OBJECTIVES: We investigated the incidence and contribution of the oxidation/nitrosylation of tropomyosin and actin to the contractile impairment and cardiomyocyte injury occurring in human end-stage heart failure (HF) as compared with nonfailing donor hearts. BACKGROUND: Although there is growing evidence that augmented intracellular accumulation of reactive oxygen/nitrogen species may play a key role in causing contractile dysfunction, there is a dearth of data regarding their contractile protein targets in human HF. METHODS: In left ventricular (LV) biopsies from explanted failing hearts (New York Heart Association functional class IV; HF group) and nonfailing donor hearts (NF group), carbonylation of actin and tropomyosin, disulphide cross-bridge (DCB) formation, and S-nitrosylation in tropomyosin were assessed, along with plasma troponin I and LV ejection fraction (LVEF). RESULTS: The LV biopsies from the HF group had 2.14 ± 0.23-fold and 2.31 ± 0.46-fold greater levels in actin and tropomyosin carbonylation, respectively, and 1.77 ± 0.45-fold greater levels of high-molecular-weight complexes of tropomyosin due to DCB formation, compared with the NF group. Tropomyosin also underwent S-nitrosylation that was 1.3 ± 0.15-fold higher in the HF group. Notably, actin and tropomyosin carbonylation was significantly correlated with both loss of viability indicated by plasma troponin I and contractile impairment as shown by reduced LVEF. CONCLUSIONS: This study demonstrated that oxidative/nitrosylative changes of actin and tropomyosin are largely increased in human failing hearts. Because these changes are inversely correlated to LVEF, actin and tropomyosin oxidation are likely to contribute to the contractile impairment evident in end-stage HF. Copyright Â
OBJECTIVES: We investigated the incidence and contribution of the oxidation/nitrosylation of tropomyosin and actin to the contractile impairment and cardiomyocyte injury occurring in human end-stage heart failure (HF) as compared with nonfailing donor hearts. BACKGROUND: Although there is growing evidence that augmented intracellular accumulation of reactive oxygen/nitrogen species may play a key role in causing contractile dysfunction, there is a dearth of data regarding their contractile protein targets in human HF. METHODS: In left ventricular (LV) biopsies from explanted failing hearts (New York Heart Association functional class IV; HF group) and nonfailing donor hearts (NF group), carbonylation of actin and tropomyosin, disulphide cross-bridge (DCB) formation, and S-nitrosylation in tropomyosin were assessed, along with plasma troponin I and LV ejection fraction (LVEF). RESULTS: The LV biopsies from the HF group had 2.14 ± 0.23-fold and 2.31 ± 0.46-fold greater levels in actin and tropomyosin carbonylation, respectively, and 1.77 ± 0.45-fold greater levels of high-molecular-weight complexes of tropomyosin due to DCB formation, compared with the NF group. Tropomyosin also underwent S-nitrosylation that was 1.3 ± 0.15-fold higher in the HF group. Notably, actin and tropomyosin carbonylation was significantly correlated with both loss of viability indicated by plasma troponin I and contractile impairment as shown by reduced LVEF. CONCLUSIONS: This study demonstrated that oxidative/nitrosylative changes of actin and tropomyosin are largely increased in human failing hearts. Because these changes are inversely correlated to LVEF, actin and tropomyosin oxidation are likely to contribute to the contractile impairment evident in end-stage HF. Copyright Â
Authors: Vikas Kumar; Timothy Dean Calamaras; Dagmar Haeussler; Wilson Steven Colucci; Richard Alan Cohen; Mark Errol McComb; David Pimentel; Markus Michael Bachschmid Journal: Antioxid Redox Signal Date: 2012-08-10 Impact factor: 8.401
Authors: Heaseung S Chung; Sheng-Bing Wang; Vidya Venkatraman; Christopher I Murray; Jennifer E Van Eyk Journal: Circ Res Date: 2013-01-18 Impact factor: 17.367
Authors: Gábor Koncsos; Zoltán V Varga; Tamás Baranyai; Kerstin Boengler; Susanne Rohrbach; Ling Li; Klaus-Dieter Schlüter; Rolf Schreckenberg; Tamás Radovits; Attila Oláh; Csaba Mátyás; Árpád Lux; Mahmoud Al-Khrasani; Tímea Komlódi; Nóra Bukosza; Domokos Máthé; László Deres; Monika Barteková; Tomáš Rajtík; Adriana Adameová; Krisztián Szigeti; Péter Hamar; Zsuzsanna Helyes; László Tretter; Pál Pacher; Béla Merkely; Zoltán Giricz; Rainer Schulz; Péter Ferdinandy Journal: Am J Physiol Heart Circ Physiol Date: 2016-08-12 Impact factor: 4.733