An ex vivo method for rapid generation of monoclonal antibodies (ADLib system)

Here, we describe a protocol for using the ADLib (Autonomously Diversifying Library) system to rapidly generate specific monoclonal antibodies using DT40, a chicken B-cell line that undergoes constitutive gene conversion at both light- and heavy-chain immunoglobulin loci. We previously developed the ADLib system on the basis of our finding that gene conversion in DT40 cells was enhanced by treatment of the cells with a histone deacetylase inhibitor, trichostatin A (TSA). TSA treatment evolves a diversified library of DT40 cells (ADLib), in which each cell has different surface IgM specificity. Antigen-specific DT40 cells are selected from ADLib using antigen-conjugated magnetic beads, and their specificity can be examined by various immunological assays, using culture supernatant containing secreted IgM. The whole process from selection to screening can be completed in about 1 week. Thus, the ADLib system will accelerate biological studies, including drug discovery and design.     

IgM but not IgG monoclonal anti-Nocardia brasiliensis antibodies confer protection against experimental actinomycetoma in BALB/c mice

Nocardia brasiliensis is a facultative intracellular microorganism that produces a human chronic infection known as actinomycetoma. Human and mouse anti- N. brasiliensis antibody response identify P24, P26 and P61 immunodominant antigens. In this work, we generated immunoglobulin M (IgM) and IgG monoclonal antibodies (mAbs) specific to immunodominant P61 antigen. The monoclonal IgM (NbM1) and IgG2a (NbG1) antibodies were assessed for their in vitro bactericidal activity, in vivo protective effect and ability to block catalase activity. These mAbs specifically recognized P61, but they did not inhibit its enzyme activity. The in vitro bactericidal effect of NbG1 was higher than the killing ability of the IgM mAb. In vivo experiments with a murine model of experimental infection with N. brasiliensis injected into rear footpads was used to test the effect of NbM1 and NbG1. The negative untreated group developed a chronic actinomycetoma within 4 weeks. IgM mAbs conferred protection to BALB/c mice infected with N. brasiliensis . IgG mAb lacked this protective effect. IgM mAb showed a dose–response correlation between antibody concentration and lesion size. These results demonstrate that humoral immune response mediated by antigen-specific IgM antibody protects against an intracellular bacterial infection.     

Production of antigen-specific human monoclonal antibodies: comparison of mice carrying IgH/kappa or IgH/kappa/lambda transloci

Here we compare human monoclonal antibody (MAb) production from mouse strains that carry disruptions of their endogenous mouse IgH/IgK loci and harbor human IgM + Igkappa(BABkappa) or human IgM + Igkappa + IgA transloci (BABkappa,lambda). We found that whereas both strains proved effective for the isolation of antigen-specific IgM antibodies, many of the IgM MAbs elicited from BABkappa comprise human mu chains that are associated with mouse lambda chains. In contrast, BABkappa,lambda mice gave rise to fully functional, polymeric human IgM antibodies comprising both human IgH and human IgL chains. Therefore, the inclusion of a human Iglambda translocus (in addition to the human IgH + Igkappa transloci) not only diminishes problems of endogenous mouse Iglambda expression but also provides a strain of mice that yields fully human MAbs to a wide range of antigens, as witnessed by the isolation of MAbs to human blood cells, tumor cell lines, and an immunoglobulin idiotype.     

Recent advances in the generation of human monoclonal antibody

The use of monoclonal antibodies (mAbs) has now gained a niche as an epochal breakthrough in medicine. Engineered antibodies (Abs) currently account for over 30% of biopharmaceuticals in clinical trials. Several methods to generate human mAbs have evolved, such as (1) immortalization of antigen-specific human B cell hybridoma technology, (2) generation of chimeric and humanized antibody (Ab) from mouse Ab by genetic engineering, (3) acquisition of antigen-specific human B cells by the phage display method, and (4) development of transgenic mice for producing human mAbs. Besides these technologies, we have independently developed a method to generate human mAbs by combining the method of in vitro immunization using peripheral blood mononuclear cells and the phage display method. In this paper, we review the developments in these technologies for generating human mAbs.     

