Lotteau Sabine, Ivarsson Niklas, Yang Zhaokang, Restagno Damien, Colyer John, Hopkins Philip, Weightman Andrew, Himori Koichi, Yamada Takashi, Bruton Joseph, Steele Derek, Westerblad Håkan, Calaghan Sarah
School of Biomedical Sciences, Faculty of Biological Sciences, University of Leeds, Leeds, United Kingdom.
Department of Physiology and Pharmacology, Karolinska Institutet, Stockholm, Sweden.
JACC Basic Transl Sci. 2019 Aug 26;4(4):509-523. doi: 10.1016/j.jacbts.2019.03.012. eCollection 2019 Aug.
This study aimed to identify a mechanism for statin-induced myopathy that explains its prevalence and selectivity for skeletal muscle, and to understand its interaction with moderate exercise. Statin-associated adverse muscle symptoms reduce adherence to statin therapy; this limits the effectiveness of statins in reducing cardiovascular risk. The issue is further compounded by perceived interactions between statin treatment and exercise. This study examined muscles from individuals taking statins and rats treated with statins for 4 weeks. In skeletal muscle, statin treatment caused dissociation of the stabilizing protein FK506 binding protein (FKBP12) from the sarcoplasmic reticulum (SR) calcium (Ca) release channel, the ryanodine receptor 1, which was associated with pro-apoptotic signaling and reactive nitrogen species/reactive oxygen species (RNS/ROS)-dependent spontaneous SR Ca release events (Ca sparks). Statin treatment had no effect on Ca spark frequency in cardiac myocytes. Despite potentially deleterious effects of statins on skeletal muscle, there was no impact on force production or SR Ca release in electrically stimulated muscle fibers. Statin-treated rats with access to a running wheel ran further than control rats; this exercise normalized FKBP12 binding to ryanodine receptor 1, preventing the increase in Ca sparks and pro-apoptotic signaling. Statin-mediated RNS/ROS-dependent destabilization of SR Ca handling has the potential to initiate skeletal (but not cardiac) myopathy in susceptible individuals. Importantly, although exercise increases RNS/ROS, it did not trigger deleterious statin effects on skeletal muscle. Indeed, our results indicate that moderate exercise might benefit individuals who take statins.
本研究旨在确定他汀类药物诱发肌病的机制,该机制可解释其在骨骼肌中的患病率和选择性,并了解其与适度运动的相互作用。与他汀类药物相关的不良肌肉症状会降低患者对他汀类药物治疗的依从性;这限制了他汀类药物在降低心血管风险方面的有效性。他汀类药物治疗与运动之间的潜在相互作用使问题更加复杂。本研究检查了服用他汀类药物的个体以及用他汀类药物治疗4周的大鼠的肌肉。在骨骼肌中,他汀类药物治疗导致稳定蛋白FK506结合蛋白(FKBP12)从肌浆网(SR)钙(Ca)释放通道——兰尼碱受体1解离,这与促凋亡信号传导以及依赖活性氮/活性氧(RNS/ROS)的自发SR Ca释放事件(Ca火花)有关。他汀类药物治疗对心肌细胞中的Ca火花频率没有影响。尽管他汀类药物对骨骼肌有潜在的有害影响,但对电刺激的肌纤维的力量产生或SR Ca释放没有影响。可以使用跑步机的他汀类药物治疗的大鼠比对照大鼠跑得更远;这种运动使FKBP12与兰尼碱受体1的结合正常化,防止Ca火花增加和促凋亡信号传导。他汀类药物介导的依赖RNS/ROS的SR Ca处理不稳定有可能在易感个体中引发骨骼肌(而非心肌)肌病。重要的是,尽管运动会增加RNS/ROS,但它并未引发他汀类药物对骨骼肌的有害影响。实际上,我们的结果表明适度运动可能对服用他汀类药物的个体有益。
