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Literature DB >> 30254034

Nature of T cell epitopes in lupus antigens and HLA-DR determines autoantibody initiation and diversification.

Zhenhuan Zhao¹, Jiling Ren¹, Chao Dai¹, Carol C Kannapell¹, Hongyang Wang¹, Felicia Gaskin², Shu Man Fu^3,4.

Abstract

OBJECTIVES: The generation of systemic lupus erythematosus (SLE)-related autoantibodies have been shown to be T cell dependent and antigen driven with HLA-DR restriction. In this study, the initiating antigen(s) and the mechanism of autoantibody diversification were investigated.
METHODS: T cell epitopes (T-epitopes) of SmD1 (SmD) were mapped by T-T hybridomas generated from DR3+AE0 mice immunised with SmD and with SmD overlapping peptides. TCRs from the reactive hybridomas were sequenced. The core epitopes were determined. Bacterial mimics were identified by bioinformatics. Sera from DR3+AE0 mice immunised with SmD peptides and their mimics were analysed for their reactivity by ELISA and immunohistochemistry. Samples of blood donors were analysed for HLA-DR and autoantibody specificities.
RESULTS: Multiple HLA-DR3 restricted T-epitopes within SmD were identified. Many T-T hybridomas reacted with more than one epitope. Some of them were cross-reactive with other snRNP peptides and with proteins in the Ro60/La/Ro52 complex. The reactive hybridomas used unique TCRs. Multiple T-epitope mimics were identified in commensal and environmental bacteria. Certain bacterial mimics shared both T and B cell epitopes with the related SmD peptide. Bacterial mimics induced autoantibodies to lupus-related antigens and to different tissues. HLA-DR3+ blood donors made significantly more SLE-related autoantibodies.
CONCLUSIONS: The unique antigenic structures of the lupus-related autoantigens provide the basis for being targeted and for T and B cell epitope spreading and autoantibody diversification with unique patterns. SLE-related autoantibodies are likely generated from responses to commensal and/or environmental microbes due to incomplete negative selection for autoreactive T cells. The production of SLE-related antibodies is inevitable in normal individuals. The findings in this investigation have significant implications in autoimmunity in general. © Author(s) (or their employer(s)) 2019. No commercial re-use. See rights and permissions. Published by BMJ.

Entities: CellLine Chemical Disease Gene Species

Keywords: HLA-DR; SLE; T cell epitopes; autoantibody; molecular mimicry

Mesh：

Substances：

Year: 2018 PMID： 30254034 PMCID： PMC6377330 DOI： 10.1136/annrheumdis-2018-214125

Source DB: PubMed Journal: Ann Rheum Dis ISSN： 0003-4967 Impact factor: 19.103

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