Isolation of monoclonal antibodies with predetermined conformational epitope specificity

Existing technologies allow isolating antigen-specific monoclonal antibodies (mAbs) from B cells. We devised a direct approach to isolate mAbs with predetermined conformational epitope specificity, using epitope mimetics (mimotopes) that reflect the three-dimensional structure of given antigen subdomains. We performed differential biopanning using bacteriophages encoding random peptide libraries and polyclonal antibodies (Abs) that had been affinity-purified with either native or denatured antigen. This strategy yielded conformational mimotopes. We then generated mimotope-fluorescent protein fusions, which were used as baits to isolate single memory B cells from rhesus monkeys (RMs). To amplify RM immunoglobulin variable regions, we developed RM-specific PCR primers and generated chimeric simian-human mAbs with predicted epitope specificity. We established proof-of-concept of our strategy by isolating mAbs targeting the conformational V3 loop crown of HIV Env; the new mAbs cross-neutralized viruses of different clades. The novel technology allows isolating mAbs from RMs or other hosts given experimental immunogens or infectious agents.     

Rapid generation of specific antibodies by enhanced homologous recombination

In the chicken immune system, gene conversion, a type of homologous recombination, primarily contributes to diversification of the immunoglobulin gene. Here, we report on the rapid generation of specific monoclonal antibodies using the chicken DT40 B-cell line undergoing gene conversion. We discovered that the gene conversion frequency at the immunoglobulin locus is increased by treating DT40 cells with a histone deacetylase inhibitor, trichostatin A (TSA), thereby generating diversity at the immunoglobulin locus in the majority of treated cells. This indicates that TSA treatment accelerates the autonomous diversification of surface IgMs on DT40 cells. We took advantage of this effect to select DT40 cells producing specific antibodies with antigen-conjugated magnetic beads. This autonomously diversifying library (ADLib) selection system enables the quick establishment (approximately 1 week from a diversifying library) of various clones producing monoclonal IgMs with enough specificity and affinity for immunological assays, and is applicable to various biotechnologies including rational protein design.     

Engineering Fully Human Monoclonal Antibodies from Murine Variable Regions

Fully human monoclonal antibodies (mAbs) derived from transgenic mice or human antibody libraries are the current state of the art for reducing the immunogenicity risk of antibody drugs. Here, we describe a novel method for generating fully human mAbs from nonhuman variable regions using information from the human germline repertoire. Central to our strategy is the rational engineering of residues within and proximal to CDRs and the V_H/V_L interface by iteratively exploring substitutions to the closest human germline sequences using semi-automated computational methods. Starting from the parent murine variable regions of three currently marketed mAbs targeting CD25, vascular endothelial growth factor, and tumor necrosis factor alpha, we have generated fully human antibodies with 59, 46, and 45 substitutions, respectively, compared to the parent murine sequences. A large number of these substitutions were in the CDRs, which are typically avoided in humanization methods. Antigen affinities of the fully human variants were comparable to the chimeric mAbs in each case. Furthermore, in vitro functional characterization indicated that all retain potency of the chimeric mAbs and have comparable activity to their respective marketed drugs daclizumab, bevacizumab, and infliximab. Based on local and global sequence identity, the sequences of our engineered mAbs are indistinguishable from those of fully human mAbs isolated from transgenic mice or human antibody libraries. This work establishes a simple rational engineering methodology for generating fully human antibody therapeutics from murine mAbs produced from standard hybridoma technology.     

Anti-schistosome monoclonal antibodies of different isotypes--correlation with cytotoxicity

Five monoclonal antibodies specific towards Schistosoma mansoni antigens were prepared by fusion of spleen cells of infected and immunized mouse with the murine myeloma NS-1 cells. Three of the five antibodies belonged to the IgG1 class, one was an IgM and the fifth one was an IgE. The IgE monoclonal antibody designated 54.10, induced antigen-specific degranulation of rat basophilic cell line, a property which served as the basis for the screening assay. Its biological function was demonstrated by a specific macrophage activation that led to killing of schistosomula; no such killing was obtained with anti-schistosome antibodies of other classes or with IgE of different antigenic specificity. The second monoclonal antibody of biological significance was an IgG1, designated 27.21 which is reactive in the immunofluorescence staining of surface antigens on intact schistosomula. All three monoclonal antibodies that belonged to the IgG1 class were effective in mediating killing of schistosomula by complement, with the highest effect exerted by 27.21. It is thus apparent that the 27.21 monoclonal antibody is directed against a densely distributed surface antigen on the schistosomula membrane which is possibly involved in the protective immunity. Preliminary data showed that immunoprecipitation with the 27.21 antibodies results in the isolation of three major protein bands, of 60 kd, 50 kd, 19 kd, respectively.     

