Exuberant fibroblast activity compromises lung function via ADAMTS4

PALISI Pediatric Intensive Care Influenza (PICFLU) Investigators

doi:10.1038/s41586-020-2877-5

Exuberant fibroblast activity compromises lung function via ADAMTS4

PALISI Pediatric Intensive Care Influenza (PICFLU) Investigators

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Severe respiratory infections can result in acute respiratory distress syndrome (ARDS)¹. There are no effective pharmacological therapies that have been shown to improve outcomes for patients with ARDS. Although the host inflammatory response limits spread of and eventually clears the pathogen, immunopathology is a major contributor to tissue damage and ARDS^1,2. Here we demonstrate that respiratory viral infection induces distinct fibroblast activation states, which we term extracellular matrix (ECM)-synthesizing, damage-responsive and interferon-responsive states. We provide evidence that excess activity of damage-responsive lung fibroblasts drives lethal immunopathology during severe influenza virus infection. By producing ECM-remodelling enzymes—in particular the ECM protease ADAMTS4—and inflammatory cytokines, damage-responsive fibroblasts modify the lung microenvironment to promote robust immune cell infiltration at the expense of lung function. In three cohorts of human participants, the levels of ADAMTS4 in the lower respiratory tract were associated with the severity of infection with seasonal or avian influenza virus. A therapeutic agent that targets the ECM protease activity of damage-responsive lung fibroblasts could provide a promising approach to preserving lung function and improving clinical outcomes following severe respiratory infections.

Original language	English (US)
Pages (from-to)	466-471
Number of pages	6
Journal	Nature
Volume	587
Issue number	7834
DOIs	https://doi.org/10.1038/s41586-020-2877-5
State	Published - Nov 19 2020

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@article{0c3fbc9d09f94cc08e3832c155b9be7d,

title = "Exuberant fibroblast activity compromises lung function via ADAMTS4",

abstract = "Severe respiratory infections can result in acute respiratory distress syndrome (ARDS)1. There are no effective pharmacological therapies that have been shown to improve outcomes for patients with ARDS. Although the host inflammatory response limits spread of and eventually clears the pathogen, immunopathology is a major contributor to tissue damage and ARDS1,2. Here we demonstrate that respiratory viral infection induces distinct fibroblast activation states, which we term extracellular matrix (ECM)-synthesizing, damage-responsive and interferon-responsive states. We provide evidence that excess activity of damage-responsive lung fibroblasts drives lethal immunopathology during severe influenza virus infection. By producing ECM-remodelling enzymes—in particular the ECM protease ADAMTS4—and inflammatory cytokines, damage-responsive fibroblasts modify the lung microenvironment to promote robust immune cell infiltration at the expense of lung function. In three cohorts of human participants, the levels of ADAMTS4 in the lower respiratory tract were associated with the severity of infection with seasonal or avian influenza virus. A therapeutic agent that targets the ECM protease activity of damage-responsive lung fibroblasts could provide a promising approach to preserving lung function and improving clinical outcomes following severe respiratory infections.",

author = "{PALISI Pediatric Intensive Care Influenza (PICFLU) Investigators} and Boyd, {David F.} and Allen, {E. Kaitlynn} and Randolph, {Adrienne G.} and Guo, {Xi zhi J.} and Yunceng Weng and Sanders, {Catherine J.} and Resha Bajracharya and Lee, {Natalie K.} and Guy, {Clifford S.} and Peter Vogel and Wenda Guan and Yimin Li and Xiaoqing Liu and Tanya Novak and Newhams, {Margaret M.} and Fabrizio, {Thomas P.} and Nicholas Wohlgemuth and Mourani, {Peter M.} and Michele Kong and Sanders, {Ronald C.} and Katherine Irby and Katri Typpo and Barry Markovitz and Natalie Cvijanovich and Heidi Flori and Adam Schwarz and Nick Anas and Peter Mourani and Angela Czaja and Gwenn McLaughlin and Matthew Paden and Keiko Tarquinio and Coates, {Bria M.} and Neethi Pinto and Wardenburg, {Juliane Bubeck} and Agan, {Anna A.} and Tanya Novak and Newhams, {Margaret M.} and Kurachek, {Stephen C.} and Hartman, {Mary E.} and Allan Doctor and Truemper, {Edward J.} and Sidharth Mahapatra and Ackerman, {Kate G.} and Daugherty, {L. Eugene} and Hall, {Mark W.} and Neal Thomas and Kathryn Shaw-Saliba and Andrew Pekosz and Rothman, {Richard E.}",

note = "Publisher Copyright: {\textcopyright} 2020, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2020",

month = nov,

day = "19",

doi = "10.1038/s41586-020-2877-5",

language = "English (US)",

volume = "587",

pages = "466--471",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Publishing Group",

number = "7834",

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TY - JOUR

T1 - Exuberant fibroblast activity compromises lung function via ADAMTS4

AU - PALISI Pediatric Intensive Care Influenza (PICFLU) Investigators

AU - Boyd, David F.

