construct containing expression cassettes for the neomycin selection marker and the Campath-IH heavy chain cDNA. The box with an arrow and MT refers to the mouse metallothionein promoter. Restriction sites indicated are:- H, Hindlll; Bg, Bglll; B, Ba HI; RI, EcoRl.
Figure 2.
SDS polyacrylamide gel of non-reduced and reduced Campath IH showing a single main band.
Figure 3.
Reversed phase high performance chromatograph of non-reduced Campath IH showing a single peak.
Figure 4.
Reversed phase high performance chromatograph of reduced and carboxymethylated Campath IH showing two resolved peaks corresponding to the heavy and light chains of the antibody.
Figure 5.
High performance size exclusion chromatograph of non-reduced Campath IH showing a single peak.
Figure 6.
High performance size exclusion chromatograph of reduced Campath IH showing two major peaks.
Example 1
Production of Campath IH from CHO cells
EXAMPLE IA: Cloning of the Heavy and Light Chain cDNAs for Campath-IH
The complementarity determining regions from the rat Campath-1G monoclonal were originally grafted directly into genomic human heavy and light chain frameworks (Winter et al. Nature. 1988, 322, 323-327). These constructs were engineered for expression in the myeloma cell line YO and resulted in yields of Campath-IH of up to 5μg/ml following 10-14 days in culture (Hale et al. Tissue Antigens. 1990, 35, 118-127 and Winter et al. Nature. 1988, 322, 323-327). The myeloma cell line TF57 (Hale et al, ibid.) was used to generate size selected cDNA fractions of 0.9-1.2kb and 1.4-1.7kb for the light and heavy chain cDNAs respectively. These were used to make EcoRl linkered cDNA libraries in λgt_.0. All procedures were as described by Huynh et al
(DNA Cloning. Vol I: A Practical Approach, 1984, Glover,D(Editor) , IRL
32 Press,Oxford) . The libraries were screened using [ P] nick
translated probes specific for the variable regions to isolate full length cDNA clones. For the light chain cDNA, the 5' untranslated leader was removed up to position -32 using Bal-31 exonuclease and a Hindlll linker added. For the 3' end, use was made of a unique Sad site 47bp upstream of the stop codon. A Sacl-Hindlll synthetic oligonucleotide pair was used to regenerate this sequence and position the Hindlll site immediately after the stop codon. For the 5' end of the heavy chain cDNA, the unique Ncol site overlapping the ATG start codon was used to re-build a 29bp untranslated leader, identical to that of the light chain, using a Hindlll-_NcoI oligonucleotide pair. At the 3' end, the unique Nael site 12bp downstream of -the stop codon was ^converted into a Hindlll site using linkers.
EXAMPLE IB: Construction of Vectors:
The human ?-actin promoter was excised from pH3APr-3-neo (which corresponds to pH^APr-1-neo (Gunning et al, P.N.A.S.. 1987, 84, 483-35) except that the SV40 polyadenylation/termination signal has been replaced with the respective human β-actin signals) as a 2860 bp PvuII-Hindlll fragment, in which the PvuII site was subsequently converted to a Bglll site using linkers. To isolate the human 3-actin polyadenylation and termination signals from pH?APr-3-neo, an SphI site.l.4kb downstream of the unique Hindlll site was converted to a BamHI site using linkers. The basal dhfr vector called pl04, was constructed as follows. The SphI site at position -128 in the SV40 promoter in pSV2dhfr (Subramani et al. Mol.Cell.Biol.. 1981, I, 854-864) was converted into a Sail site to remove all enhancer elements from the promoter. The weakened dhfr expression unit was then subcloned as a Sall-BamHI fragment into the homologous sites in pSVOd (Mellon et al. Cell. 1981, 2∑, 279-288).
