Characterization of a mouse/human chimeric monoclonal antibody (17-1A) to a colon cancer tumor-associated antigen

Mouse monoclonal antibody 17-1A is specific for an antigen expressed on cells of human gastrointestinal malignancies and has been used in radioimmune imaging and therapy trials for patients with colon and pancreatic cancer. The cell line SG3/5 was generated by transfection of a nonproducing mouse myeloma line (SP2/0) with a chimeric gene construct composed of variable regions from the mouse 17-1A immunoglobulin (gamma 2a, kappa) and constant regions of human k and gamma 3 immunoglobulin genes. The secreted immunoglobulin was bound by mouse monoclonal antibodies to human IgG(Fc) and IgG3 but not by staphylococcal protein A. Gel filtration HPLC profiles of purified chimeric antibody were similar to normal human IgG3 but quite different from native 17-1A and normal human IgG1, 2, and 4. Native and chimeric 17-1A had similar patterns of reactivity with colon cancer, other adenocarcinoma, and leukemic cell lines. Competitive inhibition documented that native and chimeric 17-1A had identical capacities to inhibit radiolabeled native 17-1A binding to colon cancer cell lines. Thus, the chimeric 17-1A exhibits molecular characteristics of normal human IgG3 but retains the specificity and binding affinity of the native 17-1A murine monoclonal antibody. The native and chimeric 17-1A mediated similar modest degrees of human lymphocyte and monocyte ADCC in a 4-hr 51Cr release assay, and both failed to mediate complement lysis of colon carcinoma cell lines in the presence of human complement. This human/mouse chimeric monoclonal antibody may be a good candidate for use in clinical trials because it retains the tumor antigen specificity and human effector cell recognition of the native 17-1A, would presumably have a fivefold to 10-fold longer circulating half-life in man, and should be considerably less immunogenic as compared with native murine immunoglobulins.     

Construction, expression, and biologic activity of murine/human chimeric antibodies with specificity for the human alpha/beta T cell receptor.

Murine/human chimeric antibodies with specificity for the human TCR-alpha/beta have been produced by genetic engineering. The L and H chain V region exons encoding the murine mAb BMA 031 were isolated and inserted into mammalian expression vectors containing the human kappa and gamma 1 or gamma 4 C region exons. The chimeric genes were transfected into murine Sp2/O hybridoma cells by electroporation and transfectomas secreting chimeric antibody were isolated. Secretion levels ranged from 1 to 7 pg/cell/24 h. The chimeric antibodies bound specifically to T cells and competed effectively with the parental murine mAb for binding to these sites. The ability to promote antibody-dependent cell-mediated cytolysis was significantly enhanced in the chimeric antibodies as compared with murine BMA 031. C-dependent cytolysis, however, was not detectable with any of the antibodies. Chimeric BMA 031 is a clinically relevant, genetically engineered antibody with potential uses in transplantation, graft-vs-host disease, autoimmune diseases and other T cell-related disorders.     

Secretion of a homodimeric V alpha C kappa T-cell receptor-immunoglobulin chimeric protein

Transfection into lymphoid cells of a chimeric T-cell receptor-immunoglobulin gene has been used to generate a secreted water-soluble form of the variable (V) domain of a human T-cell receptor alpha chain for use in structural (i.e. x-ray crystallographic) studies. The chimeric protein consists of the V alpha region of the T-cell receptor of a diphtheria toxoid-specific human T-cell clone fused to a human immunoglobulin kappa light chain constant (C) region. It is efficiently secreted by myeloma cells as a noncovalent homodimer of 65-kDa molecular mass in the absence of either immunoglobulin heavy or light chain. The V alpha C kappa protein is extensively glycosylated, and its secretion is glycosylation-dependent. Chimeric genes containing the V beta region of this particular T-cell receptor linked to immunoglobulin C kappa or C gamma 2 regions are expressed intracellularly, but the products, although glycosylated, are not secreted, nor do they assemble with the V alpha C kappa protein. This suggests that the chimeric beta chain-immunoglobulin proteins are incorrectly folded and/or processed due either to the design of the gene fusions themselves or to the absence of vital T-cell-specific accessory molecules in the myeloma host.     

