细胞对模拟微重力和流体动力应力的反应可以通过比较转录组学来区分

Nikolai V. Kouznetsov
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引用次数: 0

摘要

在轨道飞行和返回地球的微重力条件下,人体免疫系统受到损害。T细胞对免疫应答至关重要,并通过肌动蛋白介导的免疫细胞间相互作用来执行其功能,而这种相互作用可能受到MG条件的干扰。在我们的研究中,我们采用了两种传统的平台来模拟MG条件:快速旋转陀螺(CL)和随机定位机(RPM),然后使用RNA测序进行全局T细胞转录组分析。值得注意的是,两种选择的旋转模拟MG平台都迫使细胞在培养基中运动,并使细胞暴露在剪切力下,因此诱导细胞对水动力应力的一定反应。我们证明,模拟MG处理的T细胞转录组谱与水动力应激(HS)的T细胞转录组谱明显不同。利用RT-qPCR对肌动蛋白细胞骨架网络相关或参与的基因表达谱进行分析,证实了在T细胞对MG或HS的反应中存在两组差异调控基因。发现了几个可能参与T细胞重力感应的关键基因(Fam163b, Dnph1, Trim34, Upk-1b)。一些MG应答的候选生物标记基因(VAV1、VAV2、VAV3和NFATC2)和HS应答的候选生物标记基因(ITGAL、ITGB1、ITGB2、RAC1和RAC2)可用于在基因转录水平上区分这些过程。总之,MG诱导T细胞整体转录组的变化,导致细胞骨架网络基因表达的特异性变化。
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Cell Responses to Simulated Microgravity and Hydrodynamic Stress Can Be Distinguished by Comparative Transcriptomics
The human immune system is compromised in microgravity (MG) conditions during an orbital flight and upon return to Earth. T cells are critical for the immune response and execute their functions via actin-mediated immune cell-cell interactions that could be disturbed by MG conditions. In our study, we have applied two conventional platforms to simulate MG conditions: fast rotating clinostat (CL) and random positioning machine (RPM), followed by global T cell transcriptome analysis using RNA sequencing. Noteworthily, both selected rotational simulated MG platforms employ forced cell movement in cultural medium and expose cells to shear forces, therefore inducing certain cell response to hydrodynamic stress. We demonstrate that the T cell transcriptome profile in response to simulated MG treatment was clearly distinguishable from the T cell transcriptome response to hydrodynamic stress (HS). Gene expression profiling of genes related to or involved in actin cytoskeleton networks using RT-qPCR confirmed two sets of differentially regulated genes in the T cell response to MG or to HS. Several key genes potentially involved in T cell gravisensing (Fam163b, Dnph1, Trim34, Upk-1b) were identified. A number of candidate biomarker genes of the response to MG (VAV1, VAV2, VAV3, and NFATC2) and of the response to HS (ITGAL, ITGB1, ITGB2, RAC1, and RAC2) could be used to distinguish between these processes on the gene transcription level. Together, MG induces changes in the overall transcriptome of T cells, leading to specific shifts in the expression of cytoskeletal network genes.
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来源期刊
Journal of International Translational Medicine
Journal of International Translational Medicine MEDICINE, RESEARCH & EXPERIMENTAL-
自引率
0.00%
发文量
317
审稿时长
8 weeks
期刊介绍: Journal of International Translational Medicine (JITM, ISSN 2227-6394), founded in 2012, is an English academic journal published by Journal of International Translational Medicine Co., Ltd and sponsored by International Fderation of Translational Medicine. JITM is an open access journal freely serving to submit, review, publish, read and download full text and quote. JITM is a quarterly publication with the first issue published in March, 2013, and all articles published in English are compiled and edited by professional graphic designers according to the international compiling and editing standard. All members of the JITM Editorial Board are the famous international specialists in the field of translational medicine who come from twenty different countries and areas such as USA, Britain, France, Germany and so on.
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