Distinct Stress‐Dependent Signatures of Cellular and Extracellular tRNA‐Derived Small RNAs

Guoping Li; Aidan C. Manning; Alex Bagi; Xinyu Yang; Priyanka Gokulnath; Michail Spanos; Jonathan Howard; Patricia P. Chan; Thadryan Sweeney; Robert Kitchen; Haobo Li; Brice D. Laurent; Sary F. Aranki; Maria I. Kontaridis; Louise C. Laurent; Kendall Van Keuren‐Jensen; Jochen Muehlschlegel; Todd M. Lowe; Saumya Das

doi:10.1002/advs.202200829

Advanced Science (Jun 2022)

Distinct Stress‐Dependent Signatures of Cellular and Extracellular tRNA‐Derived Small RNAs

Guoping Li,
Aidan C. Manning,
Alex Bagi,
Xinyu Yang,
Priyanka Gokulnath,
Michail Spanos,
Jonathan Howard,
Patricia P. Chan,
Thadryan Sweeney,
Robert Kitchen,
Haobo Li,
Brice D. Laurent,
Sary F. Aranki,
Maria I. Kontaridis,
Louise C. Laurent,
Kendall Van Keuren‐Jensen,
Jochen Muehlschlegel,
Todd M. Lowe,
Saumya Das

Affiliations

Guoping Li: Cardiovascular Research Center Massachusetts General Hospital and Harvard Medical School Boston MA 02114 USA
Aidan C. Manning: Department of Biomolecular Engineering Baskin School of Engineering University of California Santa Cruz Santa Cruz CA 95064 USA
Alex Bagi: Department of Biomolecular Engineering Baskin School of Engineering University of California Santa Cruz Santa Cruz CA 95064 USA
Xinyu Yang: Fangshan Hospital of Beijing University of Traditional Chinese Medicine Beijing 102499 China
Priyanka Gokulnath: Cardiovascular Research Center Massachusetts General Hospital and Harvard Medical School Boston MA 02114 USA
Michail Spanos: Cardiovascular Research Center Massachusetts General Hospital and Harvard Medical School Boston MA 02114 USA
Jonathan Howard: Department of Biomolecular Engineering Baskin School of Engineering University of California Santa Cruz Santa Cruz CA 95064 USA
Patricia P. Chan: Department of Biomolecular Engineering Baskin School of Engineering University of California Santa Cruz Santa Cruz CA 95064 USA
Thadryan Sweeney: Cardiovascular Research Center Massachusetts General Hospital and Harvard Medical School Boston MA 02114 USA
Robert Kitchen: Cardiovascular Research Center Massachusetts General Hospital and Harvard Medical School Boston MA 02114 USA
Haobo Li: Cardiovascular Research Center Massachusetts General Hospital and Harvard Medical School Boston MA 02114 USA
Brice D. Laurent: Cardiovascular Research Center Massachusetts General Hospital and Harvard Medical School Boston MA 02114 USA
Sary F. Aranki: Division of Cardiac Surgery Department of Surgery Brigham and Women's Hospital Harvard Medical School Boston MA 02115 USA
Maria I. Kontaridis: Department of Biomedical Research and Translational Medicine Masonic Medical Research Institute Utica NY 13501 USA
Louise C. Laurent: Department of Obstetrics, Gynecology, and Reproductive Sciences University of California San Diego La Jolla CA 92093 USA
Kendall Van Keuren‐Jensen: Division of Neurogenomics The Translational Genomics Research Institute Phoenix AZ 85004 USA
Jochen Muehlschlegel: Department of Anesthesiology, Perioperative and Pain Medicine Brigham and Women's Hospital and Harvard Medical School Boston MA 02115 USA
Todd M. Lowe: Department of Biomolecular Engineering Baskin School of Engineering University of California Santa Cruz Santa Cruz CA 95064 USA
Saumya Das: Cardiovascular Research Center Massachusetts General Hospital and Harvard Medical School Boston MA 02114 USA

DOI: https://doi.org/10.1002/advs.202200829
Journal volume & issue: Vol. 9, no. 17
pp. n/a – n/a

Abstract

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Abstract The cellular response to stress is an important determinant of disease pathogenesis. Uncovering the molecular fingerprints of distinct stress responses may identify novel biomarkers and key signaling pathways for different diseases. Emerging evidence shows that transfer RNA‐derived small RNAs (tDRs) play pivotal roles in stress responses. However, RNA modifications present on tDRs are barriers to accurately quantifying tDRs using traditional small RNA sequencing. Here, AlkB‐facilitated methylation sequencing is used to generate a comprehensive landscape of cellular and extracellular tDR abundances in various cell types during different stress responses. Extracellular tDRs are found to have distinct fragmentation signatures from intracellular tDRs and these tDR signatures are better indicators of different stress responses than miRNAs. These distinct extracellular tDR fragmentation patterns and signatures are also observed in plasma from patients on cardiopulmonary bypass. It is additionally demonstrated that angiogenin and RNASE1 are themselves regulated by stressors and contribute to the stress‐modulated abundance of sub‐populations of cellular and extracellular tDRs. Finally, a sub‐population of extracellular tDRs is identified for which AGO2 appears to be required for their expression. Together, these findings provide a detailed profile of stress‐responsive tDRs and provide insight about tDR biogenesis and stability in response to cellular stressors.

Published in Advanced Science

ISSN: 2198-3844 (Online)
Publisher: Wiley
Country of publisher: Germany
LCC subjects: Science
Website: https://onlinelibrary.wiley.com/journal/21983844

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