To construct pLD9, the pl04 vector was digested with BamHI, phosphatased, and ligated with three other fragments consisting of the Bglll-Hindlll ^-actin promoter, the Hindlll Campath-IH light chain cDNA and the Hindlll-BamHI ^-actin polyA/termination signals. To
construct pNH316, the construct pdBPV-MMTneo (Law et al. Mol.Cell.Biol.. 1983, 3 , 2110-2115) was digested with BamHI, phosphatased, and the fragment containing the neomycin gene isolated following separation on an agarose gel. This was ligated to the two ?-actin fragments and the Campath-IH heavy chain cDNA. The constructs, pLD9 and pNH316 are depicted in Figure 1.
EXAMPLE 1C: Expression of Campath-IH in CHO Cells:
The dhfr" CHO cell line DUK-B11 (Urlaub et al. P.N.A.S.. 1980, 77, 4216-4220) was grown in Iscove's MEM supplemented with 10% fetal bovine serum, and 4μg/ml each of hypoxanthine and thymidine. 10μg of pLD9 and pNH316 was co-precipitated onto cells using the calcium phosphate method, (Gorman et al. DNA Cloning. 1985, Vol II, 143-190, Academic Press,N.Y.) and selected for the double phenotype of dhfr /neo resistance by using the medium above except that 10% dialysed serum was used, the hypoxanthine/thymidine were omitted, and G418 (Gibco) was included at 500μg/ml. In some experiments MTX was included directly in the first round selection for dhfr transformants. Several hundred resistant colonies were pooled and assayed for the production of Campath-IH antibody in the culture medium. The average yield was 0.5/_g/ml for non-amplified first round transformants.
Each pooled cell population was then cultured in the presence of 10 M MTX, and after two weeks, resistant colonies were again pooled and titred for Campath-IH production. There was a considerable increase in yield of up to 80-fold (Table 1) . These cells were dilution cloned, screened for Campath-IH yield, and two high producer lines isolated, called A37 and 3D9 (Table 1) . These were both amplified
-6 further in the presence of 10 M MTX, then dilution cloned and screened as above. The increase in expression at this second, and final, amplification stage was not so dramatic as seen previously; nevertheless, when re-fed at confluence and left for a further 4 days,
the cell lines A39 and 3D11 were capable of producing up to 200μg/ml of Campath-IH.
TABLE 1
Expression Levels of Campath-IH using Stepwise Amplification
Accumulated
Construct Selection stage Campath-IH (μg/ml)
pLD9 + pNH316 dhfr /neo basal pool 0.5
10"7M MTX amplified pool 18-40
Cell lines A37 and 3D9 40
10 M MTX amplified pool 60-90
Cell line A39 100
Cell line 3D11 150-200
Cells were allowed to reach confluence in a T-175 tissue culture flask, then re-fed with fresh 50ml of tissue culture medium and left for a further 4 days. The Campath-IH antibody that had accumulated in the medium during this period was measured by
ELISA Total cell counts on the day of assay were usually 2.5 X
10 . Thee yyiieelldd ffrroomm tthle 3D11 cell line reflects a productivity 6 of 100μg/10 cells/day.
The co-transfection vectors pLD9 and pNH316 were further employed to evaluate an alternative amplification strategy to the one described above. The dhfr CHO cells were co-transfected as usual, and two days later split directly into a series of flasks containing G418 (for neomycin selection) and increasing concentrations of MTX ranging from
-9 -7 3 X 10 M to 10 M. Following two weeks of this selection, the number of resistant colonies were counted and pooled for each flask. When the cell populations had stabilized, they were assayed for Campath-IH antibody titres and the results are shown in Table 2. As the MTX level was increased, there was a marked decrease in the number of
A- surviving dhfr colonies, but they express proportionately more Campath-IH. Thus, in a one step direct selection at high concentrations of MTX, it is possible to isolate cell populations which produce up to 60-fold increase in antibody yield compared to cell populations selected for basal dhfr levels.
TABLE 2
Expression Levels of Campath-IH using Direct Selection
Accumulated Selection (M MTX) dhfr colonies Campath-IH (μg/ml)
No MTX 500 0.5
3 X 10 40
lO"8
3 X 10"8 5 30
lO"7
Colonies at each MTX selection stage were pooled and assayed as described in the legend of Table 1.
