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.     

Phage display for the production of human monoclonal antibodies against human pathogens

In the last decade an increasing number of antibodies have made their way from the research benchtops into the clinics and many more are currently under clinical trial. Among monoclonal antibody-producing techniques, phage-display is undoubtedly the most effective and versatile. Cloning of the entire humoral repertoire derived from an infected patients into a phage display vector allows not only the simple generation of monoclonal antibodies of desired specificity, but also the molecular dissection of the antibody response itself. Generation of large panels of human monoclonal antibodies against human pathogens could open new perspectives in understanding the interplay between the infectious agent and the infected host providing tools for the prevention and the therapy of human communicable diseases. In this paper the basic principles of the phage-display approach as well as its most recent applications are reviewed.     

A high density culture system for the in-vitro production of human and mouse monoclonal antibodies

A simple high density cell culture system is described which demonstrates many of the features of commercially available hollow-fibre systems, but without the need to invest in a dedicated system. The system has been shown to achieve product concentrations of up to 40-fold greater than that obtained in batch culture making gram production of MAbs possible with considerable saving on serum costs.List of Symbols ELISA enzyme-linked immunosorbent assay - FBS foetal bovine serum - IgG immunoglobulin G - IgM immunoglobulin M - MAb monoclonal antibody - pH negative common logarithm of the hydrogen ion concentration - pO₂ dissolved oxygen concentration - RPMI 1640 Roswell Park Memorial Institute medium 1640     

A strategy for production of monoclonal antibodies to Echinococcus granulosus antigen 5 and antigen B.

Serum antibody responses to sheep hydatid cyst fluid (SHCF) and a purified Antigen 5 (Ag5) were examined in ELISA, immunoelectrophoresis (IEP) and immunoprecipitation (IP) to facilitate production of monoclonal antibodies (MAb) to E. granulosus Ag5 and Antigen B (AgB). Although sera from mice immunized with SHCF contained antibodies of various classes, the fusions using these donor mice resulted in mainly anti-AgB MAb, possibly due to the preferential selection of MAb to AgB by the SHCF-based ELISA screening system. Donor mice immunized with Ag5 also produced several classes of antibodies, and the resultant fusions enabled selection of IgG MAb to Ag5.     

A novel immobilized hybridoma reactor for the production of monoclonal antibodies

Summary Mouse hybridoma cells were succesfully cultivated for more than 640 hours in the interparticle spaces of a tubular reactor packed with spherical glass beads. The maximum monoclonal antibody (MAb) concentration attained was 110 mg/l and a viable cell density in the order of 1 × 10⁷ cells/ml was achieved. A productivity per reactor void volume of 5.2 mg MAb/hr/l was obtained, which is comparable to the best systems currently in use.     

Plant factories for the production of monoclonal antibodies

Like animal cells, plant cells bear mechanisms for protein synthesis and posttranslational modification (glycosylation and phosphorylation) that allow them to be seriously considered as factories for therapeutic proteins, including antibodies, with the development of biotechnology. The plant platform for monoclonal antibody production is an attractive approach due to its flexibility, speed, scalability, low cost of production, and lack of contamination risk from animal-derived pathogens. Contemporary production approaches for therapeutic proteins rely on transgenic plants that are obtained via the stable transformation of plant cells as well as the transient (temporary) expression of foreign proteins. In this review, we discuss present-day approaches for monoclonal antibody production in plants (MAPP), features of carbohydrate composition, and methods for the humanization of the MAPP carbohydrate profile. MAPPs that have successfully passed preclinical studies and may be promising for use in clinical practice are presented here. Perspectives on using MAPPs are determined by analyzing their economic benefits and production rates, which are especially important in personalized cancer therapy as well as in cases of bioterrorism and pandemics.     

Strategies for production of monoclonal anti-idiotype antibodies against human B cell lymphomas

Murine monoclonal antibodies (MAB) against the idiotype (Id) of B lymphocyte malignancies are powerful reagents for the study of these diseases, and are potentially useful for treatment. Different strategies for the production of these anti-Id MAB have been compared. Initially, the Id Ig from nonsecreting B cell tumors was "rescued" by human X mouse or human X human hybridization. These somatic cell hybridizations resulted in the secretion of human Ig in 10 and 100% of the fusions, respectively. In a second step, anti-Id MAB were produced by using the "rescued" Id Ig as immunogen. A more streamlined approach is based on a one-step procedure in which the tumor cell suspension is used as immunogen. This method of immunization, coupled with a four-layer ELISA, results in the detection of anti-Id MAB in a frequency of approximately 1% of the total hybrids. By using a pool of 10 different anti-Id MAB, each reactive with the tumor of one patient, we searched for idiotypic relatedness among a panel of 50 additional tumors. No cross-reactions were found, indicating that our current strategy results in the identification of unique idiotypic determinants among human B cell tumors. Idiotypic Ig can be found in the serum of patients with B cell tumors. Among groups of patients, there is a wide spectrum of serum Id levels, ranging from less than 0.01 microgram/ml to greater than 500 micrograms/ml.     

