Adapting antibodies for clinical use.

Techniques for antibody engineering are now overcoming the problems that have prevented monoclonal antibodies being used routinely in clinical practice. With chemical and genetic manipulation antibodies can be linked to bacterial toxins, enzymes, radionuclides, or cytotoxic drugs, allowing targeting of treatment. Antigen binding sites from antibodies raised in mice can be jointed with human IgG to reduce immunogenicity. In vitro gene amplification and genetic engineering of bacteriophage have produced large antibody gene libraries and facilitated large scale production of human monoclonal antibodies with high specificity. The trickle of monoclonal antibodies into clinical practice may soon become a flood.     

A human hybrid myeloma for production of human monoclonal antibodies

We produced somatic cell hybrids between human myeloma cells and a lymphoblastoid cell line that is hypoxanthine phosphoribosyl transferase-deficient and ouabain-resistant. These hybrids were phenotypically similar to the human myeloma parental cells and grew as well as the human lymphoblastoid parental cells. After counterselection in 6-thioguanine, mutants that were 6-thioguanine-and ouabain-resistant were obtained, one of which was used as a fusion partner with lymphoblastoid B cells that produce anti-tetanus toxoid (TT) antibodies. These hybrids secreted human anti-TT monoclonal antibodies in much larger amounts than the parental lymphoblastoid cells, and were stable for a period of over 10 mo until the present time. Thus, by hybridizing plasmacytomas with lymphoblastoid cells, we constructed a fusion partner that secretes large amounts of immunoglobulin (Ig), grows at a fast rate, has a high fusion frequency, and supports the production of monoclonal antibodies over long periods of time. Moreover, anti-TT antibody-producing hybrids have been grown as solid tumors in irradiated BALB/c nude mice and then adopted to ascites growth, producing 1 to 8 mg of human immunoglobulin per 1 ml of ascites fluid.     

Methods for production of monoclonal antibodies with specificity for human lung cancer cells

We have developed a screening strategy and technology to produce monoclonal antibodies with specificity for human lung cancer cells. Mice and rats were immunized with well-characterized tissue culture lines of human small cell lung cancer (SCLC), mouse myeloma x spleen hybrids formed by the technique of Kohler and Milstein, and the resulting culture fluids were screened for antibody binding phenotype using a radioimmunoassay. To facilitate testing large numbers of culture fluids, a 96-well, microtiter based, reusable, replicating device was designed. Using this, many hybridoma culture fluids were replica plated for antibody binding tests on a series of human target cell plates. Hybrids producing antibodies that reacted with the immunizing SCLC line and another independent SCLC line, but not with autologous B-lymphoblastoid cells derived from one of the patients, were identified, selected, and then repeatedly recloned using the same screening strategy. With this technology, hybridomas representing less than 0.5% of all hybrids generated could be isolated and stable antibody producing cultures derived. Such antibodies reacted with a panel of well-characterized SCLC lines and SCLC samples taken directly from patients but not with a variety of normal tissues. Using these antibodies we can demonstrate: tumor cell contamination of bone marrow specimens, marked heterogeneity of antigen expression on cells within individual SCLC lines and individual patients, and inhibition of clonal growth of SCLC lines in soft agarose assays. All of these findings have potential clinical and cell biologic application.     

A novel platform to produce human monoclonal antibodies

A new technology has been developed that allows human antibodies to be quickly generated against virtually any antigen. Using a novel process, naïve human B cells are isolated from tonsil tissue and transformed with efficiency up to 85%, thus utilizing a large portion of the human VDJ/VJ repertoire. Through ex vivo stimulation, the B cells class switch and may undergo somatic hypermutation, thus producing a human “library” of different IgG antibodies that can then be screened against any antigen. Since diversity is generated ex vivo, sampling immunized or previously exposed individuals is not necessary. Cells producing the antibody of interest can be isolated through limiting dilution cloning and the human antibody from the cells can be tested for biological activity. No humanization is necessary because the antibodies are produced from human B cells. By eliminating immunization and humanization steps, and screening a broadly diverse library, this platform should reduce both the cost and time involved in producing therapeutic monoclonal antibody candidates.     

