Estrogen-Related Receptor α (ERRα) and ERRγ Are Essential Coordinators of Cardiac Metabolism and Function

Wang, Ting; McDonald, Caitlin; Petrenko, Nataliya; Leblanc, Mathias; Wang, Tao; Giguère, Vincent; Evans, Ronald M.; Patel, Vickas V.; Pei, Liming

doi:10.1128/mcb.01156-14

Cited by 103 publications

(109 citation statements)

References 71 publications

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“…ERRγ is also necessary for normal cardiac function, as genetic deletion results in perinatal lethality with a failure to transition to oxidative metabolism in heart (51). Finally, postnatal and cardiac-specific deletion of Esrrg on an Esrra-null background results in a lethal cardiomyopathy characterized by abnormalities in mitochondrial structure and function and reduced energy production capacity (52). These results underscore the central role of ERRs in the broad control of cardiac mitochondrial function and also highlight the functional overlap and redundancy of ERRα and -γ in the mammalian heart.…”

Section: Brief Overview Of Cardiac Fuel and Energy Metabolismmentioning

confidence: 72%

Cardiac nuclear receptors: architects of mitochondrial structure and function

Vega¹,

Kelly²

2017

Journal of Clinical Investigation

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The adult mammalian heart has immense energy demands in order to support its role as a constantly active pump. Indeed, the human heart generates and utilizes kilogram quantities of ATP each day. The vast majority of ATP produced in the cardiac myocyte is generated via oxidative phosphorylation (OXPHOS) within a very-high-capacity mitochondrial system. The heart must continually adapt to changing physiologic conditions that influence workload, as well as alterations in oxygen and energy substrate availability. Notably, given that the heart has a limited capacity for fuel storage, it must utilize several energy substrates in an efficient and dynamic manner. As will be described, members of the nuclear receptor transcription factor superfamily serve to dynamically control preference and capacity for cardiac mitochondrial fuel metabolism during development and in response to myriad physiologic conditions. In addition, alterations in nuclear receptor signaling occur with pathologic cardiac growth and remodeling en route to heart failure.The adult cardiac myocyte has a higher density of mitochondria than any other cell type (1). The biogenesis of this highcapacity mitochondrial system occurs largely during the perinatal stage of development. This process involves a major burst of mitochondrial biogenesis at birth, followed by a period of mitochondrial maturation and remodeling during the postnatal period (2). Recent evidence indicates that postnatal mitochondrial maturation involves highly coordinated events including mitophagy, biogenesis, and dynamics (fusion and fission), resulting in a mitochondria network that is densely packed between sarcomeres to directly supply ATP to support cardiac contraction (2). The adult cardiac mitochondria are equipped with enzymatic machinery capable of oxidizing multiple substrates including fatty acids (the chief fuel) as well as glucose (pyruvate) and ketone bodies. This mitochondrial developmental maturation process occurs in parallel with well-characterized changes in the expression of contractile apparatus isoforms, ion channels, and calcium handling proteins. The collective perinatal programming in energy metabolic and structural genes results in an efficient and enduring pump for the adult life of the organism.The postnatal heart has an amazing capacity to oxidize multiple fuels and, therefore, is "omnivorous." Pioneering work by multiple groups has defined dynamic shifts in fuel utilization capacity and preferences during development and in disease states. The fetal and immediate postnatal heart relies primarily on glucose (glycolysis) and lactate as energy sources (3-5). However, very soon after birth the heart shifts to fatty acids as the major fuel substrate, coincident with the mitochondrial biogenic response (Figure 1 and refs. 5-8). The level of glucose oxidation also increases (8). The postnatal heart is also capable of oxidizing ketones, albeit at a low level, concomitant with the postnatal rise in circulating ketones (5). The shifts in fuel preference after birth ar...

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Section: Brief Overview Of Cardiac Fuel and Energy Metabolismmentioning

confidence: 72%

Cardiac nuclear receptors: architects of mitochondrial structure and function

Vega¹,

Kelly²

2017

Journal of Clinical Investigation

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“…Ppars have long been known to induce metabolic genes that function within mitochondria. Esrrs contribute to the expression of nuclear encoded mitochondrial gene expression and have been found to be functionally relevant in the postnatal mitochondrial biogenesis in the heart (8,38). The Errα-binding motif TGACCTY was highly enriched in downregulated gene promoters, while motifs for Tcf3 and Lef1, among others, were enriched in both upregulated and downregulated promoters ( Figure 8B and Supplemental Tables 7 and 8).…”

Section: Resultsmentioning

confidence: 96%

“…Errs have broader target specificity, as Errα and Errγ share promoter-binding motifs that are present in energy uptake and utilization, Ca 2+ handling, and contractile genes (6). Cardiac ablation of the genes encoding Errα, Errγ, and Pgc1 lead to cardiac dysfunction, particularly under pathological stress (7)(8)(9). MAPKs respond to growth factors (i.e., extracellular-regulated kinases Erk1 and Erk2), stresses (p38), or both (Erk5) (10) and regulate gene Widespread changes in cardiac gene expression occur during heart failure, yet the mechanisms responsible for coordinating these changes remain poorly understood.…”

Section: Introductionmentioning

confidence: 99%

Ectopic expression of Cdk8 induces eccentric hypertrophy and heart failure

et al. 2017

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“…Physiological studies validated the importance of the ERRs in regulating energy balance in vivo: experiments in ERRa-null mice demonstrated that ERRa is required to generate energy required to respond to physiological and pathological stresses in various tissues, but is not essential for basal cellular energy needs [35][36][37][38][39][40]. Conversely, ERRg is necessary to direct and maintain the metabolic switch in the fetal heart at birth from an energy dependence on primarily carbohydrates during development to fatty acid oxidation in the postnatal heart [41,42]. Meanwhile, the development of functional genomics technologies were pivotal in understanding the consequences of ERR transcriptional activity.…”

Section: Errs As Master Regulators Of Cellular Metabolismmentioning

confidence: 92%