puc-header

Skin Injury Activates TRPV1+ Nociceptive Fibers to Stimulate a Rapid Innate Antiviral Protein Response

42 Pages Posted: 29 Apr 2020 Publication Status: Review Complete

See all articles by Chelsea Handfield

Chelsea Handfield

Duke University - Department of Dermatology

Jeffery Kwock

Duke University - Department of Dermatology

Vivian Lei

Duke University - Department of Dermatology

Min Jin Lee

Duke University - Department of Dermatology

Margaret Coates

Duke University - Department of Dermatology

Kaiyuan Wang

Duke University

Qingjian Han

Duke University

Jennifer G. Powers

Duke University - Department of Dermatology

Sarah Wolfe

Duke University - Department of Dermatology

David L. Corcoran

Duke University - Center for Genomic and Computational Biology

Brian Fanelli

CosmosID, Inc.

Manoj Dadlani

CosmosID, Inc.

Ru-Rong Ji

Duke University - Sensory Plasticity and Pain Research Laboratory

Amanda S. MacLeod

Duke University - Department of Dermatology

More...

Abstract

The skin serves as the interface between the body and the environment and plays a fundamental role in innate antimicrobial host immunity.  Antiviral proteins are part of the innate host defense system and provide protection against viral pathogens.  How breach of the skin barrier influences innate antiviral protein production remains largely unknown.  Here, we identify and characterize the induction and regulation of antiviral proteins following skin injury.  Transcriptional and phenotypic profiling of cutaneous wounds revealed that skin injury induces high levels of antiviral proteins in both mice and humans, and interleukin (IL)-27 was found to be necessary and sufficient to induce this pattern of expression.  Notably, we here link the IL-27-mediated antiviral protein response to a neuro-immune axis.  We herein identify how damage to the skin barrier elicits cutaneous nociceptive signaling to activate innate antiviral immune responses.  Remarkably, pharmacology or genetic ablation of TRPV1-mediated nociception unveiled that TRPV1 signaling contributes significantly to the induction of antiviral proteins Oas2, Oasl2, and Isg15 via IL-27 in vivo, suggesting that nociception promotes skin antiviral competence through activation of antiviral signaling pathways upon wounding.

Keywords: skin immunity, wound, TRPV1, nociception, antiviral proteins, IL-27, innate immunity, keratinocytes, neuro-immune axis

Suggested Citation

Handfield, Chelsea and Kwock, Jeffery and Lei, Vivian and Lee, Min Jin and Coates, Margaret and Wang, Kaiyuan and Han, Qingjian and Powers, Jennifer G. and Wolfe, Sarah and Corcoran, David L. and Fanelli, Brian and Dadlani, Manoj and Ji, Ru-Rong and MacLeod, Amanda S., Skin Injury Activates TRPV1+ Nociceptive Fibers to Stimulate a Rapid Innate Antiviral Protein Response. Available at SSRN: https://ssrn.com/abstract=3581367 or http://dx.doi.org/10.2139/ssrn.3581367
This version of the paper has not been formally peer reviewed.

Chelsea Handfield

Duke University - Department of Dermatology ( email )

United States

Jeffery Kwock

Duke University - Department of Dermatology ( email )

United States

Vivian Lei

Duke University - Department of Dermatology

United States

Min Jin Lee

Duke University - Department of Dermatology

United States

Margaret Coates

Duke University - Department of Dermatology ( email )

United States

Kaiyuan Wang

Duke University

100 Fuqua Drive
Durham, NC 27708-0204
United States

Qingjian Han

Duke University ( email )

100 Fuqua Drive
Durham, NC 27708-0204
United States

Jennifer G. Powers

Duke University - Department of Dermatology

United States

Sarah Wolfe

Duke University - Department of Dermatology

United States

David L. Corcoran

Duke University - Center for Genomic and Computational Biology ( email )

Durham, NC 27710
United States

Brian Fanelli

CosmosID, Inc. ( email )

United States

Manoj Dadlani

CosmosID, Inc. ( email )

United States

Ru-Rong Ji

Duke University - Sensory Plasticity and Pain Research Laboratory ( email )

Durham, NC
United States

Amanda S. Macleod (Contact Author)

Duke University - Department of Dermatology ( email )

United States

Click here to go to Cell.com

Paper statistics

Downloads
128
Abstract Views
847
PlumX Metrics