In vitro immunization for production of murine and human monoclonal antibodies: Present status

In vitro immunization is now receiving increasing attention as a novel approach in immunotechnolgy for producing monoclonal antibodies. This concept of immunization in culture will have a major impact on the field of human monoclonal antibodies, because human antibodis against any antigen can be produced without the need for presensitized patients. In this paper I will review the progress of in vitro immunization and why it is important to develop these systems for both murine and human cells.     

A novel platform to produce human monoclonal antibodies: The next generation of therapeutic human monoclonal antibodies discovery

A new technology has been developed by immunologix that allows human antibodies to be quickly generated against virtually any antigen. Using a novel process, naïve human B cells are isolated from tonsil tissue and transformed with efficiency up to 85%, thus utilizing a large portion of the human VDJ/VJ repertoire. Through ex vivo stimulation, the B cells class switch and may undergo somatic hypermutation, thus producing a human “library” of different IgG antibodies that can then be screened against any antigen. Since diversity is generated ex vivo, sampling immunized or previously exposed individuals is not necessary. Cells producing the antibody of interest can be isolated through limiting dilution cloning and the human antibody from the cells can be tested for biological activity. No humanization is necessary because the antibodies are produced from human B cells. By eliminating immunization and humanization steps and screening a broadly diverse library, this platform should reduce both the cost and time involved in producing therapeutic monoclonal antibody candidates.Key words: human, antibody, monoclonal, novel platform, naïve, B cell, therapeutic     

DNA topological change in the hyperthermophilic archaeon Pyrococcus abyssi exposed to low temperature

Abstract Mice were immunized with resin-bound peptides whose sequences have been proposed to be part of exposed loops in Salmonella typhi outer membrane protein OmpC. To screen hybridomas for monoclonal antibodies against those epitopes, we designed fusion proteins where the candidate peptide sequence was attached to the amino end of cholera toxin B-subunit (CTB). The constructed fusion proteins allowed the efficient selection of positive clones by GM1-ELISA. Selected antibodies recognized purified OmpC and whole Salmonella bacteria. This suggests a native structure of our genetically attached peptides in agreement with immunological properties reported for previous CTB recombinant fusion proteins. In a more general context, CTB hybrids could be used to screen for antibodies towards immunogenic epitopes in other systems. This might turn out to be particularly useful when producing antibodies against peptide sequences in microorganisms whose handling is difficult or that pose inherent health risks.     

Towards proteome-wide production of monoclonal antibody by phage display

Sequencing of the human genome reveals that there are approximately 30,000 genes that encode an even greater number of proteins which comprise the human proteome. Characterization of gene products at the genome-wide scale requires the development of high throughput methods to generate temporo-spatial information on each and every protein in the cell under normal and pathological conditions. Monoclonal antibodies are important reagents for these studies. We have developed a method to generate human monoclonal antibodies by selecting phage antibody libraries directly on antigen blotted onto poly(vinylidene fluoride) membranes. Cellular proteins are first separated by two dimensional (2D) gel electrophoresis, Western blotted onto poly(vinylidene fluoride) membranes, and used to select phage antibody libraries. Monoclonal antibodies can be generated against individual protein spots on a 2D gel. The antibodies are functional in Western blotting, ELISA, and immunohistochemistry. Automation of this process should allow high throughput production of monoclonal phage antibodies against cellular proteins as well as proteins that are uniquely expressed under pathological conditions.     

