Generation of a human hybridoma producing a pure anti-HLA-A2 monoclonal antibody

Cell surface phenotyping and cytokine production of Epstein-Barr Virus (EBV)-transformed lymphoblastoid cell lines (LCLs)

Epstein-Barr Virus-transformed B lymphoblastoid cell lines (EBV-LCLs) are routinely used for the in vitro expansion of T cells. However, these cell lines are reported to produce the cytokine IL-10, which is inhibitory for T cells. We, therefore, characterized a panel of 37 EBV-LCLs for a variety of cell surface markers, for secretion of various cytokines including IL-10 and for immunoglobulin production. These cell lines were derived from normal donors or patients with nonsmall cell lung cancer, acute myelogenous leukemia, melanoma or colon cancer. Overall, 26 lines were positive for CD19 and CD20, and 11 were negative for both. All of the lines were strongly HLA-DR+, while CD40 expression was variable. Twenty-four (65%) were both CD23+ and secreted immunoglobulin, and 33 expressed kappa and/or lambda light chains. Additionally, all of the EBV-LCLs were negative for T cell (CD3), NK cell (CD16, CD56), monocyte (CD14) and granulocyte (CD66b) surface markers. Some level of IL-10, IL-6, IL-12p40 and TNF-alpha cytokine production was detected in 33, 18, 19 and 12 EBV-LCLs, respectively. Together, these data reflect the heterogeneity of EBV-LCLs, which cautions their use nondiscriminately in various immunologic assays.

HLA (A*0201) Mimicry by Anti-Idiotypic Monoclonal Antibodies

Soluble MHC Ags and anti-Id (anti-anti-MHC) Abs have both been shown to inhibit MHC alloantigen-specific B cell responses in vivo. We hypothesized that some anti-idiotypic Abs function as divalent molecular mimics of soluble HLA alloantigen. To test this idea, we studied two well-defined anti-idiotypic mAbs, T10-505 and T10-938, elicited in syngeneic BALB/c mice by immunization with CRll-351, an HLA-A2,24,28-specific mAb. Each anti-Id induced “Ab-3” Abs in rabbits that cross-reacted with HLA-A2 but not with HLA-B Ags. Furthermore, each anti-Id could bind to and block Ag recognition by Ha5C2.A2, a human homologue of mAb CRll-351. Both anti-Id mAb displayed weak reactivity with the human mAb SN66E3, which recognized an overlapping but distinct determinant of HLA-A2 Ags; neither reacted with human mAb MBW1, which recognized a nonoverlapping HLA-A2 determinant. Amino acid sequence comparison of mAb CRll-351 heavy and light chain variable region complementarity-determining regions (CDRs) with those of mAb Ha5C2.A2 and SN66E3 revealed short regions of homology with both human mAb; a large insert in the light chain CDR1 of mAb SN66E3 distinguished it from both CRll-351 and Ha5C2.A2. The amino acid sequences of mAb T10-505 and T10-938, which differed markedly from each other, revealed no homology to the α2 domain sequence of HLA-A*0201 that contains the CRll-351 mAb-defined epitope. We conclude that structurally different anti-Id Abs can mimic a polymorphic conformational epitope of an HLA Ag. In the case of T10-505 and T10-938 mimicry was not based on exact replication of the epitope by the hypervariable loops of the anti-Id mAb.

A human monoclonal antibody, produced following in vitro immunization, recognizing an epitope shared by HLA-A2 subtypes and HLA-A28

In vitro immunization and subsequent immortalization of peripheral blood cells of a multiparous woman has resulted in the production of a stable human mouse heterohybridoma, 5C2A2, secreting an HLA-A2/A28-specific human monoclonal antibody. Although possibly exposed to HLA-A2 by transfusions, the cell donor showed no HLA-A2-specific serum antibodies. The present protocol for in vitro immunization includes the elimination of suppressor cells from the responder cell population, the presence of irradiated allogeneic lymphocytes as a source of antigen, as well as stimuli--recombinant interleukin-2 and a B-cell specific nucleoside analogue--causing the proliferation of B lymphocytes, prior to immortalization. The ability of the antibody 5C2A2 to detect all known HLA-A2 subtypes, except A2.3, and A28, allows identification of the serological epitope on the HLA-A2 molecule. Application of this in vitro immunization method allows the production of a set of HLA monoclonal antibody-secreting human hybridomas, independent of the existence of serum HLA antibodies in the lymphocyte donors.