A mouse/human chimeric anti-(ganglioside GD3) antibody with enhanced antitumor activities

Ganglioside GD3, which is one of the major gangliosides expressed on the cell surface of human tumors of neuroectodermal origin has been focused on as a target molecule for passive immunotherapy. We have cloned the cDNA encoding the immunoglobulin light and heavy chains of an anti-GD3 monoclonal antibody KM641 (murine IgG3, ), and constructed the chimeric genes by linking the cDNA fragments of the murine light and heavy variable regions to cDNA fragments of the human and 1 constant regions, respectively. The transfer of these cDNA constructs into SP2/0 mouse myeloma cells resulted in the production of the chimeric antibody, designated KM871, that retained specific binding activity to GD3. Indirect immunofluorescence revealed the same staining pattern for chimeric KM871 and the mouse counterpart KM641 on GD3-expressing melanoma cells. When human serum and human peripheral blood mononuclear cells were used as effectors in complement-mediated cytotoxicity and antibody-dependent cell-mediated cytotoxicity respectively, the chimeric KM871 was more effective in killing GD3-expressing tumor cells than was the mouse counterpart KM641. Intravenous injection of chimeric KM871 markedly suppressed tumor growth in nude mice. The chimeric KM871, having enhanced antitumor activities and less immunogenicity than the mouse counterpart, would be a useful agent for passive immunotherapy of human cancer.     

抗HEV嵌合抗体的构建及在CHO细胞中的表达

通过RT-PCR方法从分泌戊型肝炎(戊肝)病毒中和性鼠源单克隆抗体(单抗)8C11的杂交瘤细胞中克隆出抗体基因的重链可变区(VH)、轻链可变区(VK)序列,并分别克隆到含有人gamma 1重链和kappa轻链恒定区序列的pcDNA3.1/Hygro和pcDNA3.1( )质粒中,共转染中华仓鼠卵巢癌细胞(CHO)细胞.RT-PCR结果表明,转染的CHO细胞转录了嵌合重链及轻链基因,间接ELISA及Western blot结果表明:翻译出的两种多肽在细胞内正确组装成嵌合抗体分子,并可分泌至细胞外,表达的嵌合抗体保留了原鼠单抗的抗原结合特异性及对8H3结合抗原的增强作用.8C11嵌合抗体的成功表达可降低鼠源性,为探讨戊肝抗体治疗的可能性奠定了基础.     

Cloning and high level expression of a chimeric antibody with specificity for human carcinoembryonic antigen

A mouse/human chimeric antibody has been constructed by using variable light and variable heavy regions from a murine hybridoma specific for human carcinoembryonic antigen (CEA) (CEM231.6.7). These V regions were combined with kappa and gamma-1 constant region genes cloned from human lymphocytes. The chimeric constructs were sequentially electroporated into murine non-Ig-producing myeloma (P3.653) and hybridoma (SP2/0) cell. Significant differences were seen in expression levels between the two cell types. High levels of expression (24 to 32 micrograms/ml/10(6) cells) were seen with several of the anti-CEA SP2/0 transfectomas but not with the P3.653 cells. The SP2/0 transfectoma lines were adapted to serum-free, chemically defined media and grown in large scale fermentation cultures where they continued to secrete high levels of antibody. The chimeric antibodies remain reactive against human CEA with affinity constants comparable to that of the parental hybridoma antibody. High level expression will make practical the production of chimeric antibodies for in vivo therapeutic and diagnostic purposes.     

Construction, expression and characterization of humanized antibodies directed against the human alpha/beta T cell receptor.

Completely humanized antibodies with specificity for the human alpha/beta TCR have been produced by genetic engineering. The L and H chain V region exons encoding the murine mAb BMA 031 CD regions and human EU framework regions were synthesized and replaced into previously isolated genomic fragments. These fragments were inserted into mammalian expression vectors containing the human kappa and gamma 1 C region exons. Two variants were constructed each containing selected BMA 031 amino acids within the human frameworks. The humanized genes were transfected into Sp2/0 hybridoma cells by electroporation and transfectomas secreting humanized antibody were isolated. Levels of antibody expression up to 7 pg/cell/24 h were obtained. The humanized antibody, BMA 031-EUCIV2, competed poorly with murine BMA 031 for binding to T cells. BMA 031-EUCIV3, however, bound specifically to T cells and competed effectively with both the murine BMA 031 antibody and a previously constructed chimeric BMA 031 antibody for binding to these cells. The relative affinity of BMA 031-EUCIV3 was about 2.5 times lower than BMA 031. The ability to promote antibody dependent cell-mediated cytolysis was significantly enhanced with the engineered antibodies as compared to murine BMA 031. Humanized BMA 031 is a clinically relevant, genetically engineered antibody with potential uses in transplantation, graft vs host disease, and autoimmunity.     