HSV-IgM人-鼠嵌合抗体制备及稳定细胞株构建工艺开发

为实现体外大规模制备单纯疱疹病毒HSV-IgM(HSV1,HSV2)人鼠嵌合抗体,本研究通过RNA连接酶介导的cDNA末端快速扩增(RNA ligase-mediated rapid amplification of cDNA ends,RLM-RACE)技术获取其对应杂交瘤细胞基因序列,构建嵌合抗体至真核表达载体,在CHO-S细胞中稳定表达所需目的蛋白。同时优化稳定细胞株筛选工艺,对细胞池构建阶段和单克隆筛选阶段的加压条件进行摸索与探究,最后目的抗体采用蛋白L亲和纯化法进行纯化并进行生物活性检测;最终成功制备899 kDa和909 kDa的稳定高表达重组IgM抗体(HSV1,HSV2)细胞株。结果表明,最适筛选压力为20P200M(一轮加压)和50P1000M(二轮加压);使用加压培养基进行单克隆筛选抗体表达量较高,HSV1-IgM和HSV2-IgM单克隆最终表达量分别为1620 mg/L和623 mg/L。本研究为HSV1和HSV2的IgM系列重组抗体质控品开发以及体外高表达分泌IgM亚型抗体提供理论与实践基础。     

In vitro immunization of human lymphocytes. I. Production of human monoclonal antibodies against bombesin and tetanus toxoid

A procedure for in vitro sensitization of human lymphocytes against bombesin conjugated to tetanus toxoid (BTT) is described. Bombesin is a tetradecapeptide associated with small cell lung carcinoma. We found that antibody responses against bombesin as well as tetanus toxoid could be generated in vitro by culturing nylon-separated human splenic lymphocytes for 6 days with lipopolysaccharide, phytohemagglutinin-activated lymphocyte supernatants, human AB serum, and bombesin conjugated to tetanus toxoid. Cells sensitized by this procedure were fused to murine myeloma cells, NS-1. The specificities of resulting hybrids were analyzed by enzyme-linked immunoassays and competitive inhibition experiments. Hybrids secreting anti-bombesin (IgM) or anti-tetanus toxoid (IgM or IgG) were obtained. The ratio of IgG to IgM antibodies against tetanus toxoid could be increased by using antigen coupled to Sepharose beads. The sensitization procedure described here offers a system for the study of antigenic stimulation of human B lymphocytes in vitro and for the production of human monoclonal antibodies with the desired specificities.     

Antibody-mediated modulation of the immune response

We have studied the ability of monoclonal IgM and IgG antibodies to enhance or suppress immune responses and attempted to dissect the underlying mechanisms. Both IgM and IgG1 antibodies increased the rate of clearance of antigen from the circulation. Monoclonal IgM antibody to SRBC was found to specifically increase antibody responses, enhancement being insensitive to low doses of irradiation (150 R). IgM antibody specifically depressed the delayed hypersensitivity response to SRBC in vivo. Following administration of IgM in vivo, in vitro responses to SRBC were also enhanced. This in vitro enhancement appeared to depend on both T cells and B cells. In contrast, monoclonal IgG1 antibody to SRBC specifically depressed antibody responses in vivo. Such depressed antibody responses were also seen in vitro following IgG1 in vivo and did not appear to be due to the induction of suppressor T cells.     

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.     

Harnessing Gene Conversion in Chicken B Cells to Create a Human Antibody Sequence Repertoire

Transgenic chickens expressing human sequence antibodies would be a powerful tool to access human targets and epitopes that have been intractable in mammalian hosts because of tolerance to conserved proteins. To foster the development of the chicken platform, it is beneficial to validate transgene constructs using a rapid, cell culture-based method prior to generating fully transgenic birds. We describe a method for the expression of human immunoglobulin variable regions in the chicken DT40 B cell line and the further diversification of these genes by gene conversion. Chicken V_L and V_H loci were knocked out in DT40 cells and replaced with human V_K and V_H genes. To achieve gene conversion of human genes in chicken B cells, synthetic human pseudogene arrays were inserted upstream of the functional human V_K and V_H regions. Proper expression of chimeric IgM comprised of human variable regions and chicken constant regions is shown. Most importantly, sequencing of DT40 genetic variants confirmed that the human pseudogene arrays contributed to the generation of diversity through gene conversion at both the Igl and Igh loci. These data show that engineered pseudogene arrays produce a diverse pool of human antibody sequences in chicken B cells, and suggest that these constructs will express a functional repertoire of chimeric antibodies in transgenic chickens.     

