Characterization and epitope mapping of four HLA class II reactive mouse monoclonal antibodies using transfected L cells and human cells transfected with mutants of DQB1*0302

Single-chain recombinant HLA-DQ2.5/peptide molecules block α2-gliadin-specific pathogenic CD4+ T-cell proliferation and attenuate production of inflammatory cytokines: a potential therapy for celiac disease

Celiac disease (CD) is a disorder of the small intestine caused by intolerance to wheat gluten and related proteins in barley and rye. CD4(+) T cells have a central role in CD, recognizing and binding complexes of HLA-DQ2.5 bearing gluten peptides that have survived digestion and that are deamidated by tissue transglutaminase (TG2), propagating a cascade of inflammatory processes that damage and eventually destroy the villous tissue structures of the small intestine. In this study, we present data showing that recombinant DQ2.5-derived molecules bearing covalently tethered α2-gliadin-61-71 peptide have a remarkable ability to block antigen-specific T-cell proliferation and inhibited proinflammatory cytokine secretion in human DQ2.5-restricted α2-gliadin-specific T-cell clones obtained from patients with CD. The results from our in vitro studies suggest that HLA-DQ2.5-derived molecules could significantly inhibit and perhaps reverse the intestinal pathology caused by T-cell-mediated inflammation and the associated production of proinflammatory cytokines.

Characterization of an HLA-DQ2-specific monoclonal antibody. Influence of amino acid substitutions in DQ beta 1*0202

The HLA-DQ(alpha 1*0501, beta 1*0201) and-DQ(alpha 1*0501, beta 1*0202) (i.e., DQ2) heterodimers are probably involved in the pathogenesis of celiac disease and several other HLA-DQ-associated diseases. To obtain a tool for studies of these molecules, a mAb of the IgG1 isotype, 2.12.E11, was produced by immunization with purified DQ(alpha 1*0501, beta 1*0201) molecules and murine NIH 3T3 cells transfected with both DQA1*05011 and DQB1*0202. Panel cell studies with HLA homozygous B-lymphoblastoid cells and HLA-transfected murine cells demonstrated that 2.12.E11 bound only to cells expressing HLA-DQ beta 1*0201 or 0202, irrespective of the accompanying DQ alpha chain (i.e., DQ alpha 1*0501 or DQ alpha 1*0201). Another DQ2-specific mAb (XIII 358.4) and the broadly HLA class-II-reactive mAb Tü39 strongly inhibited binding of 2.12.E11. Epitope mapping employing mutants with single aa substitutions of DQ beta 1*0202 indicated that position 37 may be of some importance for 2.12.E11 binding. A triple mutant (45G-->E, 46E-->V, 47F-->Y) failed to bind 2.12.E11, suggesting a crucial role for one or more of these residues in the epitope. However, the expression of the mutant beta chain could not be formally proved, as none of the DQ2-reactive mAbs recognized this transfectant.

The cytotoxic HLA-DQ3 reactive human hybridoma antibody 4166 that may distinguish DQ7 + 8 from DQ9

The human cytotoxic hybridoma antibody 4166 (IgM kappa) was generated by fusing an in vitro EBV-transformed B-LCL from a multiparous woman with the mouse-human heteromyeloma fusion partner CB-F7. In microcytotoxicity and IIF tests with B-LCLs as target cells, the mAb 4166 was specific for DQ3 (= DQ7 + 8 + 9). However, when used for DQ typing of class-II-positive PBMCs, 4166 could be rendered functionally specific for DQ7 + 8 and did not react with DQ9+ PBMCs. Binding of mAb 4166 to DQ8-positive cells was efficiently blocked by several allotype-specific mAbs recognizing DQ8. Other HLA class-II-specific mAbs were unable to inhibit. With the use of mAb 4166, it is possible to discriminate DQ7 + 8 from DQ9 in serologic DQ typing.