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B 细胞内稳态的改变与 1 型糖尿病和 PTPN22 等位基因变异携带者有关。

Altered B cell homeostasis is associated with type I diabetes and carriers of the PTPN22 allelic variant.

机构信息

Translational Research Program, Benaroya Research Institute, Seattle, WA 98101, USA.

出版信息

J Immunol. 2012 Jan 1;188(1):487-96. doi: 10.4049/jimmunol.1102176. Epub 2011 Nov 21.

DOI:10.4049/jimmunol.1102176
PMID:22105996
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3670766/
Abstract

The PTPN22 genetic variant 1858T, encoding Lyp620W, is associated with multiple autoimmune disorders for which the production of autoantibodies is a common feature, suggesting a loss of B cell tolerance. Lyp620W results in blunted BCR signaling in memory B cells. Because BCR signal strength is tightly coupled to central and peripheral tolerance, we examined whether Lyp620W impacts peripheral B cell homeostasis in healthy individuals heterozygous for the PTPN221858T variant. We found that these subjects display alterations in the composition of the B cell pool that include specific expansion of the transitional and anergic IgD(+)IgM(-)CD27(-) B cell subsets. The PTPN22 1858T variant was further associated with significantly diminished BCR signaling and a resistance to apoptosis in both transitional and naive B cells. Strikingly, parallel changes in both BCR signaling and composition of B cell compartment were observed in type 1 diabetic subjects, irrespective of PTPN22 genotype, revealing a novel immune phenotype and likely shared mechanisms leading to a loss of B cell tolerance. Our combined findings suggest that Lyp620W-mediated effects, due in part to the altered BCR signaling threshold, contribute to breakdown of peripheral tolerance and the entry of autoreactive B cells into the naive B cell compartment.

摘要

PTPN22 基因变异 1858T,编码 Lyp620W,与多种自身免疫性疾病相关,这些疾病的共同特征是产生自身抗体,表明 B 细胞耐受丧失。Lyp620W 导致记忆 B 细胞中 BCR 信号转导减弱。由于 BCR 信号强度与中枢和外周耐受紧密相关,我们研究了 Lyp620W 是否会影响携带 PTPN221858T 变体杂合子的健康个体的外周 B 细胞稳态。我们发现,这些受试者的 B 细胞池组成发生了改变,包括过渡性和无能性 IgD(+)IgM(-)CD27(-)B 细胞亚群的特异性扩增。PTPN22 1858T 变体还与过渡性和幼稚 B 细胞中 BCR 信号转导显著减弱和抗凋亡能力降低有关。引人注目的是,1 型糖尿病患者的 BCR 信号转导和 B 细胞池组成都发生了类似的变化,与 PTPN22 基因型无关,揭示了一种新的免疫表型和可能的共同机制,导致 B 细胞耐受丧失。我们的综合研究结果表明,Lyp620W 介导的效应,部分归因于 BCR 信号转导阈值的改变,导致外周耐受的破坏和自身反应性 B 细胞进入幼稚 B 细胞池。

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