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.     

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.     

Antibody engineering,a strategy for the development of monoclonal antibodies

Antibody engineering is the selection process enabling the isolation of hybridoma clones, each of which produces an antibody with predefined qualities. The state of the art of hybridoma technology is reviewed with emphasis on the results obtained by antibody engineering in our laboratories for the development of monoclonal antibodies for specific use in diagnostic tests. The perspective for in vitro monoclonal antibody production as well as the application of monoclonal antibodies for diagnostic reagents, industrial purification and therapeutic use are indicated.     

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.

     

A modified hybridoma technique for production of monoclonal antibodies having desired isotypes

In the present study, we describe a modified hybridoma technique for production of monoclonal antibodies (mAbs) having a desired isotype. Mice were immunized with the antigen of interest. After having reached a high antibody titer, cells expressing IgM or IgG molecules were isolated from spleen cells of the immunized mice using a Magnetic Cell Sorting System. The isolated cells were fused with myeloma cells using the conventional fusion protocol. With the isolated IgM⁺ spleen cells, more than 75% (85 ± 7%; means ± SD) were IgM producing cells and a large number of IgM mAbs specific to the protein of interest were obtained. With the isolated IgG⁺ spleen cells, 41 ± 40% of the generated hybridomas produced IgG antibody and no IgM producing hybridoma was generated. A large number of IgG mAbs specific to the protein of interest could be produced. The results indicate that the generated hybridomas produce corresponding antibody isotypes as expressed on the surface of their starting cells. The technique that we have developed will be very useful for production of desired mAbs having a specific isotype.     

Development of human monoclonal antibodies: A review

This article describes the current status in the development of human monoclonal antibodies. Over the last ten years a lot of information about the human immune system has emerged. Combining these with the many new (bio-)technologies it is plausible that the long awaited breakthrough of this technology is close. This paper focuses on the classical cell-biological methods of achieving stable, antibody-producing human cell lines via cell fusion methods or virus derived transformations of human B-lymphocytes, as well as genetic engineering methods e.g. DNA libraries or phage display technology. The available in vitro immunization methods are critically reviewed and their impact on this topic is discussed. Therapeutic applications for cancer treatment or passive immunization against infectious diseases with antibodies derived by both ways are also reviewed.     

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     

Feasibility studies of large scale production of human anti-tetanus toxoid monoclonal antibodies

The feasibility of large scale production of human anti-tetanus toxoid monoclonal antibody for therapeutic use was evaluated using a human heterohybridoma. The effects of duration of subculture, transition from static to agitated culture conditions and the level of serum concentration were studied. The level of antibody secreted by the clone decreased with increasing length of subculture and decreasing serum concentration. The clone exhibited heterogeneity in expression of surface IgG after 2 or 7 weeks of subculture in static culture conditions irrespective of the serum concentration. However, a prolonged duration of subculture (9 weeks) in 3% serum medium had an effect on the expression of surface IgG both in static and agitated culture conditions. With respect to total (surface and intracellular) IgG, two distinct cell populations were observed. On long term subculture (9 weeks) in low serum medium (3% FCS), there was a decrease in the population which was the high synthesizer. In addition, when these cells were cultivated in agitated spinner flasks, a defect in secretion of antibodies was observed. Thus a general fall in the amount of antibody in the supernatant of agitated cultures was due to decrease in antibody synthesis as well as the defect in secretion of antibodies.     

A comparison of three different mammalian cell bioreactors for the production of monoclonal antibodies

Three different commercially available stirred tank reactors for mammalian cell culturing were compared for the ability to support hybridoma cell growth and monoclonal antibody production in batch mode operation. Despite quite similar vessel geometries differences were found both in growth and production profiles in the systems. These differences can possibly be related to the different aeration modes used in the bioreactors, and the levels of shear stress created by stirrer and agitator in the tanks.