This selection procedure was repeated following another co-transfection of cells, and in this instance, the entire population
-8 was selected in medium containing G418 and 3 X 10 M MTX. This generated a larger pool of resistant colonies which were subsequently pooled and re-amplified twice more using MTX concentrations of 6 X
10" M, then 3 X 10" M. At this stage, the cells were dilution cloned and screened for Campath-IH levels. The two highest producer cell lines isolated were capable of producing antibody levels up to
100-150μg/ml and were designated_as lines 4F11 and 5E10.
The growth rates of these cell lines, and the A39/3D11 lines described above, were considerably slower than the parental non-transformed dhfr CHO cells. This is usually a common feature of these cells once they have been engineered to express high quantities of a product gene. The yields from the 5E10 and 4F11 cell lines proved to be quite variable over time, and the latter appeared to have only a limited passage life lasting about 3 weeks before entering crisis and death. This instability was not evident at all in the other cell lines, although in general, the lines isolated from the second amplification procedure, including 5E10, were usually more fickle to culture. Of all the lines, the 3D11 coupled good growth and stability with high Campath-IH yields. To ensure the propagation of these features, the 3D11 cell line was dilution cloned once more to generate the 3D11 line and this similarly produced Campath-IH yields up to 200μg/ml.
Example 2
*
Growth of and Production from CIH 3D11 44 in Serum Free medium
CIH 3D11* cells growing as a monolayer in Iscoves + 10% FBS Flow non-essential amino acids, 10" M Methotrexate and antibiotics were approximately 90% confluent. These cells were removed from the
plastic with trypsin/versene, washed in Iscoves medium without
4 supplements centrifuged and resuspended at 5 x 10 /ml in WCM4 medium set out in Table below + 0.25% peptone + 0.1% polyethylene glycol
(PEG) 10,000 + 0.5% fetal bovine serum (FBS) without methotrexate
2 (MTX) . Three 25cm flasks were set up with 10ml of cell suspension + hypoxanthine (H) , thymidine (T) or HT. These flasks were incubated at
36.5°C in 5% C0„ incubator.
After six days, the contents of the flasks were pooled and added to an equal volume of medium + MTX without peptone or PEG, and were
2 transferred to a 75cm flask.
These cells were used to seed a 500ml Techne spinner, incubated at 36.5 C spinning at 40 rpm. Cells continued growing serum free for a period of over five months and although it was found that the cells needed a period of adaptation, the growth rate and viability steadily improved. The population doubling time was calculated to be 73.1 hours over approximately 7 weeks; this decreased to 47.4 hours over the subsequent 20 days then stabilised. Antibody secretion remained high at levels in excess of 60 μg/ml. It was determined that the gene copy number in these cells did not decrease according to band intensity using Northern blot analysis.
In fermenters, these cells produced antibody in excess of 70μg/ml and regularly achieved levels of lOOμg/ml or more. These cells are donated CIH 3D11* 44.
WCM4 Medium
Iscoves DMEM (Iscoves N and Melcher (1978), J.Exp.Med. 1, 47, 923) modified to exclude BSA, transferrin and lecithin.
+ 5 ml/litre 200mM L glutamine
+ 50 mg/litre L proline
+ 50 mg/litre L threonine
+ 50 mg/litre L methionine +. _ 50 mg/litre. - L cysteine
+ 50 mg/litre L tyrosine
+ 25 mg/litre ascorbic acid
+ 0.062 mg/litre vitamin B6
+ 1.36 mg/litre vitamin B12
+ 0.2 mg/litre lipoic acid
+ 0.088 mg/litre methyl linoleate
+ lμM methotrexate
+ 1 mg/litre FeSO. 4
+ 1 mg/litre ZnSO. 4
+ 0.0025 mg/litre CuSO. 4
+ 5 mg/litre recombinant insulin (Nucellin)
+ 50,000 Iu/litre polymyxin
+ 20,000 Iu/litre neomycin
+ 0.16 mg/litre putrescine-2 HCL.
