Author: Tang, Hao; Gao, Yuehan; Li, Zhaohuai; Miao, Yushan; Huang, Zhaohao; Liu, Xiuxing; Xie, Lihui; Li, He; Wen, Wen; Zheng, Yingfeng; Su, Wenru
Title: The noncoding and coding transcriptional landscape of the peripheral immune response in patients with COVIDâ€19 Cord-id: a8zeeran Document date: 2020_10_11
ID: a8zeeran
Snippet: BACKGROUND: COVIDâ€19 is currently a global pandemic, but the response of human immune system to severe acute respiratory syndrome coronavirus 2 (SARSâ€CoVâ€2) infection remains unclear. Noncoding RNAs serve as immune regulators and thus may play a critical role in disease progression. METHODS: We performed multiâ€transcriptome sequencing of both noncoding RNAs and mRNAs isolated from the red blood cell depleted whole blood of moderate and severe COVIDâ€19 patients. The functions of noncodi
Document: BACKGROUND: COVIDâ€19 is currently a global pandemic, but the response of human immune system to severe acute respiratory syndrome coronavirus 2 (SARSâ€CoVâ€2) infection remains unclear. Noncoding RNAs serve as immune regulators and thus may play a critical role in disease progression. METHODS: We performed multiâ€transcriptome sequencing of both noncoding RNAs and mRNAs isolated from the red blood cell depleted whole blood of moderate and severe COVIDâ€19 patients. The functions of noncoding RNAs were validated by analyses of the expression of downstream mRNAs. We further utilized the singleâ€cell RNAâ€seq data of COVIDâ€19 patients from Wilk et al. and Chua et al. to characterize noncoding RNA functions in different cell types. RESULTS: We defined four types of microRNAs with different expression tendencies that could serve as biomarkers for COVIDâ€19 progress. We also identified miRâ€146aâ€5p, miRâ€21â€5p, miRâ€142â€3p, and miRâ€15bâ€5p as potential contributors to the disease pathogenesis, possibly serving as biomarkers of severe COVIDâ€19 and as candidate therapeutic targets. In addition, the transcriptome profiles consistently suggested hyperactivation of the immune response, loss of Tâ€cell function, and immune dysregulation in severe patients. CONCLUSIONS: Collectively, these findings provide a comprehensive view of the noncoding and coding transcriptional landscape of peripheral immune cells during COVIDâ€19, furthering our understanding and offering novel insights into COVIDâ€19 pathogenesis.
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