Characterization of a human T cell-specific chimeric antibody (CD7) with human constant and mouse variable regions

A chimeric human-mouse anti-T lymphocyte mAb (CHT2; SDZ 214-380) has been constructed by cloning the variable region exons of both the L and H chains from the murine hybridoma RFT2 which have CD7 specificity and reactivity with a 40-kDa Ag. The variable L chain exon was joined to the human C kappa, and the variable H chain exon was joined to the human IgG1 region exon encoding the human allotype nGlm(z), nGlm(a). The gene constructs were introduced by electroporation into SP2/0, a non-Ig-producing murine myeloma. The identical tissue reactivity of the newly made CHT2 and the original murine RFT2 mAb (CD7) was confirmed by blocking experiments as well as by immunohistology and flow cytometry. Because this new mAb may have clinical use, the CD7 Ag expression of T lineage cells has also been quantitated in double and triple immunofluorescence assays in combinations with mAb to restricted forms of leukocyte common Ag that designate unprimed (CD45R+) and primed T lymphocyte populations (UCHL1+). CHT2 shows very strong reactivity with large thymic blast cells and cortical thymocytes from which T-ALL originates. Strong staining is seen on CD45R+ unprimed "virgin" T lymphocytes, whereas the expression on UCHL1+ primed "memory" cell types is weaker unless these cells are reactivated by mitogens or Ag. Thus CHT2 may spare a substantial population of resting memory T cells which is relevant to its potential therapeutic use. In addition the chimeric antibody had a greater in vitro antibody dependent cytotoxicity and a prolonged half-life (4.2 to 5.0 days) in Rhesus monkeys.     

A human/mouse chimeric monoclonal antibody against CA125 for radioimmunoimaging of ovarian cancer

Murine monoclonal antibody 196-14 recognizes the ovarian-cancer-associated antigen CA 125, but the epitope it recognizes is different from that of monoclonal antibody OC125. We developed a human/mouse chimeric 196-14 using the variable regions of the murine 196-14 and human heavy-chain (l) and light-chain () constant regions. Cell binding and competitive inhibition assays using chimeric 196-14 labeled with¹²⁵I,¹¹¹In or^99mTc demonstrated that the in vitro immunoreactivity of the chimeric antibody was identical to that of the parental murine monoclonal antibody. However, in mice bearing human ovarian cancer xenografts, the clearance from blood was faster and absolute levels of accumulation in the tumor were lower for the¹²⁵I-labeled or^99mTc-labeled chimeric antibody than for the murine antibody labeled with the corresponding radionuclides. The tumor-to-blood radioactivity ratio was not significantly different between the chimeric antibody and the murine antibody, regardless of the radionuclide used for labeling. Chimeric antibody 196-14 labeled with¹³¹I,¹¹¹In or^99mTc is promising for the radioimmunoimaging of ovarian cancer.     

Transfectomas expressing both secreted and membrane-bound forms of chimeric IgE with anti-viral specificity.

Because of the lack of a cell line expressing on surface and secreting human IgE of known Ag specificity, the construction of a transfectoma line possessing such properties would be useful for studying the roles of surface IgE and the effects of anti-IgE antibodies on IgE-producing B cells. Toward this goal, the human genomic DNA segment encompassing the two exons encoding the membrane anchor peptide of epsilon-chain and their flanking regions was sequenced. Hybrid epsilon and kappa genomic DNA comprising the C regions of human epsilon- and kappa-chains and the H and L chain V regions of the murine mAb BAT123, which reacts with the gp120 envelope protein of HIV-1, were constructed. Mammalian expression vectors containing these fusion genes were used to transfect murine myeloma Sp2/0 cells, and transfectants stably expressing on surface and secreting into culture medium chimeric IgE were obtained. The chimeric IgE showed identical Ag-binding properties as the murine mAb BAT123. Acting in concert with the specific peptide Ag polyvalently coupled to a protein carrier, the chimeric antibody could induce histamine release from human blood basophils. These results demonstrate the potential utility of the transfectoma cells and the chimeric IgE in studying the roles of membrane-bound IgE and effects of anti-IgE antibodies on IgE-producing B cells.     