CIH 3D11*44 cells from previous stage which had been growing serum-free for over 2 months were transferred to a SGi 1 litre fermenter with a stainless steel angled paddle turning at 70rpm. The temperature was set at 37 C, d0„ at 10% and pH control to 7-7.2. The fermenter was seeded on day 0 with 0.22 x 10 cells/ml in WCM4 medium with 0.1% polyethylene glycol (PEG) 10,000 and 0.25% soy peptone, and
was top gassed with Q- . The cells were routinely passaged using fresh medium and a split rate typically between 1 to 2 and 1 to 4.
On day 33 the top gassing was replaced with deep sparging which is expected to cause more physical damage to the cells.
On day 50 onwards WCM5 (see Table below) was used together with peptone and PEG instead of WCM4.
On day 53 the PEG was replaced with 0.1% pluronic F68. The resulting growth and antibody levels achieved were in excess of lOOμg/ml in fermenters.
WCM5 Medium
Iscoves DMEM modified to ex-lude BSA, transferrin and lecithin.
All components in WCM4 and WCM5 are commercially available.
Example 3
Purification of Campath IH (G Dev-95.
Materials and Methods
The purification method used was based on chromatagraphy through three columns. The gels used were 7.85ml Protein A Sepharose 4 Fast Flow, Pharmacia code No. 17-0974-04 (10cm x 1cm); 7.85 ml S Sepharose Fast Flow cation exchanger, Pharmacia code No. 17-0511-01 (10cm x 1cm); and 120ml Superdex 200 size exclusion medium, Pharmacia code No.17-1046-01 (60cm x 1.6cm). Each column was protected by a 0.2 μm Gelman Aero sterilising filter.
Preparation of equipment and solutions
The hardware of the protein A column system was washed through with IN NaOH and left in this solution for 24 hours to remove endotoxin. The gel was then packed into the Pharmacia CIO/20 column and sanitized with 2% hibitane gluconate in 20% ethanol. Since, according to the manufacturer, S Sepharose and Superdex 200 gels are both stable in IN NaOH for prolonged periods these gels were packed into their columns (a Pharmacia CIO/20 and a C16/100 column respectively) washed through with IN NaOH and then left to stand in this solution for 24 hours to remove endotoxin and sanitize the column systems.
The solutions for column operation and sanitization were manufactured using pyrogen free distilled water and sterile filtered to 0.2 μm through Millipore Millipack 100 filters. Samples of all solutions were assayed for endotoxin by LAL test and only those with low values subsequently used.
Column operation
Protein A Sepharose 4 Fast Flow gel.
Tissue culture medium from Example 1 containing Campath IH antibody was supplied and filtered to 0.2μm through a sterile PALL posidyne SLK7002 NFZP filter in a Sealkleen housing. The 2% hibitane gluconate in 20% ethanol used to sanitize the protein A column system was removed with distilled water and the system equilibrated with the tris buffered saline pH 7.5 (T.B.S.). The protein A column was then loaded with 1.75 litres of crude Campath IH (71.4mg) at a flow rate of 300 cm hour (235 ml/hour) at a temperature of 20°C + 5°C. Unbound material was washe, from the column system with 5 bed volumes (39.25ml.) of T.B.S. pH 7.5 at the same flow rate. The Protein A gel was eluted at 300 cm hour with 0.1M citric acid pH 3.0 for <24 hours at room temperature. The elution profile was monitored at A280nm using a Pharmacia UVl single path monitor and the protein peak isolated. The elution peak volume was 18.9ml and 1ml of this was removed and assayed for Campath IH by ELISA as described below.
S. Sepharose Fast Flow gel
The IN NaOH was washed from the S.Sepharose column system with 20mM Hepes pH 7.5 until the column washings were at pH 7.5. The remaining 17.9ml. of Protein A column eluate was loaded onto the column at a flow rate of 300 cm/hour (235ml/hour). Unbound material was washed from the column system with 7 bed volumes (55ml) of 20mM Hepes pH 7.5 at the same flow rate. The S.Sepharose gel was eluted by a step elution, using 0.2M NaCI in 20mM Hepes pH 7.5 at a flow rate of 300 cm/hour. The elution peak was collected by trace using a Pharmacia UVl monitor at A280nm (2mm path le gth 0.5 AUFS). Eluate collection was started at approximately 20% deflection and continued until the trace had declined to 70% deflection. The elution volume was 10ml and lml of this was sampled for assay for Campath IH by ELISA as described below.
