Kuum Malle, Kaasik Allen, Joubert Frederic, Ventura-Clapier Renée, Veksler Vladimir
Faculté de Pharmacie, U-769 INSERM, Université Paris-Sud, Châtenay-Malabry, France.
Cardiovasc Res. 2009 Jul 1;83(1):89-96. doi: 10.1093/cvr/cvp125. Epub 2009 Apr 23.
Increased diastolic sarcoplasmic reticulum (SR) Ca(2+) loss could depress contractility in heart failure. Since the failing myocardium has impaired energetics, we investigated whether Ca(2+) loss is linked to changes in energetic pathways.
Leakage from SR in mouse permeabilized preparations was assessed using exogenous ATP, ATP + phosphocreatine (activation of bound creatine kinase, CK), ATP + mitochondrial substrates (mitochondrial activation), or with all of these together (optimal energetic conditions) in Ca(2+)-free solution. In ventricular fibres caffeine-induced tension transients under optimal energetic conditions were used to estimate SR [Ca(2+)]. In cardiomyocytes, intra-SR Ca(2+) was monitored by use of the fluorescent marker Mag-fluo 4. In fibres, SR Ca(2+) content after 5 min incubation strongly depended on energy supply (100%-optimal energetic conditions; 27 +/- 5%-exogenous ATP only, 52 +/- 5%-endogenous CK activation; 88 +/- 8%-mitochondrial activation, P < 0.01 vs. CK system). The significant loss with only exogenous ATP was not inhibited by the ryanodine receptor blockers tetracaine or ruthenium red. However, the SR Ca(2+)-ATPase (SERCA) inhibitors cyclopiazonic acid or 2,5-di(tert-butyl)-1,4-benzohydroquinone significantly decreased Ca(2+) loss. At 100 nM external [Ca(2+)], the SR Ca(2+) loss was also energy dependent and was not significantly inhibited by tetracaine. In cardiomyocytes, the decline in SR [Ca(2+)] at zero external [Ca(2+)] was almost two times slower under optimal energetic conditions than in the presence of exogenous ATP only.
At low extra-reticular [Ca(2+)], the main leak pathway is an energy-sensitive backward Ca(2+) pump, and direct mitochondrial-SERCA ATP channelling is more effective in leak prevention than local ATP generation by bound CK.
舒张期肌浆网(SR)钙(Ca2+)流失增加会降低心力衰竭时的心肌收缩力。由于衰竭心肌的能量代谢受损,我们研究了Ca2+流失是否与能量代谢途径的变化有关。
在无钙溶液中,使用外源性ATP、ATP + 磷酸肌酸(激活结合型肌酸激酶,CK)、ATP + 线粒体底物(线粒体激活)或所有这些一起使用(最佳能量条件)来评估小鼠透化制剂中SR的泄漏情况。在最佳能量条件下,利用咖啡因诱导的心室纤维张力瞬变来估计SR [Ca2+]。在心肌细胞中,通过使用荧光标记物Mag-fluo 4监测肌浆网内的Ca2+。在纤维中,孵育5分钟后的SR Ca2+含量强烈依赖于能量供应(100%为最佳能量条件;仅外源性ATP时为27±5%;内源性CK激活时为52±5%;线粒体激活时为88±8%,与CK系统相比,P <0.01)。仅外源性ATP时Ca2+的显著流失不受ryanodine受体阻滞剂丁卡因或钌红的抑制。然而,SR Ca2+-ATP酶(SERCA)抑制剂环匹阿尼酸或2,5-二(叔丁基)-1,4-苯二酚显著降低了Ca2+流失。在细胞外[Ca2+]为100 nM时,SR Ca2+流失也依赖于能量,且不受丁卡因的显著抑制。在心肌细胞中,在细胞外[Ca2+]为零时肌浆网[Ca2+] 的下降在最佳能量条件下比仅存在外源性ATP时慢近两倍。
在低细胞外网状[Ca2+]时,主要的泄漏途径是能量敏感的逆向Ca2+泵,并且直接的线粒体-SERCA ATP通道在防止泄漏方面比结合型CK产生局部ATP更有效。