The design, construction and function of a new chimeric anti-CD20 antibody

A novel murine IgM-type anti-human CD20 monoclonal antibody (mAb) 1-28 was prepared in our Lab, which can induce apoptosis and inhibit proliferation of Daudi and Raji cells. However, the efficacy of 1-28mAb in human cancer therapy is likely to be limited by human anti-mouse antibody responses. A chimeric antibody, C1-28, containing 1-28mAb variable region genes fused to human constant region genes (gamma 1, kappa) was constructed. However, C1-28 lost the antigen-binding activity. Here, using sequence similarity and known 3D structure of antibody variable regions as template, the spatial conformations of 1-28 variable regions (i.e. V(H) and V(L)) were analyzed with computer-guided homology modeling methods. According to the surface electrostatic distribution and interaction free energy analysis, the relationship between structure and stability of 1-28 variable regions was studied theoretically and a new chimeric anti-CD20 antibody scFv-Ig named 5S was designed. Expression level of 5S in the culture supernatant was determined to be around 50mug/mL using sandwich ELISA method with chimeric antibody Rituxan as reference. 5S retained its murine counterpart's binding activity by fluorescence-activated cell-sorting analysis. Furthermore, it could kill CD20 positive Daudi and Raji cells by complement-dependent cytotoxicity. For binding affinity often decreased even lost when IgM antibody was constructed into chimeric IgG1 form, our success give a hint about how to construct a IgG1-type chimeric antibody from IgM-type murine antibody to preserve its binding activity.     

Convenient plasmid vectors for construction of chimeric mouse/human antibodies

Chimeric antibodies composed of mouse-derived variable regions and human-derived constant regions have been developed for clinical use. However, construction of chimeric mouse/human genes in expression vectors is time-consuming work. In this study, we developed convenient vectors for construction of chimeric mouse/human antibodies. The protocols are as follows: In mouse hybridomas and B cells, most active VH and V kappa genes can be identified as rearranged bands by Southern hybridization of EcoRI- and HindIII-digested DNAs with JH and J kappa probes, respectively, and such fragments can be isolated in lambda-EcoRI and lambda-HindIII vectors, respectively. We constructed two plasmids: pSV2-HG 1 gpt contains human C gamma 1 and Ecogpt genes, and only one EcoRI site upstream of the C gamma 1 gene; pSV2-HC kappa neo contains human C kappa and neo genes, and only one HindIII site upstream of the C kappa gene. An isolated EcoRI fragment containing a VHDHJH gene and a HindIII fragment containing a V kappa J kappa gene are inserted into pSV2-HC kappa neo, respectively. Both resulting plasmid DNAs are co-transfected into SP2/0 cell, a non-Ig-secreting mouse myeloma. Transformants are selected by both mycophenolic acid and G418. With this procedure, it takes only 2 months to obtain chimeric antibodies.     

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.     

Molecular cloning and chimerisation of an inhibitory anti-cathepsin B antibody and its expression in Chinese hamster ovary cells

The lysosomal cysteine protease cathepsin B is one of several proteases that have been linked to tumour progression. Its increased expression and secretion in tumour cells may facilitate the degradation of extracellular matrix proteins, leading to tumour cell invasion and metastasis. Specific inhibitory monoclonal antibodies are a possible alternative to synthetic inhibitors as a therapeutic tool for cancer treatment. An inhibitory monoclonal antibody, which binds to an epitope near the active site of cathepsin B and inhibits its proteolytic activity, was prepared and its effect on invasion of ras-transformed MCF-10A neoT cells was tested in vitro. Here we present the nucleotide sequences of the heavy and light chains of the inhibitory antibody and compare them to the murine immunoglobulin germline sequences for possible somatic hypermutations. Since no harmful mutations were found, a mouse/human chimeric antibody was constructed by fusing murine V(H) and V(L) variable regions of the inhibitory antibody with human gamma 1 and K constant regions, respectively. Chinese hamster ovary K1 cells were co-transfected with expression vectors pcD-NA3L and pcDNA3H and the reactivity of the isolated chimeric antibody was tested by ELISA and Western blotting. We could demonstrate an inhibitory effect of the chimeric antibody.     