Superdex 200 gel
The IN NaOH was washed from the Superdex column system with PBS pH 7.2 until the column washings were at pH 7.2. The remaining 9ml of S Sepharose eluate was loaded onto the Superdex column with a syringe via a Millipore Millex GV filter and the filter washed through with 2ml of PBS pH 7.2. The column was developed with PBS pH 7.2 at 30 cm hour (60π_l/hour) . The size exclusion peaks were monitored using a Pharmacia UVl monitor at A280nm. As the peaks eluted fractions were taken in order to separate the aggregate peak from the monomer peak, the monomer peak fraction had a volume of 17.6ml.
Enzyme Linked Immunosorbent Assay (ELISA)
This is a standard Sandwich Enzyme Immunoassay (Reference) in which anti-human IgG, made from immune-purified goat antiserum, is attached to the solid phase as a capture layer. Detection of captured antigen (Campath IH Ig) is achieved with a peroxidase - labelled goat anti-human IgG. The assay is sequential with samples of Campath IH being diluted in a buffer containing casein and hydrolysed gelatin. Incubation periods of 1 hour and 30 minutes, are used at temperature of 37°C. 3',3',5,5' Tetrameth lbenzidine (TMB) chromagen plus hydrogen peroxide substrate are added to reveal any bound peroxidase. Optical densities at 450nm can be determined and Campath IH concentrations read from a standard curve of known concentrations ranging from 3.9ng to 250ng of purified Campath IH.
Testing of purified Campath IH
The protein content of the monomer peak was estimated at A280nm using
1% an extinction coefficent (E _ ) of 1.35 (optionally 1.32) and a sample examined for aggregate content by HPLC size exclusion column.
The remaining material was sterile filtered through a Millipore Millex
GV filter (0.2um pore size) and filled into 29 0.5ml aliquots in sterile Sarstedt tubes. The majority of the sample tubes were stored
at 4 C however 6 tubes were stored at -70 C. Samples from 4 C storage were sent for assays as detailed in the following examples.
Results and Discussions
The Campath ELISA results are shown in the table below.
Campath IH
Sample Titre Vol. (ml) Total mg Wgt.ClH % by ELISA of bulk CIH in applied recovery/ bulk next col. column
111.2
85.0
76.4
The overall recovery across the three column system, based on the recovery across each column is 61.6%.
Endotoxin content by LAL test
Sample Eu/ml
Crude 1.25
Superdex monomer <0.625 peak
Example 4
Conventional SDS polyacrylamide gel electrophoresis was carried out on a flat bed 8-18% gradient Pharmacia Excelgel. The results are shown in Figure 2.
Example 5
Characterisation of Campath IH by reversed phase high performance liquid chromatography.
A 50μl sample of the.product of Example 3 (designated G-Dev-95) in phosphate buffered saline (PBS) at a concentration of 2.4mg/ml was subjected to reversed phase high performance liquid chromatography (RP-HPLC) under the following conditions:
Column: PLRP-S 1000°A (pore size); 8μM (particle size) 15 x 0.46 cm from Polymer Laboratories Ltd UK.
Mobile phase utilised a formic acid/water/acetonitrile system: Component A - Formic acid: water (5:3).
B - CHjCN. in the following gradient:
The column was run at ambient temperature at a flow rate of lml/min and UV detection on IDC Spectro Monitor D variable wavelength was carried out at a wavelength of 280nm with a sensitivity of 0.1 a.u.f.s.
Result
As can be seen in Figure 3 chromatography of Campath IH utilising the above system gave a single sharp peak. The peaks eluting after 30 minutes are due to the mobile phase.