AU - Allen, E. Kaitlynn

AU - Randolph, Adrienne G.

AU - Guo, Xi zhi J.

AU - Weng, Yunceng

AU - Sanders, Catherine J.

AU - Bajracharya, Resha

AU - Lee, Natalie K.

AU - Guy, Clifford S.

AU - Vogel, Peter

AU - Guan, Wenda

AU - Li, Yimin

AU - Liu, Xiaoqing

AU - Novak, Tanya

AU - Newhams, Margaret M.

AU - Fabrizio, Thomas P.

AU - Wohlgemuth, Nicholas

AU - Mourani, Peter M.

AU - Kong, Michele

AU - Sanders, Ronald C.

AU - Irby, Katherine

AU - Typpo, Katri

AU - Markovitz, Barry

AU - Cvijanovich, Natalie

AU - Flori, Heidi

AU - Schwarz, Adam

AU - Anas, Nick

AU - Mourani, Peter

AU - Czaja, Angela

AU - McLaughlin, Gwenn

AU - Paden, Matthew

AU - Tarquinio, Keiko

AU - Coates, Bria M.

AU - Pinto, Neethi

AU - Wardenburg, Juliane Bubeck

AU - Agan, Anna A.

AU - Novak, Tanya

AU - Newhams, Margaret M.

AU - Kurachek, Stephen C.

AU - Hartman, Mary E.

AU - Doctor, Allan

AU - Truemper, Edward J.

AU - Mahapatra, Sidharth

AU - Ackerman, Kate G.

AU - Daugherty, L. Eugene

AU - Hall, Mark W.

AU - Thomas, Neal

AU - Shaw-Saliba, Kathryn

AU - Pekosz, Andrew

AU - Rothman, Richard E.

PY - 2020/11/19

Y1 - 2020/11/19

N2 - Severe respiratory infections can result in acute respiratory distress syndrome (ARDS)1. There are no effective pharmacological therapies that have been shown to improve outcomes for patients with ARDS. Although the host inflammatory response limits spread of and eventually clears the pathogen, immunopathology is a major contributor to tissue damage and ARDS1,2. Here we demonstrate that respiratory viral infection induces distinct fibroblast activation states, which we term extracellular matrix (ECM)-synthesizing, damage-responsive and interferon-responsive states. We provide evidence that excess activity of damage-responsive lung fibroblasts drives lethal immunopathology during severe influenza virus infection. By producing ECM-remodelling enzymes—in particular the ECM protease ADAMTS4—and inflammatory cytokines, damage-responsive fibroblasts modify the lung microenvironment to promote robust immune cell infiltration at the expense of lung function. In three cohorts of human participants, the levels of ADAMTS4 in the lower respiratory tract were associated with the severity of infection with seasonal or avian influenza virus. A therapeutic agent that targets the ECM protease activity of damage-responsive lung fibroblasts could provide a promising approach to preserving lung function and improving clinical outcomes following severe respiratory infections.

AB - Severe respiratory infections can result in acute respiratory distress syndrome (ARDS)1. There are no effective pharmacological therapies that have been shown to improve outcomes for patients with ARDS. Although the host inflammatory response limits spread of and eventually clears the pathogen, immunopathology is a major contributor to tissue damage and ARDS1,2. Here we demonstrate that respiratory viral infection induces distinct fibroblast activation states, which we term extracellular matrix (ECM)-synthesizing, damage-responsive and interferon-responsive states. We provide evidence that excess activity of damage-responsive lung fibroblasts drives lethal immunopathology during severe influenza virus infection. By producing ECM-remodelling enzymes—in particular the ECM protease ADAMTS4—and inflammatory cytokines, damage-responsive fibroblasts modify the lung microenvironment to promote robust immune cell infiltration at the expense of lung function. In three cohorts of human participants, the levels of ADAMTS4 in the lower respiratory tract were associated with the severity of infection with seasonal or avian influenza virus. A therapeutic agent that targets the ECM protease activity of damage-responsive lung fibroblasts could provide a promising approach to preserving lung function and improving clinical outcomes following severe respiratory infections.

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U2 - 10.1038/s41586-020-2877-5

DO - 10.1038/s41586-020-2877-5

M3 - Article

C2 - 33116313

AN - SCOPUS:85094679147

SN - 0028-0836

VL - 587

SP - 466

EP - 471

JO - Nature

JF - Nature

IS - 7834

ER -

Exuberant fibroblast activity compromises lung function via ADAMTS4

Abstract

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