Methods for production of monoclonal antibodies with specificity for human lung cancer cells

Summary We have developed a screening strategy and technology to produce monoclonal antibodies with specificity for human lung cancer cells. Mice and rats were immunized with well-characterized tissue culture lines of human small cell lung cancer (SCLC), mouse myeloma x spleen hybrids formed by the technique of Kohler and Milstein, and the resulting culture fluids were screened for antibody binding phenotype using a radioimmunoassay. To facilitate testing large numbers of culture fluids, a 96-well, microtiter based, resuable, replicating device was designed. Using this, many hybridoma culture fluids were replica plated for antibody binding tests on a series of human target cell plates. Hybrids producing antibodies that reacted with the immunizing SCLC line and another independent SCLC line, but not with autologous B-lymphoblastoid cells derived from one of the patients, were identified, selected, and then repeatedly recloned using the same screening strategy. With this technology, hybridomas representing less than 0.5% of all hybrids generated could be isolated and stable antibody producing cultures derived. Such antibodies reacted with a panel of well-characterized SCLC lines and SCLC samples taken directly from patients but not with a variety of normal tissues. Using these antibodies we can demonstrate: tumor cell contamination of bone marrow specimens, marked heterogeneity of antigen expression on cells within individual SCLC lines and individual patients, and inhibition of clonal growth of SCLC lines in soft agarose assays. All of these findings have potential clinical and cell biologic application. Presented in the symposium on The Biology of Hybridomas at the 32nd Annual Meeting of the Tissue Culture Association, Washington, D.C., June 7–11, 1981. This symposium was supported in part by the following organizations: Bethesda Research Laboratories, Cetus Corporation, Hybritech Incorporated, MAB-Monoclonal Antibodies, Inc., National Capital Area Branch of the Tissue Culture Association, New England Nuclear Corporation, and Ortho Pharmaceutical Corporation.     

Reduction of High Background Staining by Heating Unfixed Mouse Skeletal Muscle Tissue Sections Allows for Detection of Thermostable Antigens With Murine Monoclonal Antibodies

Antigen detection with indirect immunohistochemical methods is hampered by high background staining if the primary antibody is from the same species as the examined tissue. This high background can be eliminated in unfixed cryostat sections of mouse skeletal muscle by boiling sections in PBS, and several proteins including even the low abundant dystrophin protein can then be easily detected with murine monoclonal antibodies. However, not all antigens withstand the boiling procedure. Immunoreactivity of some of these antigens can be restored by subsequent washing in Triton X-100, whereas immunoreactivity of other proteins is not restored by this detergent treatment. When such thermolabile proteins are labeled with polyclonal primary antibodies followed by dichlorotriazinylaminofluorescein–conjugated secondary antibodies and boiled, the fluorescence signal persists, and sections can then be processed with a monoclonal antibody for double immunostaining of a protein unaffected by boiling. This stability of certain fluorochromes on heating can also be exploited for double immunofluorescence labeling of two different thermostable proteins with murine monoclonal antibodies as well as for combination with Y-chromosome fluorescence in situ hybridization. Our method should extend the range of monoclonal antibodies applicable to tissues derived from the same species as the monoclonal antibodies. (J Histochem Cytochem 56:969–975, 2008)     

Monoclonal antibodies to the pituitary growth-hormone receptor by the anti-idiotypic approach. Production and initial characterization.

We obtained 10/192 and 3/384 antibody-secreting hybrids after immunization of Balb/c mice with either human growth hormone or affinity-purified rabbit anti-(human growth hormone) respectively. Radiolabelled rabbit anti-(human growth hormone) antibodies, but not human growth hormone, were specifically bound by supernatants from the 13 hybrids. The binding was completely inhibited by human-growth-hormone serum binding protein. However, anti-(human growth hormone antibodies) were detected in the sera of all the mice immunized with human growth hormone. In an independent fusion, which was carried out after immunization with fewer doses of human growth hormone, anti-(human growth hormone) antibodies were also obtained. Five hybrids, where the starting antigen was human growth hormone, were selected for ascites production, and the corresponding monoclonal antibodies were partially purified and characterized with respect to their immunoglobulin isotype and their interaction with human-growth-hormone receptors. These antibodies were found to enhance the binding of radioiodinated human growth hormone to human-growth-hormone serum binding protein from human and rabbit plasma by 40%. Scatchard analysis of the effect of one of the monoclonal antibodies showed that this enhancement was due to an increased number of binding sites. All of the partially purified antibodies but one (F12) inhibited the binding of human growth hormone to rat but not rabbit, liver microsomes to various extents, as well as to H-4-II-E rat hepatoma cells. Monoclonal antibody F12 enhanced the binding of radiolabelled human growth hormone to rat liver microsomes and H-4-II-E hepatoma cells. This enhancement was found to be due to an increase in the number of binding sites.     