Example 6
Characterisation of reduced and carboxymethylated Campath 1 by reverse phase high performance liquid chromatography (RPHPLC)
6a. Reduction and carboxymeth lation of Campath IH
Campath IH may be reduced into its component heavy and light chains by utilising standard reduction and carbe .ymethylation procedures, which firstly reduce the disulphide bonds and prevents them reforming by alkylating the free thiol groups.
To 1ml Campath IH G Dev-95 from Example 3, in phosphate buffered saline at a concentration of 2.4 mg/ml was added 1ml of 8M Guanidinium chloride in 0.5M Tris/HCl pH 9.0 buffer and 120μl of 7% Dithiothreitol in the same buffer. The mixture was incubated for two hours at 37 C.
After incubation 120μl of 9% iodoacetic acid in 0.5M Tris/HCl buffer was added and the mixture was left in the dark for 1 hour. The resulting reduced carboxymethylated material was designated Campath IH RCM.
6b RP HPLC characterisation of Campath IH RCM
30μl of the material from Example 6a was subjected to reverse phase high performance liquid chromatography under the following conditions.
Column PLRP-S 1000 A (pore size); 8μ(particle size) 15 x 0.46 cm from Polymer laboratories Ltd UK.
Mobile phase used a water, formic acid and acetonitrile gradient as depicted in the table below:
Time (mins) 0 5 70 ' 72 82 82.1 95
The column was run at a flow rate of lml/min at ambient temperatures and followed by UV absorbance at a wavelength of 280nm a.u.f.s.
Result
As can be seen from Figure 4, the resulting material resolves into two peaks, corresponding to the heavy and light chains.
Example 7
Characterisation of Campath IH by high performance size exclusion chromatography for the determination of high molecular weight components in Campath IH.
A 50μl sample of the product of Example 3 (G-Dev -95) in phosphate buffered saline (at a concentration of 2.4mg/ml) was subjected to high performance size exclusion chromatography under the following conditions.
Column - TSK gel G3000 SWxl 30cm x 0.78cm i.d.
Mobile phase - 0.05M Na2H P04 + 0.1M Naχ SO adjusted with H-P04 to pH 6.8
Flow rate - 0.75 ml/min
The column was run for twenty four minutes at ambient temperature and followed by UV absorbance at a wavelength of 280 nm.
A second 50μl sample using Campath IH reduced in accordance with Example 6a) was analysed by the same method.
Results: The results in Figure 5 show a clean single peak indicating low levels of aggregate. Levels of between 0.5 and 2.0% are generally achieved. The results in Figure 6 show two main peaks corresponding to heavy and light chains in expected ratio. The peaks at total permeation volumn (ca.15-18 minutes) are due to reagents.
Biological assays for functional purified Campath IH
Complement lvsis assay for Campath IH
The complement lysis assay is a measure of antibody function expressed as specific activity, determined by the ability of a purified preparation of an anti-CDW52 antibody of known concentration to bind to a pre-determined number of cells and effect cell lysis.
The assay is carried out on Campath IH using Karpas 422 cells (established from B-cell non-Hodgkin lymphoma cell line - Dyer et al (1990) Blood, 75. 704-714) expressing Campath antigen on the cell surface. 1.2 x 10 cells were loaded with radiolabel by incubating for 2 hours at 37 C in a CO- incubator in the presence of 600μCi of
51
Cr (sodium chromate) .
5.3 ml of the loaded cells in medium (total volume 23.5ml), were added to 12.5ml of normal human serum and 150μl of the mixture were pipetted into the wells of a microtitre plate.
50μl samples of the final eluate from three purification runs were mixed with the cells and incubated for 30 minutes at 4 C followed by 90 minutes at 37 C. The culture was centrifuged at 2000 rpm for 5 minutes and the radioactivity in lOOμl of cell supernatant was counted on a gamma counter. Complement lysis activity in Kilo Units/ml was calculated from a standard curve of a reference preparation (1000 Units/ml) .
The results are set out in Table 3.
The concentration of Campath IH in the 50μl samples of final eluate was estimated using samples in PBS pH 7.2 read on a spectrophotometer at 280nm. The results are expressed in Table 3 as optical density in mg/ml.
