细胞生物学
FOXP3型
实验性自身免疫性脑脊髓炎
免疫系统
调节性T细胞
生物
周边公差
免疫耐受
T细胞
CD28
白细胞介素2受体
免疫学
作者
Hong Yu,Hiroshi Nishio,Joseph Barbi,Marisa Mitchell-Flack,Paolo Vignali,Ying Zheng,Andriana Lebid,Kwang‐Yu Chang,Juan Fu,Lee Blosser,Ada Tam,Drew Pardoll
出处
期刊:Journal of Immunology
[The American Association of Immunologists]
日期:2022-05-01
卷期号:208 (1_Supplement): 56.03-56.03
标识
DOI:10.4049/jimmunol.208.supp.56.03
摘要
Abstract T cell activation and tolerance are tightly regulated to ensure effective elimination of foreign antigen while maintaining immune tolerance to self-antigens. Development of T cell anergy and regulatory T cell (Treg) mediated suppression both contribute to the establishment of immune tolerance. Here, we show that neuritin (Nrn1), a conserved GPI-anchored surface molecule important for the development, survival and function of neurons, is highly expressed in anergic and Treg cells. Nrn1 deficient CD4 cells are resistant to Treg cell mediated suppression, display defective anergy induction, and have reduced peripheral Treg generation. Nrn1 deficient Foxp3+ Treg cells exhibit reduced control of inflammatory colitis. Moreover, upon induction of experimental autoimmune encephalomyelitis (EAE), Nrn1 deficient mice develop non-remitting disease and have increased spinal cord inflammatory infiltrates. These in vivo findings underscore the importance of Nrn1 in immune tolerance. Recently, Nrn1 was identified as an accessory component of the ionotropic AMPA receptor (AMPAR) complex in neurons. AMPARs mediate glutamate dependent cation flux and regulate cell membrane potential. Cell membrane potential can impact nutrient uptake, calcium influx, cell size, proliferation and survival. In vitro analysis reveals that Nrn1 deficient Treg cells exhibit reduced proliferation and survival, associated with higher membrane potential, reduced nutrient sensitivity, reduced glycolysis and mTOR activation. AMPAR blockade can correct proliferation defect in Nrn1 deficient Treg cells. These findings reveal Nrn1 as an important regulator of immune tolerance functioning through the modulation of glutamate activated AMPAR.
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