BACKGROUND: Epsilon-protein kinase C (εPKC) protects the heart from ischemic injury. However, the mechanism(s) of εPKC cardioprotection is still unclear. Identification of the εPKC targets may aid in elucidating the εPKC-mediated cardioprotective mechanisms. Previous studies, using εPKC transgenic mice and difference in gel electrophoresis, identified proteins involved in glucose metabolism, the expression of which was modified by εPKC. Those studies were accompanied by metabolomic analysis, suggesting that increased glucose oxidation may be responsible for the cardioprotective effect of εPKC. Whether these εPKC-mediated alterations were because of differences in protein expression or phosphorylation was not determined. METHODS AND RESULTS: In the present study, we used an εPKC -specific activator peptide, ψεRACK, combined with phosphoproteomics, to find εPKC targets, and identified that the proteins whose phosphorylation was altered by selective activation of εPKC were mostly mitochondrial proteins. Analysis of the mitochondrial phosphoproteome led to the identification of 55 spots, corresponding to 37 individual proteins, exclusively phosphorylated, in the presence of ψεRACK. The majority of the proteins identified were involved in glucose and lipid metabolism, components of the respiratory chain as well as mitochondrial heat shock proteins. CONCLUSIONS: The protective effect of εPKC during ischemia involves phosphorylation of several mitochondrial proteins involved in glucose and lipid metabolism and oxidative phosphorylation. Regulation of these metabolic pathways by εPKC phosphorylation may lead to εPKC-mediated cardioprotection induced by ψεRACK.
BACKGROUND: Epsilon-protein kinase C (εPKC) protects the heart from ischemic injury. However, the mechanism(s) of εPKC cardioprotection is still unclear. Identification of the εPKC targets may aid in elucidating the εPKC-mediated cardioprotective mechanisms. Previous studies, using εPKC transgenic mice and difference in gel electrophoresis, identified proteins involved in glucose metabolism, the expression of which was modified by εPKC. Those studies were accompanied by metabolomic analysis, suggesting that increased glucose oxidation may be responsible for the cardioprotective effect of εPKC. Whether these εPKC-mediated alterations were because of differences in protein expression or phosphorylation was not determined. METHODS AND RESULTS: In the present study, we used an εPKC -specific activator peptide, ψεRACK, combined with phosphoproteomics, to find εPKC targets, and identified that the proteins whose phosphorylation was altered by selective activation of εPKC were mostly mitochondrial proteins. Analysis of the mitochondrial phosphoproteome led to the identification of 55 spots, corresponding to 37 individual proteins, exclusively phosphorylated, in the presence of ψεRACK. The majority of the proteins identified were involved in glucose and lipid metabolism, components of the respiratory chain as well as mitochondrial heat shock proteins. CONCLUSIONS: The protective effect of εPKC during ischemia involves phosphorylation of several mitochondrial proteins involved in glucose and lipid metabolism and oxidative phosphorylation. Regulation of these metabolic pathways by εPKC phosphorylation may lead to εPKC-mediated cardioprotection induced by ψεRACK.
Authors: Helio Miranda Costa-Junior; Nicole Milaré Garavello; Mariana Lemos Duarte; Denise Aparecida Berti; Talita Glaser; Alexander de Andrade; Carlos A Labate; André Teixeira da Silva Ferreira; Jonas Enrique Aguilar Perales; José Xavier-Neto; José Eduardo Krieger; Deborah Schechtman Journal: J Proteome Res Date: 2010-11-01 Impact factor: 4.466
Authors: Keith D Garlid; Alexandre D T Costa; Casey L Quinlan; Sandrine V Pierre; Pierre Dos Santos Journal: J Mol Cell Cardiol Date: 2008-12-11 Impact factor: 5.000
Authors: G W Dorn; M C Souroujon; T Liron; C H Chen; M O Gray; H Z Zhou; M Csukai; G Wu; J N Lorenz; D Mochly-Rosen Journal: Proc Natl Acad Sci U S A Date: 1999-10-26 Impact factor: 11.205
Authors: Grant R Budas; Eric N Churchill; Marie-Hélène Disatnik; Lihan Sun; Daria Mochly-Rosen Journal: Cardiovasc Res Date: 2010-06-16 Impact factor: 10.787
Authors: Manuel Mayr; David Liem; Jun Zhang; Xiaohai Li; Nuraly K Avliyakulov; Jeong In Yang; Glen Young; Tom M Vondriska; Christophe Ladroue; Basetti Madhu; John R Griffiths; Aldrin Gomes; Qingbo Xu; Peipei Ping Journal: J Mol Cell Cardiol Date: 2008-10-26 Impact factor: 5.000
Authors: Eric N Churchill; Julio C Ferreira; Patricia C Brum; Luke I Szweda; Daria Mochly-Rosen Journal: Cardiovasc Res Date: 2009-10-10 Impact factor: 13.081
Authors: Kyung In Baek; Rongsong Li; Nelson Jen; Howard Choi; Amir Kaboodrangi; Peipei Ping; David Liem; Tyler Beebe; Tzung K Hsiai Journal: Antioxid Redox Signal Date: 2017-09-21 Impact factor: 8.401
Authors: Brandon M Gassaway; Max C Petersen; Yulia V Surovtseva; Karl W Barber; Joshua B Sheetz; Hans R Aerni; Jane S Merkel; Varman T Samuel; Gerald I Shulman; Jesse Rinehart Journal: Proc Natl Acad Sci U S A Date: 2018-09-04 Impact factor: 11.205
Authors: Débora da Luz Scheffer; Adriana Ann Garcia; Lucia Lee; Daria Mochly-Rosen; Julio Cesar Batista Ferreira Journal: Antioxid Redox Signal Date: 2022-04-18 Impact factor: 7.468
Authors: Rashidi M Pakri Mohamed; Mohd H Mokhtar; Ernie Yap; Athirah Hanim; Norhazlina Abdul Wahab; Farah H F Jaffar; Jaya Kumar Journal: Front Neurosci Date: 2018-04-12 Impact factor: 4.677