Author
Listed:
- Pablo Cordero
(Stanford University
Stanford University)
- Victoria N. Parikh
(Stanford University)
- Elizabeth T. Chin
(Stanford University
Stanford University)
- Ayca Erbilgin
(Stanford University)
- Michael J. Gloudemans
(Stanford University
Stanford University)
- Ching Shang
(Stanford University)
- Yong Huang
(Stanford University)
- Alex C. Chang
(Stanford University)
- Kevin S. Smith
(Stanford University)
- Frederick Dewey
(Stanford University)
- Kathia Zaleta
(Stanford University)
- Michael Morley
(University of Pennsylvania)
- Jeff Brandimarto
(University of Pennsylvania)
- Nicole Glazer
(Boston University School of Medicine)
- Daryl Waggott
(Stanford University)
- Aleksandra Pavlovic
(Stanford University)
- Mingming Zhao
(Stanford University)
- Christine S. Moravec
(Lerner Research Institute)
- W. H. Wilson Tang
(Lerner Research Institute
Heart and Vascular Institute)
- Jamie Skreen
(Providence Medical Group—Milwaukie)
- Christine Malloy
(University of Maryland)
- Sridhar Hannenhalli
(University of Maryland)
- Hongzhe Li
(University of Pennsylvania)
- Scott Ritter
(University of Pennsylvania)
- Mingyao Li
(University of Pennsylvania)
- Daniel Bernstein
(Stanford University)
- Andrew Connolly
(University of California San Francisco)
- Hakon Hakonarson
(The Children’s Hospital of Philadelphia)
- Aldons J. Lusis
(University of California Los Angeles)
- Kenneth B. Margulies
(University of Pennsylvania
University of Pennsylvania
University of Pennsylvania)
- Anna A. Depaoli-Roach
(Indiana University)
- Stephen B. Montgomery
(Stanford University
Stanford University)
- Matthew T. Wheeler
(Stanford University
Stanford University)
- Thomas Cappola
(University of Pennsylvania
University of Pennsylvania
University of Pennsylvania)
- Euan A. Ashley
(Stanford University
Stanford University
Stanford University)
Abstract
Heart failure is a leading cause of mortality, yet our understanding of the genetic interactions underlying this disease remains incomplete. Here, we harvest 1352 healthy and failing human hearts directly from transplant center operating rooms, and obtain genome-wide genotyping and gene expression measurements for a subset of 313. We build failing and non-failing cardiac regulatory gene networks, revealing important regulators and cardiac expression quantitative trait loci (eQTLs). PPP1R3A emerges as a regulator whose network connectivity changes significantly between health and disease. RNA sequencing after PPP1R3A knockdown validates network-based predictions, and highlights metabolic pathway regulation associated with increased cardiomyocyte size and perturbed respiratory metabolism. Mice lacking PPP1R3A are protected against pressure-overload heart failure. We present a global gene interaction map of the human heart failure transition, identify previously unreported cardiac eQTLs, and demonstrate the discovery potential of disease-specific networks through the description of PPP1R3A as a central regulator in heart failure.
Suggested Citation
Pablo Cordero & Victoria N. Parikh & Elizabeth T. Chin & Ayca Erbilgin & Michael J. Gloudemans & Ching Shang & Yong Huang & Alex C. Chang & Kevin S. Smith & Frederick Dewey & Kathia Zaleta & Michael M, 2019.
"Pathologic gene network rewiring implicates PPP1R3A as a central regulator in pressure overload heart failure,"
Nature Communications, Nature, vol. 10(1), pages 1-14, December.
Handle:
RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-10591-5
DOI: 10.1038/s41467-019-10591-5
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