Analysis of human monoclonal antibodies derived from lymphocytes of patients with cancer

Human lymphocytes from tumor-bearing patients and normal individuals have been fused with the NS-1 mouse myeloma line or the LICR -LON- HMY2 ( LICR -2) or SK0 -007 human cell lines. For a given number of lymphocytes, fusions with NS-1 produced 8 times more clones than fusions with LICR -2 and greater than 20 times more clones than fusions with SK0 -007. The percentage of clones that secrete human immunoglobulin (Ig) and the range of Ig production were comparable for clones derived from the three myeloma/lymphoblastoid lines. Clones derived from fusions with LICR -2 and SK0 -007 were found to secrete new species of light and heavy Ig chains in addition to those of the myeloma/lymphoblastoid lines, and clones derived from fusions with NS-1 secreted human Ig and contained both mouse and human chromosomes, which indicates that true hybrid cells were derived from fusions with each of the myeloma/lymphoblastoid lines under study. The stability of Ig production was similar for clones derived from fusions with NS-1, LICR -2, or SK0 -007; these results were comparable to those obtained with standard mouse/mouse hybrids. Stable clones producing human monoclonal antibodies that react with cell surface, cytoplasmic, cytoskeletal, nuclear, or nucleolar antigens have been isolated from tumor-bearing patients and normal individuals. A number of human monoclonal antibodies reactive with cytoskeletal antigens appear to be directed against components of the intermediate filament family. Techniques for the production of human monoclonal antibody appear to be sufficiently advanced to initiate a serological dissection of the humoral immune response to cancer.     

Human monoclonal antibodies to a genus-specific chlamydial antigen, produced by EBV-transformed B cells

Stable B cell lines producing human monoclonal antibodies to Chlamydia were established from salpingitis patients in the early convalescence phase. The antibody-producing cells were immortalized by Epstein Barr virus (EBV) transformation. Specific antibody-secreting clones were enriched by a stepwise microtiter plate cloning procedure. The selected B cell clones showed stable antibody production for more than 1 yr in continuous culture. Serologic specificity was demonstrated by micro-immunofluorescence (micro-IF) tests against a panel of Chlamydia reference strains. The antibodies were of the IgG1 subclass, and complement fixation could be demonstrated for one clone. There was no cross-reactivity against a large number of other bacteria. The monoclonal antibodies are directed against a common genus-specific surface antigen of the Chlamydia organism. Infected McCoy cells showed a brilliant, punctuated fluorescence surrounded by an inclusion membrane. Compared with conventional antisera, the monoclonal antibodies showed a clearer fluorescence pattern with very low background.     

Manufacture of biopharmaceutical proteins by mammalian cell culture systems

In the last several years, dramatic advances have been in the development of new biopharmaceuticals including monoclonal antibodies for diagnosis and treatment and such genetically engineered proteins as tPA, Factor VIIIc, erythropoietin and soluble CD4, an anti-AIDS protein. Currently, there are several hundred such candidate drugs in human clinical trials. In most cases, these protein-based drugs will require manufacture by mammalian cell culture due to the inability of lower organisms to properly glycosylate, fold, make correct disulfide bonds and secrete active biomolecular forms. The need for large scale production from cell culture will greatly increase as more of the products in clinical trials are approved for commercial production. This will require significant reduction in manufacturing costs per gram, concomitant with increased capacity to hundreds or perhaps even thousands of kilograms annually. As an example, Invitron's multi-reactor manufacturing facility has operated at greater than one-half million liters per year and has experience with more than 250 mammalian cell lines for producing protein drug products.     