Development of new versions of anti-human CD34 monoclonal antibodies with potentially reduced immunogenicity

Despite the widespread clinical use of CD34 antibodies for the purification of human hematopoietic stem/progenitor cells, all the current anti-human CD34 monoclonal antibodies (mAbs) are murine, which have the potential to elicit human antimouse antibody (HAMA) immune response. In the present study, we developed three new mouse anti-human CD34 mAbs which, respectively, belonged to class I, class II and class III CD34 epitope antibodies. In an attempt to reduce the immunogenicity of these three murine mAbs, their chimeric antibodies, which consisted of mouse antibody variable regions fused genetically to human antibody constant regions, were constructed and characterized. The anti-CD34 chimeric antibodies were shown to possess affinity and specificity similar to that of their respective parental murine antibodies. Due to the potentially better safety profiles, these chimeric antibodies might become alternatives to mouse anti-CD34 antibodies routinely used for clinical application.     

Chimeric human/murine monoclonal IgM antibodies to HIV-1 Nef antigen expressed on chronically infected cells

Human IgM antibody (Ab) to gangliosides induced cytolysis of HIV-1-infected cells by homologous human complement. We expected that any human IgM Ab reactive with HIV-1 infected cells could cause complement-mediated cytolysis. The trans-chromosome mouse (TC mouse) contains human chromosomes harboring genes responsible for immunoglobulin production. Spleen cells from TC mice immunized with recombinant Nef were fused with mouse myeloma cells to generate hybridomas, and we selected those that produced human mu-chain-positive Abs reactive with Nef fixed on an ELISA plate. However, the L-chain of the monoclonal Abs (mAbs) were murine lambda in type and were chimeric, and we could not succeed in obtaining mAb with human mu- and human kappa-chains. The chimeric mAbs reacted with the HIV-1 infected cells as seen with flow cytometric analysis, and the surface expression of Nef was also detectable on chronically infected OM10.1 cells which had no detectable gp120. However, although the reaction of the chimeric IgM mAb with HIV-1-infected MOLT4 cells induced C3 deposition on cell surfaces on incubation with fresh human serum, the cells remained unlysed, as determined by 51Cr release assay. The amount of Nef antigen on the cells might not have been high enough to overcome the function of HRF20 (CD59) that restricts formation of membrane attack complexes of homologous complement. However, combination of anti-Nef IgM mAb with other IgM mAbs reactive with the surface of HIV-1-infected cells may induce a synergistic effect in complement mediated cytolysis.     

Assessing kinetic and epitopic diversity across orthogonal monoclonal antibody generation platforms

The ability of monoclonal antibodies (mAbs) to target specific antigens with high precision has led to an increasing demand to generate them for therapeutic use in many disease areas. Historically, the discovery of therapeutic mAbs has relied upon the immunization of mammals and various in vitro display technologies. While the routine immunization of rodents yields clones that are stable in serum and have been selected against vast arrays of endogenous, non-target self-antigens, it is often difficult to obtain species cross-reactive mAbs owing to the generally high sequence similarity shared across human antigens and their mammalian orthologs. In vitro display technologies bypass this limitation, but lack an in vivo screening mechanism, and thus may potentially generate mAbs with undesirable binding specificity and stability issues. Chicken immunization is emerging as an attractive mAb discovery method because it combines the benefits of both in vivo and in vitro display methods. Since chickens are phylogenetically separated from mammals, their proteins share less sequence homology with those of humans, so human proteins are often immunogenic and can readily elicit rodent cross-reactive clones, which are necessary for in vivo proof of mechanism studies. Here, we compare the binding characteristics of mAbs isolated from chicken immunization, mouse immunization, and phage display of human antibody libraries. Our results show that chicken-derived mAbs not only recapitulate the kinetic diversity of mAbs sourced from other methods, but appear to offer an expanded repertoire of epitopes. Further, chicken-derived mAbs can bind their native serum antigen with very high affinity, highlighting their therapeutic potential.     

