Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.

Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.

Cardiomyocytes are vulnerable to hypoxia in the adult, but adapted to hypoxia in utero. Current understanding of endogenous cardiac oxygen sensing pathways is limited. Myocardial oxygen consumption is determined by regulation of energy metabolism, which shifts from glycolysis to lipid oxidation soon...

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Main Authors: Ross A Breckenridge, Izabela Piotrowska, Keat-Eng Ng, Timothy J Ragan, James A West, Surendra Kotecha, Norma Towers, Michael Bennett, Petra C Kienesberger, Ryszard T Smolenski, Hillary K Siddall, John L Offer, Mihaela M Mocanu, Derek M Yelon, Jason R B Dyck, Jules L Griffin, Andrey Y Abramov, Alex P Gould, Timothy J Mohun
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2013-09-01
Series:PLoS Biology
Online Access:http://europepmc.org/articles/PMC3782421?pdf=render
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spelling doaj-c94bc252bb4048fdb56691e64de2627d2021-07-02T05:23:40ZengPublic Library of Science (PLoS)PLoS Biology1544-91731545-78852013-09-01119e100166610.1371/journal.pbio.1001666Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.Ross A BreckenridgeIzabela PiotrowskaKeat-Eng NgTimothy J RaganJames A WestSurendra KotechaNorma TowersMichael BennettPetra C KienesbergerRyszard T SmolenskiHillary K SiddallJohn L OfferMihaela M MocanuDerek M YelonJason R B DyckJules L GriffinAndrey Y AbramovAlex P GouldTimothy J MohunCardiomyocytes are vulnerable to hypoxia in the adult, but adapted to hypoxia in utero. Current understanding of endogenous cardiac oxygen sensing pathways is limited. Myocardial oxygen consumption is determined by regulation of energy metabolism, which shifts from glycolysis to lipid oxidation soon after birth, and is reversed in failing adult hearts, accompanying re-expression of several "fetal" genes whose role in disease phenotypes remains unknown. Here we show that hypoxia-controlled expression of the transcription factor Hand1 determines oxygen consumption by inhibition of lipid metabolism in the fetal and adult cardiomyocyte, leading to downregulation of mitochondrial energy generation. Hand1 is under direct transcriptional control by HIF1α. Transgenic mice prolonging cardiac Hand1 expression die immediately following birth, failing to activate the neonatal lipid metabolising gene expression programme. Deletion of Hand1 in embryonic cardiomyocytes results in premature expression of these genes. Using metabolic flux analysis, we show that Hand1 expression controls cardiomyocyte oxygen consumption by direct transcriptional repression of lipid metabolising genes. This leads, in turn, to increased production of lactate from glucose, decreased lipid oxidation, reduced inner mitochondrial membrane potential, and mitochondrial ATP generation. We found that this pathway is active in adult cardiomyocytes. Up-regulation of Hand1 is protective in a mouse model of myocardial ischaemia. We propose that Hand1 is part of a novel regulatory pathway linking cardiac oxygen levels with oxygen consumption. Understanding hypoxia adaptation in the fetal heart may allow development of strategies to protect cardiomyocytes vulnerable to ischaemia, for example during cardiac ischaemia or surgery.http://europepmc.org/articles/PMC3782421?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Ross A Breckenridge
Izabela Piotrowska
Keat-Eng Ng
Timothy J Ragan
James A West
Surendra Kotecha
Norma Towers
Michael Bennett
Petra C Kienesberger
Ryszard T Smolenski
Hillary K Siddall
John L Offer
Mihaela M Mocanu
Derek M Yelon
Jason R B Dyck
Jules L Griffin
Andrey Y Abramov
Alex P Gould
Timothy J Mohun
spellingShingle Ross A Breckenridge
Izabela Piotrowska
Keat-Eng Ng
Timothy J Ragan
James A West
Surendra Kotecha
Norma Towers
Michael Bennett
Petra C Kienesberger
Ryszard T Smolenski
Hillary K Siddall
John L Offer
Mihaela M Mocanu
Derek M Yelon
Jason R B Dyck
Jules L Griffin
Andrey Y Abramov
Alex P Gould
Timothy J Mohun
Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.
PLoS Biology
author_facet Ross A Breckenridge
Izabela Piotrowska
Keat-Eng Ng
Timothy J Ragan
James A West
Surendra Kotecha
Norma Towers
Michael Bennett
Petra C Kienesberger
Ryszard T Smolenski
Hillary K Siddall
John L Offer
Mihaela M Mocanu
Derek M Yelon
Jason R B Dyck
Jules L Griffin
Andrey Y Abramov
Alex P Gould
Timothy J Mohun
author_sort Ross A Breckenridge
title Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.
title_short Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.
title_full Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.
title_fullStr Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.
title_full_unstemmed Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.
title_sort hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism.
publisher Public Library of Science (PLoS)
series PLoS Biology
issn 1544-9173
1545-7885
publishDate 2013-09-01
description Cardiomyocytes are vulnerable to hypoxia in the adult, but adapted to hypoxia in utero. Current understanding of endogenous cardiac oxygen sensing pathways is limited. Myocardial oxygen consumption is determined by regulation of energy metabolism, which shifts from glycolysis to lipid oxidation soon after birth, and is reversed in failing adult hearts, accompanying re-expression of several "fetal" genes whose role in disease phenotypes remains unknown. Here we show that hypoxia-controlled expression of the transcription factor Hand1 determines oxygen consumption by inhibition of lipid metabolism in the fetal and adult cardiomyocyte, leading to downregulation of mitochondrial energy generation. Hand1 is under direct transcriptional control by HIF1α. Transgenic mice prolonging cardiac Hand1 expression die immediately following birth, failing to activate the neonatal lipid metabolising gene expression programme. Deletion of Hand1 in embryonic cardiomyocytes results in premature expression of these genes. Using metabolic flux analysis, we show that Hand1 expression controls cardiomyocyte oxygen consumption by direct transcriptional repression of lipid metabolising genes. This leads, in turn, to increased production of lactate from glucose, decreased lipid oxidation, reduced inner mitochondrial membrane potential, and mitochondrial ATP generation. We found that this pathway is active in adult cardiomyocytes. Up-regulation of Hand1 is protective in a mouse model of myocardial ischaemia. We propose that Hand1 is part of a novel regulatory pathway linking cardiac oxygen levels with oxygen consumption. Understanding hypoxia adaptation in the fetal heart may allow development of strategies to protect cardiomyocytes vulnerable to ischaemia, for example during cardiac ischaemia or surgery.
url http://europepmc.org/articles/PMC3782421?pdf=render
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