Human monoclonal antibodies

Summary The technology for the production of murine monoclonal antibodies has been refined enormously since its introduction in 1975. However, the technology for generating human monoclonal antibodies has only recently come into its own. In this review, three currently available approaches to the production of human monoclonal antibodies are described. These include the hybridoma technique, based on the fusion of antibody-producing human B lymphocytes with either mouse or human myeloma or lymphoblastoid cells; the EBV immortalization technique, based on the use of Epstein-Barr virus (EBV) to immortalize antigen-specific human B lymphocytes; and the EBV-hybridoma technique, based on a combination of the first two methods.The EBV-hybridoma system retains the advantageous features of the other two systems while overcoming their pitfalls and may be the current method of choice for producing human monoclonal antibodies with a defined specificity.Recipient of a W.H.O. training scholarship in Tropical Diseases.Fellow of the National Cancer Institute of Canada.     

Fragmentation of monoclonal antibodies

Fragmentation is a degradation pathway ubiquitously observed in proteins despite the remarkable stability of peptide bond; proteins differ only by how much and where cleavage occurs. The goal of this review is to summarize reports regarding the non-enzymatic fragmentation of the peptide backbone of monoclonal antibodies (mAbs). The sites in the polypeptide chain susceptible to fragmentation are determined by a multitude of factors. Insights are provided on the intimate chemical mechanisms that can make some bonds prone to cleavage due to the presence of specific side-chains. In addition to primary structure, the secondary, tertiary and quaternary structures have a significant impact in modulating the distribution of cleavage sites by altering local flexibility, accessibility to solvent or bringing in close proximity side chains that are remote in sequence. This review focuses on cleavage sites observed in the constant regions of mAbs, with special emphasis on hinge fragmentation. The mechanisms responsible for backbone cleavage are strongly dependent on pH and can be catalyzed by metals or radicals. The distribution of cleavage sites are different under acidic compared to basic conditions, with fragmentation rates exhibiting a minimum in the pH range 5 to 6; therefore, the overall fragmentation pattern observed for a mAb is a complex result of structural and solvent conditions. A critical review of the techniques used to monitor fragmentation is also presented; usually a compromise has to be made between a highly sensitive method with good fragment separation and the capability to identify the cleavage site. The effect of fragmentation on the function of a mAb must be evaluated on a case-by-case basis depending on whether cleavage sites are observed in the variable or constant regions, and on the mechanism of action of the molecule.     

Immunotoxicity of monoclonal antibodies

Monoclonal antibodies (mAbs) are large molecules intended to bind to specific targets often expressed on the immune system, and to treat various immunopathological conditions. Therefore, mAbs can be considered to have a high potential for immunotoxicity, which is reflected in the clinical experience accumulated on mAbs-induced adverse effects related to immunosuppression, immunostimulation, and hypersensitivity (immunogenicity). So far, non clinical immunotoxicity studies have been inadequate to address all safety issues in relation to the possible immunotoxicity of mAbs, because they are fraught with limitations and pitfalls primarily related to the lack of relevant animal species. In addition, clinical studies rarely include validated end-points dedicated to the prediction of immunotoxicity. With the ongoing development of mAbs as novel therapeutic strategies for a wide variety of diseases, efforts should be paid to improve our understanding of mAbs-induced immunotoxic effects and design dedicated strategies to assess their immunological safety, both non clinically and clinically.     