Nucleotide sequences of the variable regions of a human monoclonal antibody against HLA-A1, A23, and A24

Nucleotide sequences of the heavy and light chain variable (VH and VL) regions of a human monoclonal antibody (4-35-7), which recognized HLA-A1, A23 and A24, were determined by means of the reverse transcriptase-polymerase chain reaction. This antibody was generated by Epstein-Barr virus transformation of lymphocytes obtained from a multiparous donor, followed by fusion with mouse myeloma cells. The VH gene segment belonged to the VHIII gene family, and used the DXP4 and JH4 gene segments. This VH gene segment had 92.9% homology to the germline gene VH26, and contained 21 nucleotide substitutions. Fourteen of them generated the replacements of amino acids, while 7 failed to generate the replacement. The ratio of replacement to silent mutations in complementarity determining regions (CDRs) was 7.0. The VL gene segment belonged to the VkI gene family, and used Jk4. This VL gene segment showed 96.1% homology to the germline gene HK102, and contained 11 nucleotide substitutions. Seven of them generated the replacement of amino acids, while 4 failed to generate the replacement. The high ratio of replacement to silent mutations in CDRs of the VH gene segment suggested that the multiparity caused the processes of antigenic selection and somatic mutation, and generated this anti-HLA antibody.

Activation of HLA-A2-specific memory B cells in severe combined immunodeficient mice

Peripheral blood leukocytes of all five HLA-A2-sensitized patients produced significant levels of human IgG (> or = 0.25 micrograms/ml) following polyclonal activation in vitro, but PBLs from only one patient (K.H.) who had been transfused recently (< 4 weeks) produced detectable anti-HLA-A2 IgG. PBLs from this in vitro responder and from one in vitro nonresponder (L.G.) were transferred intraperitoneally into SCID mice. A low level (range, 5-40 ng/ml) of human anti-HLA-A2 IgG was detected in the serum of the mice without additional stimulation. This anti-HLA-A2 IgG response was boosted (range, 40-200 ng/ml) when mice received a human skin xenograft or an early challenge with x-irradiated human leukocytes intraperitoneally. Although the anti-HLA antibodies produced were specific for HLA-A2, the boosting of anti-HLA-A2 IgG production did not require the expression of the HLA-A2 protein, since either HLA-A2-negative skin xenografts or HLA-identical x-irradiated PBLs enhanced the production of anti-HLA-A2 IgG. Dose-response of transferred PBLs and kappa:lambda composition of individual mouse anti-HLA-A2 production suggested that low-frequency human memory B-cell clones were stimulated to proliferate and/or triggered to become high Ab secretors by skin graft or PBL boost.

A human monoclonal antibody that detects HLA-A1, A23 and A24 antigens

We report the production and characterization of a human monoclonal IgM (mu, kappa) antibody recognizing the HLA A1, A23 and A24 antigens. B lymphocytes obtained from a multiparous Japanese woman were transformed in vitro by Epstein-Barr virus, screened with an immune adherence assay, and fused with a murine myeloma cell line, P3-X63-Ag8.653. After subcloning by limiting dilution three times, a stable antibody-secreting hybridoma cell line, 4-35-7, was identified. The culture supernant had a titer of 1:32-64 against each of A1-, A23- and A24-positive lymphocyte panels, and showed complete correlation (r = 1.00) with the A1, A23 and A24 antigens on a lymphocyte panel of 287 unrelated, class I HLA-typed donors by the NIH cytotoxicity assay. Monoclonality of the antibody was ensured by Southern blot analysis of the human immunoglobulin heavy chain gene of 4-35-7. In view of the published data on HLA class I nucleotide sequences, the antibody may recognize an antigeneic determinant including two amino acid residues, Asp-166 and Gly-167, in the alpha 2 helix of the class I molecule that are specific for A1, A23 and A24 so far analyzed.

