Michael T Davidson1,2, Paul A Grimsrud1, Ling Lai3, James A Draper1, Kelsey H Fisher-Wellman1, Tara M Narowski1, Dennis M Abraham4, Timothy R Koves1, Daniel P Kelly3, Deborah M Muoio1,5,2. 1. From the Duke Molecular Physiology Institute and Sarah W. Stedman Nutrition and Metabolism Center (M.T.D., P.A.G., J.A.D., K.H.F.-W., T.M.N., T.R.K., D.M.M.), Duke University Medical Center, Durham, NC. 2. Department of Pharmacology and Cancer Biology, Duke University Medical Center (M.T.D., D.M.M.). 3. Cardiovascular Institute and Department of Medicine, Perelman School of Medicine at the University of Pennsylvania, PA (L.L., D.P.K.). 4. Department of Medicine, Division of Cardiology and Duke Cardiovascular Physiology Core (D.M.A.). 5. Department of Medicine, Division of Endocrinology, Metabolism, and Nutrition (D.M.M.), Duke University Medical Center, Durham, NC.
Abstract
RATIONALE: Circumstantial evidence links the development of heart failure to posttranslational modifications of mitochondrial proteins, including lysine acetylation (Kac). Nonetheless, direct evidence that Kac compromises mitochondrial performance remains sparse. OBJECTIVE: This study sought to explore the premise that mitochondrial Kac contributes to heart failure by disrupting oxidative metabolism. METHODS AND RESULTS: A DKO (dual knockout) mouse line with deficiencies in CrAT (carnitine acetyltransferase) and Sirt3 (sirtuin 3)-enzymes that oppose Kac by buffering the acetyl group pool and catalyzing lysine deacetylation, respectively-was developed to model extreme mitochondrial Kac in cardiac muscle, as confirmed by quantitative acetyl-proteomics. The resulting impact on mitochondrial bioenergetics was evaluated using a respiratory diagnostics platform that permits comprehensive assessment of mitochondrial function and energy transduction. Susceptibility of DKO mice to heart failure was investigated using transaortic constriction as a model of cardiac pressure overload. The mitochondrial acetyl-lysine landscape of DKO hearts was elevated well beyond that observed in response to pressure overload or Sirt3 deficiency alone. Relative changes in the abundance of specific acetylated lysine peptides measured in DKO versus Sirt3 KO hearts were strongly correlated. A proteomics comparison across multiple settings of hyperacetylation revealed ≈86% overlap between the populations of Kac peptides affected by the DKO manipulation as compared with experimental heart failure. Despite the severity of cardiac Kac in DKO mice relative to other conditions, deep phenotyping of mitochondrial function revealed a surprisingly normal bioenergetics profile. Thus, of the >120 mitochondrial energy fluxes evaluated, including substrate-specific dehydrogenase activities, respiratory responses, redox charge, mitochondrial membrane potential, and electron leak, we found minimal evidence of oxidative insufficiencies. Similarly, DKO hearts were not more vulnerable to dysfunction caused by transaortic constriction-induced pressure overload. CONCLUSIONS: The findings challenge the premise that hyperacetylation per se threatens metabolic resilience in the myocardium by causing broad-ranging disruption to mitochondrial oxidative machinery.