Fragmentation of monoclonal antibodies

Fragmentation is a degradation pathway ubiquitously observed in proteins despite the remarkable stability of peptide bond; proteins differ only by how much and where cleavage occurs. The goal of this review is to summarize reports regarding the non-enzymatic fragmentation of the peptide backbone of monoclonal antibodies (mAbs). The sites in the polypeptide chain susceptible to fragmentation are determined by a multitude of factors. Insights are provided on the intimate chemical mechanisms that can make some bonds prone to cleavage due to the presence of specific side-chains. In addition to primary structure, the secondary, tertiary and quaternary structures have a significant impact in modulating the distribution of cleavage sites by altering local flexibility, accessibility to solvent or bringing in close proximity side chains that are remote in sequence. This review focuses on cleavage sites observed in the constant regions of mAbs, with special emphasis on hinge fragmentation. The mechanisms responsible for backbone cleavage are strongly dependent on pH and can be catalyzed by metals or radicals. The distribution of cleavage sites are different under acidic compared to basic conditions, with fragmentation rates exhibiting a minimum in the pH range 5–6; therefore, the overall fragmentation pattern observed for a mAb is a complex result of structural and solvent conditions. A critical review of the techniques used to monitor fragmentation is also presented; usually a compromise has to be made between a highly sensitive method with good fragment separation and the capability to identify the cleavage site. The effect of fragmentation on the function of a mAb must be evaluated on a case-by-case basis depending on whether cleavage sites are observed in the variable or constant regions, and on the mechanism of action of the molecule.Key words: fragmentation, cleavage, clipping, hinge region, peptide bond hydrolysis, IgG1, IgG2     

Immunotoxicity of monoclonal antibodies

Monoclonal antibodies (mAbs) are large molecules intended to bind to specific targets often expressed on the immune system, and to treat various immunopathological conditions. Therefore, mAbs can be considered to have a high potential for immunotoxicity, which is reflected in the clinical experience accumulated on mAbs-induced adverse effects related to immunosuppression, immunostimulation and hypersensitivity (immunogenicity). So far, non clinical immunotoxicity studies have been inadequate to address all safety issues in relation to the possible immunotoxicity of mAbs, because they are fraught with limitations and pitfalls primarily related to the lack of relevant animal species. In addition, clinical studies rarely include validated end-points dedicated to the prediction of immunotoxicity. With the ongoing development of mAbs as novel therapeutic strategies for a wide variety of diseases, efforts should be paid to improve our understanding of mAbs-induced immunotoxic effects and design dedicated strategies to assess their immunological safety, both non clinically and clinically.Key words: immunotoxicology, monoclonal antibodies, immunological safety evaluation     

Modulation by antiidiotypic monoclonal antibodies of immune lysis mediated by anti-HLA monoclonal antibodies

The mAb R18-9 recognizes a cross-reacting idiotope outside the Ag-combining site of the syngeneic anti HLA-DQw3 mAb KS13, whereas the mAb R1-38, KO3-34, KO3-256, and KO3-335 recognize spatially close private idiotopes within the Ag-combining site of mAb KS13. All the analyzed Id require the association of the H and L chain of mAb KS13 for their expression. The mAb R1-38 and R18-9 were shown to markedly differ in their ability to modulate immune lysis of target cells mediated by mAb KS13. mAb R18-9 did not affect C-dependent lysis of cultured B lymphoid cells WALK mediated by mAb KS13, but enhanced cell-dependent mAb KS13-mediated lysis. mAb R1-38 inhibited both C and cell-dependent lysis mediated by mAb KS13. The effect was influenced by the incubation conditions. mAb R1-38 completely inhibited lysis when it was preincubated with mAb KS13 before being added to target cells, inhibited it partially when it was added simultaneously with mAb KS13 to target cells and did not affect it when added to target cells which had been preincubated with mAb KS13. Neither mAb R1-38 nor R18-9 in combination with mAb KS13 modulated T cell proliferation induced by allogeneic HLA mismatched lymphocytes. The system we have described may represent a useful in vitro model to investigate the mechanism(s) by which antiidiotypic antibodies may influence the outcome of organs transplanted in recipients with a history of humoral presensitization to donor's HLA Ag.     

Preparation of monoclonal antibodies against duck hepatitis B core antigen and analysis of the monoclonal antibodies

Mice were immunized against duck hepatitis B virus core (DHBc) particles isolated from the liver of asymptomatic carrier ducks of duck hepatitis B virus (DHBV) by ultracentrifugation. Their spleen cells were fused with mouse myeloma (NS-1) cells, and 12 clones of hybridoma cells secreting antibodies against DHBc (anti-DHBc) were isolated. According to the reactivity to core particles and core peptide obtained from DHBc particles treated with SDS-2ME, the 12 antibodies were classified into two groups. Two monoclonal antibodies reacted against both core particles and core peptide (B-type), the other ten monoclonal antibodies reacted against core particles but did not react against core peptide obtained from DHBc particles treated with SDS-2 ME. (A-type). Solid phase enzyme immuno assay (EIA) using these two types of antibodies could detect core antigenisity not only in the liver homogenate but also in the DHBV infected serum. Sucrose gradient analysis and gel filtration analysis revealed this DHBc antigenisity in the serum is not carried by core particles but carried by core peptide, equivalent to HBe antigen in the serum of Hepatitis B virus (HBV) carrier. This EIA may provide sensitive test monitoring both serum DHBe antigen levels and DHBc antigen levels in the liver during DHBV infection.     