Characterization of two human monoclonal antibodies reactive with HLA-B12 and HLA-B60, respectively, raised by in vitro secondary immunization of peripheral blood lymphocytes

We have developed an in vitro immunization system for the production of B-cell lines that secrete HLA-specific human mAbs. For this purpose, peripheral blood lymphocytes of parous women were stimulated with pools of allogeneic lymphocytes. Preferential outgrowth of B-lymphocytes was effected by inclusion of rIL-2 and a B-cell specific nucleoside analogue. Stimulated B cells were immortalized by EBV transformation, and specific antibody-producing transformants were fused to heteromyeloma or mouse myeloma cell lines, yielding stable hybridomas. This approach has led to the successful development of two human heterohybridomas producing HLA-specific mAbs reactive by complement-mediated cytotoxicity. The specificities of these human mAbs, reactive with HLA-B12(44 + 45) and HLA-B60, respectively, are fully concordant with those of HLA-typing sera.

Immunochemical analysis of a recombinant, genetically engineered, secreted HLA-A2/Q10b fusion protein

We engineered a fusion gene which encodes the alpha 1 and alpha 2 domains of HLA-A2 with the alpha 3 and truncated transmembrane domains of the murine class I-like protein Q10b, and transferred it into mouse L cells along with the gene for human beta 2-microglobulin (beta 2m). The secreted rA2/Q10b gene product consisted of a single heavy chain of molecular weight 42 kd that was noncovalently associated with the human beta 2m light chain. Native detergent-solubilized HLA-A2 and secreted rA2/Q10b proteins were found to be similar by: (a) the binding to mouse monoclonal anti-HLA antibodies in an ELISA; (b) the blocking of lysis of HLA-A2+ cells by human anti-HLA-A2,-B17, anti-HLA-A2,9,28, and anti-HLA-A2,28 cross-reactive group (CREG) antisera in a complement-dependent cytotoxicity assay; and (c) the ability when coupled to Sepharose to selectively purify HLA-A2,9,28 and HLA-A2,28 CREG-specific antibodies. Mouse L cells expressing rA2/Q10b produced as much as 2.5 micrograms protein per 10(6) cells/day, or 50- to 100-fold more antigen on a per cell basis than the level of HLA-A2 expressed by B-lymphoblastoid cell line or spleen cells. Thus rA2/Q10b represents a viable alternative to detergent-solubilized HLA-A2 for purification of anti-HLA-A2 antibodies and analysis of anti-HLA-A2 immune responses.

Intramolecular specificity of anti-HLA alloantibodies

Recent descriptions of epitopes within HLA class I antigens recognized by mouse monoclonal antibodies are providing an antigenic map of such molecules. However, for transplantation purposes, it is crucial to understand the epitope specificity of alloantibodies. To investigate this issue, we performed sequential absorption/elution studies with serum from a broadly sensitized patient and homozygous typing cells (HTCs) which shared one HLA-A,B antigen with the patient. Antibody reactivity in the different eluates was measured by flow cytometry in a panel of 20 HTCs. These studies revealed two major findings: (a) There were multiple antibodies recognizing one HLA antigen. For example, there were 8 anti-B62 antibodies, 8 anti-B51, 5 anti-B57, 5 anti-B46, and 4 anti-B35. (b) The reactivity of most antibodies correlated highly with the presence of specific amino acids at a given position in the target HLA molecule. Such residues were absent in most HLA antigens not recognized by the antibody. Most of the target residues were located in the accessible alpha helices or connecting loops, but at least one antibody reactivity appeared to be influenced by residues located in the beta sheets. The HLA antigens evaluated in this study were those of the B5, B15, B17 cross-reactive group which have multiple epitopic sites. However, further studies are necessary to determine if alloantibodies directed to other HLA molecules will have a similar or more restricted degree of complexity.