全转录组分析揭示通过可变剪接对人类巨噬细胞炎症表型的调控
Transcriptome-Wide Analysis Reveals Modulation of Human Macrophage Inflammatory Phenotype Through Alternative Splicing.
作者信息
Lin Jennie, Hu Yu, Nunez Sara, Foulkes Andrea S, Cieply Benjamin, Xue Chenyi, Gerelus Mark, Li Wenjun, Zhang Hanrui, Rader Daniel J, Musunuru Kiran, Li Mingyao, Reilly Muredach P
机构信息
From the Renal, Electrolyte, and Hypertension Division, Department of Medicine, Perelman School of Medicine (J.L.), Department of Biostatistics and Epidemiology (Y.H., M.L.), Department of Genetics, Perelman School of Medicine (B.C., K.M., D.J.R.), and Cardiovascular Institute, Department of Medicine, Perelman School of Medicine (M.G., W.L., K.M.), University of Pennsylvania, Philadelphia; Irving Institute for Clinical and Translational Research (M.P.R.) and Division of Cardiology, Department of Medicine (C.X., H.Z., M.P.R.), Columbia University Medical Center, New York, NY; and Department of Mathematics and Statistics, Mount Holyoke College, South Hadley, MA (S.N., A.S.F.).
出版信息
Arterioscler Thromb Vasc Biol. 2016 Jul;36(7):1434-47. doi: 10.1161/ATVBAHA.116.307573. Epub 2016 May 26.
OBJECTIVE
Human macrophages can shift phenotype across the inflammatory M1 and reparative M2 spectrum in response to environmental challenges, but the mechanisms promoting inflammatory and cardiometabolic disease-associated M1 phenotypes remain incompletely understood. Alternative splicing (AS) is emerging as an important regulator of cellular function, yet its role in macrophage activation is largely unknown. We investigated the extent to which AS occurs in M1 activation within the cardiometabolic disease context and validated a functional genomic cell model for studying human macrophage-related AS events.
APPROACH AND RESULTS
From deep RNA-sequencing of resting, M1, and M2 primary human monocyte-derived macrophages, we found 3860 differentially expressed genes in M1 activation and detected 233 M1-induced AS events; the majority of AS events were cell- and M1-specific with enrichment for pathways relevant to macrophage inflammation. Using genetic variant data for 10 cardiometabolic traits, we identified 28 trait-associated variants within the genomic loci of 21 alternatively spliced genes and 15 variants within 7 differentially expressed regulatory splicing factors in M1 activation. Knockdown of 1 such splicing factor, CELF1, in primary human macrophages led to increased inflammatory response to M1 stimulation, demonstrating CELF1's potential modulation of the M1 phenotype. Finally, we demonstrated that an induced pluripotent stem cell-derived macrophage system recapitulates M1-associated AS events and provides a high-fidelity macrophage AS model.
CONCLUSIONS
AS plays a role in defining macrophage phenotype in a cell- and stimulus-specific fashion. Alternatively spliced genes and splicing factors with trait-associated variants may reveal novel pathways and targets in cardiometabolic diseases.
目的
人类巨噬细胞可根据环境挑战在炎症性M1和修复性M2表型之间转变,但促进炎症和心脏代谢疾病相关M1表型的机制仍未完全了解。可变剪接(AS)正成为细胞功能的重要调节因子,但其在巨噬细胞激活中的作用 largely unknown。我们研究了在心脏代谢疾病背景下M1激活中AS发生的程度,并验证了用于研究人类巨噬细胞相关AS事件的功能基因组细胞模型。
方法与结果
通过对静息、M1和M2原代人单核细胞衍生巨噬细胞进行深度RNA测序,我们在M1激活中发现了3860个差异表达基因,并检测到233个M1诱导的AS事件;大多数AS事件是细胞特异性和M1特异性的,富集了与巨噬细胞炎症相关的途径。利用10种心脏代谢性状的遗传变异数据,我们在21个可变剪接基因的基因组位点内鉴定出28个与性状相关的变异,以及在M1激活中7个差异表达的调节性剪接因子内的15个变异。在原代人巨噬细胞中敲低1种这样的剪接因子CELF1,导致对M1刺激的炎症反应增加,证明了CELF1对M1表型的潜在调节作用。最后,我们证明了诱导多能干细胞衍生的巨噬细胞系统概括了与M1相关的AS事件,并提供了一个高保真的巨噬细胞AS模型。
结论
AS以细胞和刺激特异性方式在定义巨噬细胞表型中发挥作用。具有与性状相关变异的可变剪接基因和剪接因子可能揭示心脏代谢疾病中的新途径和靶点。
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