Mitogen-like monoclonal anti-actin antibodies

Monoclonal antibodies (IgM kappa) have been produced to actin isolated electrophoretically from L cell extracts. These monoclonal anti-actin antibodies bind to intact L cells and modulate DNA synthesis and cell proliferation, much like affinity-purified polyclonal rabbit antibody to the same Mr 42,000 actin. In addition, monoclonal antibodies specific for actin from Entamoeba histolytica also bound to and modulated the growth of L cells. A monoclonal antibody directed against a neuroblastoma surface antigen did not produce stimulation of L cells, and the binding activity of anti-actin monoclonal antibody to L cells was removed by absorption with actin covalently coupled to Sepharose. These observations demonstrate the specificity of interaction between the anti-actin monoclonal antibodies and the surface of intact L cells. We conclude that a surface actin-like molecule on the L cell, when bound by specific monoclonal antibody, initiates a stimulatory signal which results in enhanced cellular metabolism.     

Recombinant human monoclonal antibodies

To produce human monoclonal antibodies in bacteria, a gene repertoire of IgM variable regions was isolated from human peripheral B lymphocytes by the polymerase chain reaction. Alternatively, synthetic antibody genes with random hypervariable regions are being generated that may provide libraries of even higher complexity. For the selection of specific monoclonal antibodies from these libraries, we have developed twoE. coli vector systems that facilitate the surface display of an antibody physically linked to its own gene. The phagemid pSEX encodes a fusion protein of an antigen binding domain (Fv-antibody) with the docking protein (pIII) of filamentous phages. Specific antibody genes can therefore be enriched by antigen affinity chromatography. The plasmid pAP1 encodes a fusion protein of an Fv-antibody with a bacterial cell-wall protein. Bacteria carrying this plasmid express functional Fv-antibodies tightly bound to their surface. This should enable the selection of single cells with a fluorescence-assisted cell sorter (FACS) using labeled antigen or by adsorption to immobilized antigen. These vectors permit three major principles of the antibody response to be mimicked inE. coli:

1. Generation of a highly complex antibody repertoire;
2. Clonal selection procedures for library screening; and
3. The possibility of increasing a given affinity by repeated rounds of mutation and selection.

     

Preclinical development of monoclonal antibodies

The development of mAbs remains high on the therapeutic agenda for the majority of pharmaceutical and biotechnology companies. Often, the only relevant species for preclinical safety assessment of mAbs are non-human primates (NHPs), and this raises important scientific, ethical and economic issues. To investigate evidence-based opportunities to minimize the use of NHPs, an expert working group with representatives from leading pharmaceutical and biotechnology companies, contract research organizations and institutes from Europe and the USA, has shared and analyzed data on mAbs for a range of therapeutic areas. This information has been applied to hypothetical examples to recommend scientifically appropriate development pathways and study designs for a variety of potential mAbs. The addendum of ICHS6 provides a timely opportunity for the scientific and regulatory community to embrace strategies which minimize primate use and increase efficiency of mAb development.     

Biological screening of monoclonal antibodies

A method was developed to screen hybridomas secreting immunoglobulin to cell surface receptors by observing the ability of antibodies to inhibit cell attachment and survival. The model used to develop the screening procedure involved mouse hybridomas secreting monoclonal IgG to human epidermal growth factor (EGF) receptors. Conditioned medium from these hybridomas inhibited the attachment and subsequent growth of human foreskin fibroblasts unless excess EGF was added to the cultures. This procedure allows for the selection of hybridomas producing increased levels of immunoglobulin.