1. Single Nucleus Multiomic Profiling Reveals Age-Dynamic Regulation of Host Genes Associated with SARS-CoV-2 Infection
- Author
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Wang, Allen, Chiou, Joshua, Poirion, Olivier B, Buchanan, Justin, Valdez, Michael J, Verheyden, Jamie M, Hou, Xiaomeng, Guo, Minzhe, Newsome, Jacklyn M, Kudtarkar, Parul, Faddah, Dina A, Zhang, Kai, Young, Randee E, Barr, Justinn, Misra, Ravi, Huyck, Heidie, Rogers, Lisa, Poole, Cory, Whitsett, Jeffery A., Pryhuber, Gloria, Xu, Yan, Gaulton, Kyle J, Preissl, Sebastian, and Sun, Xin
- Subjects
0303 health sciences ,Biology ,TMPRSS2 ,stat ,Chromatin ,03 medical and health sciences ,0302 clinical medicine ,medicine.anatomical_structure ,030228 respiratory system ,Respiratory failure ,Immunology ,medicine ,Respiratory system ,Gene ,Nucleus ,030304 developmental biology ,Epigenomics - Abstract
SUMMARYRespiratory failure is the leading cause of COVID-19 death and disproportionately impacts adults more than children. Here, we present a large-scale snATAC-seq dataset (90,980 nuclei) of the human lung, generated in parallel with snRNA-seq (46,500 nuclei), from healthy donors of ~30 weeks, ~3 years and ~30 years of age. Focusing on genes implicated in SARS-CoV-2 cell entry, we observed an increase in the proportion of alveolar epithelial cells expressingACE2andTMPRSS2in adult compared to young lungs. Consistent with expression dynamics, 10 chromatin peaks linked toTMPRSS2exhibited significantly increased activity with age and harbored IRF and STAT binding sites. Furthermore, we identified 14 common sequence variants in age-increasing peaks with predicted regulatory function, including several associated with respiratory traits andTMPRSS2expression. Our findings reveal a plausible contributor to why children are more resistant to COVID-19 and provide an epigenomic basis for transferring this resistance to older populations.
- Published
- 2020
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