Acetylation of muscle creatine kinase negatively impacts high-energy phosphotransfer in heart failure
Matthew A. Walker, Juan Chavez, Outi Villet, Xiaoting Tang, Andrew Keller, James E. Bruce, Rong Tian
Matthew A. Walker, Juan Chavez, Outi Villet, Xiaoting Tang, Andrew Keller, James E. Bruce, Rong Tian
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Research Article Cardiology

Acetylation of muscle creatine kinase negatively impacts high-energy phosphotransfer in heart failure

Abstract

A hallmark of impaired myocardial energetics in failing hearts is the downregulation of the creatine kinase (CK) system. In heart failure patients and animal models, myocardial phosphocreatine content and the flux of the CK reaction are negatively correlated with the outcome of heart failure. While decreased CK activity is highly reproducible in failing hearts, the underlying mechanisms remains elusive. Here, we report an inverse relationship between the activity and acetylation of CK muscle form (CKM) in human and mouse failing hearts. Hyperacetylation of recombinant CKM disrupted MM homodimer formation and reduced enzymatic activity, which could be reversed by sirtuin 2 treatment. Mass spectrometry analysis identified multiple lysine residues on the MM dimer interface, which were hyperacetylated in the failing hearts. Molecular modeling of CK MM homodimer suggested that hyperacetylation prevented dimer formation through interfering salt bridges within and between the 2 monomers. Deacetylation by sirtuin 2 reduced acetylation of the critical lysine residues, improved dimer formation, and restored CKM activity from failing heart tissue. These findings reveal a potentially novel mechanism in the regulation of CK activity and provide a potential target for improving high-energy phosphoryl transfer in heart failure.

Authors

Matthew A. Walker, Juan Chavez, Outi Villet, Xiaoting Tang, Andrew Keller, James E. Bruce, Rong Tian

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Figure 5

Acetylation of human recombinant CKM disrupts dimer formation.

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Acetylation of human recombinant CKM disrupts dimer formation. (A) Nonac...
(A) Nonacetylated and acetylated human rCKM was prepared under reducing and nonreducing conditions and run on native-PAGE prior to Western transfer and immunoblotting with anti-CKM antibodies. Representative immunoblot (left) to determine dimeric versus monomeric CKM. Statistical analysis (right) of densitomeric measurements of monomer and dimer CKM; n = 5 per group. (B) rCKM was incubated over a range of acetyl-CoA concentration (0–500 μM) prior to being run on native-PAGE. Dimeric versus monomeric CKM was determined; n = 5 per group. (C) Crosslinking mass spectrometry (XL-MS) revealed distance constraints between crosslinked lysine residues and obtained information on the structure of the rCKM dimer mapped to PDB 1U6R. XL-MS analysis of rCKM found the homodimer links K196-K196 and K11-K11 were heavily disrupted with acetylation of rCKM. Sirt2 deaceytlation restored the K196-K196 and K11-K11 homodimer crosslink back toward control (right). (D) MS analysis of in vitro acetylated rCKM compared with Sirt2 deacetylated rCKM. Data shown as mean ± SEM; n = 5 per group. P values calculated by 1-way ANOVA followed by Tukey post hoc analysis. *P < 0.05 versus nonacetylated rCKM dimer, #P < 0.05 versus nonacetylated Monomer rCKM (A and B).