Production of human-mouse chimeric antibody by high cell density perfusion culture

Two mouse myeloma cell lines which were transfected with chimeric mouse variable-human constant immunoglobulin heavy and light chain genes have been cultured at high cell density in a settling perfusion culture vessel to produce chimeric antibody specific for human common acute lymphocytic leukemia antigen (cALLA).J558L transfectant proliferated well in a serum-free medium (ITES-eRDF) to a viable cell density of 3.7×10⁷ cells/ml and produced chimeric antibody to a maximum value of 60 g/ml in 120 ml scale vessel. X63Ag8.653 transfectant reached a density of 1.9×10⁷ cells/ml in 1.2 I scale vessel in serum supplemented medium (10% FCS-eRDF) and produced chimeric antibody which consisted of chimeric gamma and chimeric kappa chains to a maximum value of 5.8 g/ml.     

Characterization of neutralizing mouse‐human chimeric and shuffling antibodies against botulinum neurotoxin A

Mouse‐human chimeric monoclonal antibodies that could neutralize botulinum neurotoxins were developed and an attempt was made to establish mouse hybridoma cell clones that produced monoclonal antibodies that neutralized botulinum neurotoxin serotype A (BoNT/A). Four clones (2–4, 2–5, 9–4 and B1) were selected for chimerization on the basis of their neutralizing activity against BoNT/A and the cDNA of the variable regions of their heavy (V_H) and light chains (V_L) were fused with the upstream regions of the constant counterparts of human kappa light and gamma 1 heavy chain genes, respectively. CHO‐DG44 cells were transfected with these plasmids and mouse‐human chimeric antibodies (AC24, AC25, AC94 and ACB1) purified to examine their binding and neutralizing activities. Each chimeric antibody exhibited almost the same capability as each parent mouse mAb to bind and neutralize activities against BoNT/A. From the chimeric antibodies against BoNT/A, shuffling chimeric antibodies designed with replacement of their V_H or V_L domains were constructed. A shuffling antibody (AC2494) that derived its V_H and V_L domains from chimeric antibodies AC24 and AC94, respectively, showed much higher neutralizing activity than did other shuffling antibodies and parent counterparts. This result indicates that it is possible to build high‐potency neutralizing chimeric antibodies by selecting and shuffling V_H and V_L domains from a variety of repertoires. A shuffling chimeric antibody might be the best candidate for replacing horse antitoxin for inducing passive immunotherapy against botulism.     

Expression of a functional mouse-human chimeric anti-CD19 antibody in the milk of transgenic mice

Human B cell lymphomas are suitable targets for immunotherapy. Clinical trials with mouse-human chimeric B cell-specific monoclonal antibodies (mAbs) have already shown promising results. However, limitations for their use in clinical trials can be the lack of sufficient amounts and high production costs. Expression of mAbs in the mammary gland of transgenic animals provides an economically advantageous possibility for production of sufficient quantities of a promising antibody for clinical trials and beyond. In this paper, we show the feasibility of this approach, by generating transgenic mice expressing mouse-human chimeric anti-CD19 mAbs in their milk. Mouse anti-CD19 variable (V) region genes were combined with human IgG1 heavy (H) and kappa light (L) chain constant (C) region genes and fused to the bovine -lactoglobulin (BLG) promoter in two separate expression cassettes. Co-injection resulted in five transgenic lines. In one of these lines completely assembled chimeric mAbs were secreted into the milk, at an approximate level of 0.5mg/ml. These mAbs were able to bind specifically to the CD19 surface antigen on human B cells.     

Stability of murine, chimeric and humanized antibodies against pre-S2 surface antigen of hepatitis B virus

We have constructed a humanized antibody with specificity for the pre-S2 surface antigen of hepatitis B virus (HBV) by grafting the complementarity determining regions (CDRs) of parental murine monoclonal antibody (mAb) into human anti-Sm antibody framework regions. The humanized antibody has a substitution at position 94 in a framework region of the heavy chain variable region, and exhibits the same antigen binding affinity as the parental murine monoclonal and chimeric antibodies. In order to assess the stability of these antibodies, thermal inactivation of the parental, chimeric and humanized antibodies was analyzed. Fifty percent inactivation of the chimeric and humanized antibodies was observed at 63.7 degrees C and 68.7 degrees C, respectively, compared to 55.0 degrees C for murine antibody. The humanized antibody also exhibited increased stability against denaturant. Guanidine-induced unfolding monitored by the changes in fluorescence intensity at 360 nm showed that midpoints of the transition of the chimeric and humanized antibodies were 2.47 M and 2.56 M, respectively, whereas that of the murine antibody was 1.36 M.