Plasmodium falciparum: production of human antibodies specific for the MSP-3 protein in the Hu-SPL-SCID mouse

Human immunity against Plasmodium falciparum malaria is mediated by IgG antibodies. One of the major targets of protective antibodies is the MSP-3 protein. Anti-MSP-3 human monoclonal antibodies could therefore be valuable for passive immunotherapy, particularly of drug resistant malaria. Human monoclonal antibodies were previously produced in the Hu-SPL-SCID model reconstituted with human splenocytes, immunized by highly immunogenic neo-antigen or a recall antigen. We report here that this model can also be successfully employed to induce human antibody-secreting cells specific of low immunogenicity neo-antigens, such as MSP-3. These cells represent a new and valuable source of human monoclonal anti-malaria antibodies.     

An immunodominant domain in adenovirus type 2 early region 1A proteins.

Six independent rat hybridoma cell lines producing monoclonal antibodies to human subgroup C adenovirus early region 1A (E1A) proteins were isolated. Competition binding experiments revealed that each of the monoclonal antibodies was directed against the same epitope or overlapping cluster of epitopes on the E1A proteins. Viral E1A deletion mutants and deleted forms of E1A proteins expressed in Escherichia coli were used to localize the antibody recognition sites to sequences between amino acids 23 and 120, encoded within the first exon of the E1A gene. Similarly, polyclonal antisera raised against the trpE-E1A fusion protein, as well as against the native, biologically active E1A protein, were also directed primarily against this immunodominant region.     

Monoclonal antibodies against subunits of yeast mitochondrial H+-ATPase

Fourteen stable lines of myeloma-spleen cell hybrids producing antibodies against the mitochondrial H+-ATPase have been isolated. One reacted with the alpha-subunit of the enzyme complex (Mr 56000), nine with the beta-subunit (Mr 54000), and four with a 25 kDa subunit which has not been previously characterized. These antibodies are inhibitory or stimulatory or have no effect upon the enzyme activity. Two of the monoclonal anti-beta-subunit antibodies were found to be particularly effective in immunoprecipitating intact H+-ATPase complex.     

Production of antigen-specific human monoclonal antibodies from in vitro-primed human splenocytes

We have developed culture conditions for human lymphocytes that support primary in vitro immune responses to protein Ag of either human or nonhuman origin. We now show that these primed B cells can be efficiently immortalized by fusion with a heterohybrid fusion partner to generate human, Ag-specific IgM or IgG antibody-producing heterohybridomas at a rate of 17 to 50 hybrids/10(6) lymphocytes fused. Approximately 50% of the Ig-secreting clones were stable with respect to Ig secretion. Levels of secretion attained with terminal cultures ranged from less than 1 to 100 micrograms/ml. Fusions of cells between 2 and 5 days after initiation of in vitro exposure to Ag produced more Ag-reactive and Ag-specific antibodies than fusions at 1 day or fusions performed after 5 days. Ag-reactive hybrids could be isolated at frequencies of 3 to 10%, depending on antigenicity of the immunogen. Foreign proteins, horse spleen ferritin, and a murine monoclonal Ig, induced higher percentages of Ag-reactive mAb than immunization with the human-derived ferritin. Ag-reactive IgG mAb were produced at relatively high frequency, depending on immunization conditions and the nature of the Ag. The strategy for identification of the best hybrids included early elimination of unstable hybridomas and of hybridomas producing broadly cross-reactive antibody, followed by evaluation of units of Ag reactivity/micrograms Ig. Ferritin-specific mAb selected according to these criteria showed immunocytochemical reactivity with ferritin-containing tissues and apparent affinities in the range of 10(7) to 10(8)/mol.     

Preparation of "histocomposites" for direct immunohistochemical screening of monoclonal antibodies

Screening and selection of hybrids producing relevant antibodies in monoclonal technology usually rely on rapid and sensitive adsorption assays of the ELISA type. To identify clones producing antibodies with unexpected specificities direct immunohistological screening may be applied, but this is both tedious and expensive. Histocomposites made from a number of tissue types permit testing of supernatants at the required early stage after fusion. The multiple antigenic specificities displayed in such test specimens ensure detection of a broad range of antibodies. A simple method for production of the histocomposites is described.