兔心肌细胞肌浆网与线粒体之间的钙离子循环
Ca2+ cycling between sarcoplasmic reticulum and mitochondria in rabbit cardiac myocytes.
作者信息
Bassani J W, Bassani R A, Bers D M
机构信息
Division of Biomedical Sciences, University of California, Riverside 92521.
出版信息
J Physiol. 1993 Jan;460:603-21. doi: 10.1113/jphysiol.1993.sp019489.
Abstract
- Shortening and intracellular Ca2+ (Ca2+i) transients were measured in isolated rabbit ventricular myocytes during paired contractures induced by rapid application of 10 mM caffeine. 2. Caffeine-induced contractures relax despite maintained presence of caffeine. In control solution, a second phasic caffeine contracture failed to appear, unless the sarcoplasmic reticulum (SR) was refilled by a series of electrically stimulated twitches during the interval between caffeine exposures. 3. The relaxation of caffeine-induced contractures in 0 Na(+)-0 Ca2+ solution has previously been shown to rely on mitochondrial Ca2+ uptake and sarcolemmal Ca2(+)-ATPase. Thus, a second caffeine contracture (T2) while still in 0 Na(+)-0 Ca2+ was greatly reduced compared to the first one (T1). However, the amplitude of T2 increased exponentially with the time interval, attaining a maximum of approximately 50% of T1 for an interval of 180-300 s, with a time constant (tau) of 41.2 s. Similar results were found for Ca2+i transients (tau = 45 s). 4. Inhibition of the mitochondrial Ca2+ uptake by the oxidative phosphorylation uncoupler, FCCP during T1 dramatically depressed T2. On the other hand, inhibition of the sarcolemmal Ca2(+)-ATPase (by increasing extracellular Ca2+ concentration, [Ca2+]o) resulted in increase of T2. Spermine inclusion during T1 also increased T2, possibly by an increase of mitochondrial Ca2+ uptake. 5. We conclude that Ca2+ taken up by mitochondria during the decline of T1 moves back to the SR after caffeine is removed, with a tau approximately 40 s. 6. Partial intracellular Na+ depletion by prolonged (3 min) perfusion with 0 Na(+)-0 Ca2+ solution before T1 (a) accelerated relaxation and [Ca2+]i decline during T1, and (b) slowed, but did not abolish, the recovery of T2 as the interval was increased. This effect was particularly pronounced when choline was used instead of Li+ as the Na+ substitute. 7. We further conclude that the mitochondrial Na(+)-Ca2+ antiporter influences the rate of net Ca2+ uptake by mitochondria and is also important in Ca2+ efflux from mitochondria during rest.
摘要
- 在快速施加10 mM咖啡因诱导的成对挛缩过程中,测量了分离的兔心室肌细胞的缩短和细胞内Ca2+(Ca2+i)瞬变。2. 尽管咖啡因持续存在,但咖啡因诱导的挛缩仍会松弛。在对照溶液中,除非在咖啡因暴露间隔期间通过一系列电刺激抽搐使肌浆网(SR)重新充盈,否则第二次相性咖啡因挛缩不会出现。3. 先前已表明,在0 Na(+)-0 Ca2+溶液中,咖啡因诱导的挛缩的松弛依赖于线粒体Ca2+摄取和肌膜Ca2(+)-ATP酶。因此,与第一次(T1)相比,在仍处于0 Na(+)-0 Ca2+时的第二次咖啡因挛缩(T2)大大减小。然而,T2的幅度随时间间隔呈指数增加,在180 - 300 s的间隔内达到T1的约50%的最大值,时间常数(tau)为41.2 s。对于Ca2+i瞬变也发现了类似结果(tau = 45 s)。4. 在T1期间,氧化磷酸化解偶联剂FCCP抑制线粒体Ca2+摄取会显著降低T2。另一方面,抑制肌膜Ca2(+)-ATP酶(通过增加细胞外Ca2+浓度,[Ca2+]o)会导致T2增加。在T1期间加入精胺也会增加T2,可能是通过增加线粒体Ca2+摄取。5. 我们得出结论,在T1下降期间被线粒体摄取的Ca2+在咖啡因去除后会以约40 s的tau回到SR。6. 在T1之前用0 Na(+)-0 Ca2+溶液长时间(3分钟)灌注导致细胞内部分Na+耗竭:(a)加速了T1期间的松弛和[Ca2+]i下降,(b)随着间隔增加,减缓但未消除T2的恢复。当使用胆碱代替Li+作为Na+替代物时,这种效应尤为明显。7. 我们进一步得出结论,线粒体Na(+)-Ca2+反向转运体影响线粒体净Ca2+摄取的速率,并且在静息期间线粒体Ca2+外流中也很重要。
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