Hypoxia induces dichotomous and reversible attenuation of T cell responses through reactive oxygen species-dependent phenotype redistribution and delay in lymphoblast proliferation.

IF 3.6 3区 生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
Dharmendra Kumar Maurya, Deepak Sharma, Santosh Kumar Sandur
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引用次数: 0

Abstract

As T cells transit between blood, lymphoid organs, and peripheral tissues, they experience varied levels of oxygen/hypoxia in inflamed tissues, skin, intestinal lining, and secondary lymphoid organs. Critical illness among COVID-19 patients is also associated with transient hypoxia and attenuation of T cell responses. Hypoxia is the fulcrum of altered metabolism, impaired functions, and cessation of growth of a subset of T cells. However, the restoration of normal T cell functions following transient hypoxia and kinetics of their phenotype-redistribution is not completely understood. Here, we sought to understand kinetics and reversibility of dichotomous T cell responses under sustained and transient hypoxia. We found that a subset of activated T cells accumulated as lymphoblasts under hypoxia. Further, T cells showed the normal expression of activation markers CD25 and CD69 and inflammatory cytokine secretion but a subset exhibited delayed cell proliferation under hypoxia. Increased levels of reactive oxygen species (ROS) in cytosol and mitochondria were seen during dichotomous and reversible attenuation of T cell response under hypoxia. Cell cycle analysis revealed maximum levels of cytosolic and mitochondrial ROS in dividing T cells (in S, G2, or M phase). Hypoxic T cells also showed specific attenuation of activation induced memory phenotype conversion without affecting naïve and activated T cells. Hypoxia-related attenuation of T cell proliferation was also found to be reversible in an allogeneic leukocyte specific mixed lymphocyte reaction assay. In summary, our results show that hypoxia induces a reversible delay in proliferation of a subset of T cells which is associated with obliteration of memory phenotype and specific increase in cytosolic/mitochondrial ROS levels in actively dividing subpopulation. Thus, the transient reoxygenation of hypoxic patients may restore normal T cell responses.

缺氧通过活性氧依赖的表型再分配和淋巴细胞增殖的延迟诱导T细胞反应的二分性和可逆性衰减。
当T细胞在血液、淋巴器官和外周组织之间运输时,它们在炎症组织、皮肤、肠内壁和次级淋巴器官中经历不同水平的氧/缺氧。COVID-19患者的危重疾病也与短暂性缺氧和T细胞反应衰减有关。缺氧是T细胞亚群代谢改变、功能受损和停止生长的支点。然而,暂时缺氧后正常T细胞功能的恢复及其表型再分配动力学尚不完全清楚。在这里,我们试图了解在持续和短暂缺氧下二分T细胞反应的动力学和可逆性。我们发现,在缺氧条件下,有一部分活化的T细胞聚集成淋巴细胞。此外,T细胞表现出正常的活化标志物CD25和CD69的表达和炎症细胞因子的分泌,但一部分细胞在缺氧条件下表现出延迟的细胞增殖。在低氧条件下,细胞溶胶和线粒体中的活性氧(ROS)水平在二分性和可逆的T细胞反应衰减过程中增加。细胞周期分析显示,分裂的T细胞(S期、G2期和M期)胞浆和线粒体ROS水平最高。缺氧T细胞在不影响naïve和活化T细胞的情况下也表现出活化诱导记忆表型转换的特异性衰减。在异基因白细胞特异性混合淋巴细胞反应试验中,发现缺氧相关的T细胞增殖衰减也是可逆的。总之,我们的研究结果表明,缺氧诱导T细胞亚群增殖的可逆延迟,这与记忆表型的消除和活跃分裂亚群中胞质/线粒体ROS水平的特异性增加有关。因此,缺氧患者的短暂再氧化可以恢复正常的T细胞反应。
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来源期刊
Free Radical Research
Free Radical Research 生物-生化与分子生物学
CiteScore
6.70
自引率
0.00%
发文量
47
审稿时长
3 months
期刊介绍: Free Radical Research publishes high-quality research papers, hypotheses and reviews in free radicals and other reactive species in biological, clinical, environmental and other systems; redox signalling; antioxidants, including diet-derived antioxidants and other relevant aspects of human nutrition; and oxidative damage, mechanisms and measurement.
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