From this data the specific activity in Kilo Units/mg is determined by using the equation: KU/ml
OD
Sample Complement Ivs Kilo Units/ml
A 11.2 B 14.8 C 13.7
The results indicate that purified preparations of Campath IH are functional.
Claims (16)
1. A purified preparation of an anti-CDW52 antibody which exhibits on size exclusion chromatography, a single peak under non-reducing conditions and two major peaks under reducing conditions.
2. A purified preparation as claimed in claim 1 which exhibits on conventional SDS polyacrylamide gel electrophoresis, one main band using a non-reduced sample and two main bands using a reduced sample.
3. A purified preparation as claimed in claim 1 or 2 which exhibits on reversed phase HPLC, a single peak under non-reducing conditions and two major peaks under reducing conditions.
4. A purified preparation of an anti-CDW52 antibody having a specific activity greater than 0.8 Kilo Units/mg.
5. A purified preparation of an anti-CDW52 antibody substantially free from host cell contaminants and/or aggregates.
6. A purified preparation as claimed in any of claims 1 to 5 wherein the antibody is an altered antibody.
7. A purified preparation as claimed in claim 6 wherein the antibody is a CDR-grafted antibody.
8. A process of purifying an anti-CDW52 antibody comprising applying an aqueous solution of the antibody to:
a) a Protein A column so as to absorb the antibody onto the column and eluting the antibody with an acid solution; b) applying the acidic eluate to an ion-exchange column of charged particles so as to absorb the antibody and then eluting the antibody with an aqueous solution of counter-charged ions;
c) applying the aqueous eluate to a size exclusion column of porous particles so as to retain non-antibody molecules in the porous particles and to obtain the desired antibody in selected fractions produced from the column.
9. A process as claimed in claim 8 wherein the Protein A column is eluted at acid pH.
10. A process as claimed in claim 8 or 9 wherein the Protein A column is eluted with citric acid.
11. A process as claimed in any of claims 8 to 10 wherein the Protein A column is Protein A Sepharose.
12. A process as claimed in claim 8 wherein the ion-exchange column is a cation-exchange column.
13. A process as claimed in claim 8 wherein the ion-exchange column is an anion-exchange column.
14. A formulation containing a purified preparation of an anti-CDW52 antibody according to any of claims 1 to 7 and a physiologically acceptable diluent or carrier.
15. A purified preparation of an anti-CDW52 antibody according to any of claims 1 to 7 for use in therapy.
16. Use of a purified preparation of an anti-CDW52 antibody according to any of claims 1 to 7 in the manufacture of a medicament for immunosuppression, for the treatment of T-cell mediated disorders, severe vasculitis, rheumatoid arthritis, systemic lupis, multiple sclerosis, graft vs host disease, psoriasis, juvenile onset diabetes, Sjogren's disease, thyroid disease, myasthenia gravis, transplant rejection, or asthma.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
AU45218/97A AU716402B2 (en) | 1990-10-17 | 1997-11-13 | Purified immunoglobulins |
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
GB909022547A GB9022547D0 (en) | 1990-10-17 | 1990-10-17 | Purified immunoglobulin |
GB9022547 | 1990-10-17 | ||
PCT/GB1991/001816 WO1992007084A1 (en) | 1990-10-17 | 1991-10-17 | Purified cdw52-specific antibodies |
Related Child Applications (3)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
AU25321/92A Addition AU658926B2 (en) | 1990-10-17 | 1992-09-23 | Purified immunoglobulin |
AU70242/94A Division AU7024294A (en) | 1990-10-17 | 1994-08-11 | Purified immunoglobulins |
AU45218/97A Division AU716402B2 (en) | 1990-10-17 | 1997-11-13 | Purified immunoglobulins |
Publications (3)
Publication Number | Publication Date |
---|---|
AU8729491A AU8729491A (en) | 1992-05-20 |
AU649078B2 AU649078B2 (en) | 1994-05-12 |
AU649078C true AU649078C (en) | 1995-04-13 |
Family
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