RATIONALE: Circumstantial evidence links the development of heart failure to posttranslational modifications of mitochondrial proteins, including lysine acetylation (Kac). Nonetheless, direct evidence that Kac compromises mitochondrial performance remains sparse. OBJECTIVE: This study sought to explore the premise that mitochondrial Kac contributes to heart failure by disrupting oxidative metabolism. METHODS AND RESULTS: A DKO (dual knockout) mouse line with deficiencies in CrAT (carnitine acetyltransferase) and Sirt3 (sirtuin 3)-enzymes that oppose Kac by buffering the acetyl group pool and catalyzing lysine deacetylation, respectively-was developed to model extreme mitochondrial Kac in cardiac muscle, as confirmed by quantitative acetyl-proteomics. The resulting impact on mitochondrial bioenergetics was evaluated using a respiratory diagnostics platform that permits comprehensive assessment of mitochondrial function and energy transduction. Susceptibility of DKO mice to heart failure was investigated using transaortic constriction as a model of cardiac pressure overload. The mitochondrial acetyl-lysine landscape of DKO hearts was elevated well beyond that observed in response to pressure overload or Sirt3 deficiency alone. Relative changes in the abundance of specific acetylated lysine peptides measured in DKO versus Sirt3 KO hearts were strongly correlated. A proteomics comparison across multiple settings of hyperacetylation revealed ≈86% overlap between the populations of Kac peptides affected by the DKO manipulation as compared with experimental heart failure. Despite the severity of cardiac Kac in DKO mice relative to other conditions, deep phenotyping of mitochondrial function revealed a surprisingly normal bioenergetics profile. Thus, of the >120 mitochondrial energy fluxes evaluated, including substrate-specific dehydrogenase activities, respiratory responses, redox charge, mitochondrial membrane potential, and electron leak, we found minimal evidence of oxidative insufficiencies. Similarly, DKO hearts were not more vulnerable to dysfunction caused by transaortic constriction-induced pressure overload. CONCLUSIONS: The findings challenge the premise that hyperacetylation per se threatens metabolic resilience in the myocardium by causing broad-ranging disruption to mitochondrial oxidative machinery.
Entities:
Keywords:
energy metabolism; heart; heart failure; mitochondria; proteomics
Authors: Thomas Taus; Thomas Köcher; Peter Pichler; Carmen Paschke; Andreas Schmidt; Christoph Henrich; Karl Mechtler Journal: J Proteome Res Date: 2011-11-10 Impact factor: 4.466
Authors: Ling Lai; Teresa C Leone; Mark P Keller; Ola J Martin; Aimee T Broman; Jessica Nigro; Kapil Kapoor; Timothy R Koves; Robert Stevens; Olga R Ilkayeva; Rick B Vega; Alan D Attie; Deborah M Muoio; Daniel P Kelly Journal: Circ Heart Fail Date: 2014-09-18 Impact factor: 8.790
Authors: H A Rockman; R S Ross; A N Harris; K U Knowlton; M E Steinhelper; L J Field; J Ross; K R Chien Journal: Proc Natl Acad Sci U S A Date: 1991-09-15 Impact factor: 11.205
Authors: Xiaokan Zhang; Ruiping Ji; Xianghai Liao; Estibaliz Castillero; Peter J Kennel; Danielle L Brunjes; Marcus Franz; Sven Möbius-Winkler; Konstantinos Drosatos; Isaac George; Emily I Chen; Paolo C Colombo; P Christian Schulze Journal: Circulation Date: 2018-01-12 Impact factor: 29.690
Authors: Timothy N Audam; Caitlin M Howard; Lauren F Garrett; Yi Wei Zheng; James A Bradley; Kenneth R Brittian; Matthew W Frank; Kyle L Fulghum; Miklós Pólos; Szilvia Herczeg; Béla Merkely; Tamás Radovits; Shizuka Uchida; Bradford G Hill; Sujith Dassanayaka; Suzanne Jackowski; Steven P Jones Journal: Am J Physiol Heart Circ Physiol Date: 2021-09-17 Impact factor: 5.125
Authors: Mateusz M Tomczyk; Kyle G Cheung; Bo Xiang; Nahid Tamanna; Ana L Fonseca Teixeira; Prasoon Agarwal; Stephanie M Kereliuk; Victor Spicer; Ligen Lin; Jason Treberg; Qiang Tong; Vernon W Dolinsky Journal: Circ Heart Fail Date: 2022-04-14 Impact factor: 10.447
Authors: Dan Tong; Gabriele G Schiattarella; Nan Jiang; Francisco Altamirano; Pamela A Szweda; Abdallah Elnwasany; Dong I Lee; Heesoo Yoo; David A Kass; Luke I Szweda; Sergio Lavandero; Eric Verdin; Thomas G Gillette; Joseph A Hill Journal: Circ Res Date: 2021-04-22 Impact factor: 23.213
Authors: Jessica N Peoples; Nasab Ghazal; Duc M Duong; Katherine R Hardin; Janet R Manning; Nicholas T Seyfried; Victor Faundez; Jennifer Q Kwong Journal: Am J Physiol Cell Physiol Date: 2021-07-28 Impact factor: 5.282