Generation of monoclonal antibodies to Macaca mulatta (rhesus) IgA

One IgG1 and five IgM murine monoclonal antibodies (mAb) specific for rhesus (Rh) IgA were generated. These mAbs bound to Rh IgA but not IgG or IgM when tested by enzyme-linked immunosorbent assay. Immunoblotting revealed that the mAbs reacted with the alpha heavy chain of Rh but not human IgA. The IgG1 anti-Rh IgA mAb detected IgA-producing cells in sections of monkey gut examined by immunofluorescent staining. These mAbs should be useful for characterizing IgA responses in the Rh monkey.     

Specificities of human heterophile Hanganutziu and Deicher (HD) antibodies to glycosphingolipids and a glycoprotein

The specificities of five heterophile Hanganutziu and Deicher (HD) antibody-containing sera from four different cancer patients and one other diseased patients were compared. Three glycosphingolipids and one glycoprotein antigens and their chemically modified derivatives were used. The antibodies of all whole sera showed similar specificities. IgG and IgM antibody fractions of each serum were separated. Although antibodies of the same class showed similar specificities, differences were detected between the specificities of IgG and IgM. IgG antibody specificities were dependent on the hydrophobic (ceramide) group while IgM antibodies were directed more to the terminal sialic acid moiety of the glycosphingolipid antigens. The results suggested that a similar population of IgG-producing lymphocytes is stimulated in patients. Due to the similarities in specificities of HD antibodies, the results of this study will facilitate the future isolation of either IgG or IgM antibody-producing lymphocyte(s) from a patient with HD antibodies and the establishment of a monoclonal antibody through hybridization with a human myeloma cell line.     

Construction and characterization of the chimeric antibody 8C11 to the hepatitis E virus

Homodimers of the truncated hepatitis E virus (HEV) capsid proteins, E2 and p239, were conformed to model the dominant antigenic determinants of HEV. Using E2 as an immunogen, two neutralizing monoclonal antibodies (mAbs), namely 8C11 and 8H3, were produced. We constructed a mouse-human chimeric antibody derived from 8C11 and its expression in Chinese hamster ovary (CHO) cells. cDNAs encoding variable regions of heavy and light chains were isolated from hybridoma cells and inserted into mammalian expression vectors containing cDNA of human gamma-1 and kappa constant regions, respectively. The vectors were then cotransfected into CHO cells, and a stable cell line was established. Results from indirect enzyme-linked immunosorbent assay (ELISA) and Western blot analysis showed that the chimeric antibody was assembled correctly to the native IgG molecule and could be secreted from the cells. Similar to the original mAb, the expressed chimeric antibody displayed HEV antigen-binding activity and an enhancement effect on 8H3 binding to HEV antigen. The chimeric antibody could specifically inhibit the binding of p239 to HepG2 cells and compete with HEV IgG in positive serum by antibody-competitive ELISA. The chimeric antibody is expected to be less immunogenic in human and more suitable for antibody therapy of hepatitis E.     

Efficient Recovery of High-Affinity Antibodies from a Single-Chain Fab Yeast Display Library

Yeast display is a powerful technology for the isolation of monoclonal antibodies (mAbs) against a target antigen. Antibody libraries have been displayed on the surface of yeast as both single-chain variable fragment (scFv) and antigen binding fragment (Fab). Here, we combine these two formats to display well-characterized mAbs as single-chain Fabs (scFabs) on the surface of yeast and construct the first scFab yeast display antibody library. When expressed on the surface of yeast, two out of three anti-human immunodeficiency virus (HIV)-1 mAbs bound with higher affinity as scFabs than scFvs. Also, the soluble scFab preparations exhibited binding and neutralization profiles comparable to that of the corresponding Fab fragments. Display of an immune HIV-1 scFab library on the surface of yeast, followed by rounds of sorting against HIV-1 gp120, allowed for the selection of 13 antigen-specific clones. When the same cDNA was used to construct the library in an scFv format, a similar number but a lower affinity set of clones were selected. Based on these results, yeast-displayed scFab libraries can be constructed and selected with high efficiency, characterized without the need for a reformatting step, and used to isolate higher-affinity antibodies than scFv libraries.