Fu Ying, Shaw Seiji A, Naami Robert, Vuong Caresse L, Basheer Wassim A, Guo Xiuqing, Hong TingTing
From Cedars-Sinai Heart Institute, Cedars-Sinai Medical Center, Los Angeles, CA (Y.F., S.A.S., R.N., C.L.V., W.A.B., T.H.); Institute for Translational Genomics and Population Sciences, Department of Pediatrics, Los Angeles Biomedical Research Institute at Harbor-UCLA Medical Center, Torrance, CA (X.G.); and Departments of Medicine, Cedars-Sinai Medical Center and UCLA, Los Angeles, CA (T.H.).
Circulation. 2016 Jan 26;133(4):388-97. doi: 10.1161/CIRCULATIONAHA.115.018535. Epub 2016 Jan 5.
The key pathophysiology of human acquired heart failure is impaired calcium transient, which is initiated at dyads consisting of ryanodine receptors (RyRs) at sarcoplasmic reticulum apposing CaV1.2 channels at t-tubules. Sympathetic tone regulates myocardial calcium transients through β-adrenergic receptor (β-AR)-mediated phosphorylation of dyadic proteins. Phosphorylated RyRs (P-RyR) have increased calcium sensitivity and open probability, amplifying calcium transient at a cost of receptor instability. Given that bridging integrator 1 (BIN1) organizes t-tubule microfolds and facilitates CaV1.2 delivery, we explored whether β-AR-regulated RyRs are also affected by BIN1.
Isolated adult mouse hearts or cardiomyocytes were perfused for 5 minutes with the β-AR agonist isoproterenol (1 µmol/L) or the blockers CGP+ICI (baseline). Using biochemistry and superresolution fluorescent imaging, we identified that BIN1 clusters P-RyR and CaV1.2. Acute β-AR activation increases coimmunoprecipitation between P-RyR and cardiac spliced BIN1+13+17 (with exons 13 and 17). Isoproterenol redistributes BIN1 to t-tubules, recruiting P-RyRs and improving the calcium transient. In cardiac-specific Bin1 heterozygote mice, isoproterenol fails to concentrate BIN1 to t-tubules, impairing P-RyR recruitment. The resultant accumulation of uncoupled P-RyRs increases the incidence of spontaneous calcium release. In human hearts with end-stage ischemic cardiomyopathy, we find that BIN1 is also 50% reduced, with diminished P-RyR association with BIN1.
On β-AR activation, reorganization of BIN1-induced microdomains recruits P-RyR into dyads, increasing the calcium transient while preserving electric stability. When BIN1 is reduced as in human acquired heart failure, acute stress impairs microdomain formation, limiting contractility and promoting arrhythmias.
人类获得性心力衰竭的关键病理生理学特征是钙瞬变受损,其始于由肌浆网中的兰尼碱受体(RyRs)与横管中的CaV1.2通道相对构成的二联体。交感神经张力通过β-肾上腺素能受体(β-AR)介导的二联体蛋白磷酸化来调节心肌钙瞬变。磷酸化的RyRs(P-RyR)具有更高的钙敏感性和开放概率,以受体不稳定为代价放大钙瞬变。鉴于桥连整合蛋白1(BIN1)组织横管微褶并促进CaV1.2的转运,我们探究了β-AR调节的RyRs是否也受BIN1影响。
将成年小鼠离体心脏或心肌细胞用β-AR激动剂异丙肾上腺素(1 μmol/L)或阻滞剂CGP + ICI(基线)灌注5分钟。通过生物化学和超分辨率荧光成像,我们确定BIN1使P-RyR和CaV1.2聚集。急性β-AR激活增加了P-RyR与心脏剪接型BIN1 + 13 + 17(含外显子13和17)之间的共免疫沉淀。异丙肾上腺素将BIN1重新分布至横管,募集P-RyRs并改善钙瞬变。在心脏特异性Bin1杂合子小鼠中,异丙肾上腺素无法使BIN1聚集至横管,损害P-RyR的募集。未偶联的P-RyRs的累积增加了自发钙释放的发生率。在终末期缺血性心肌病患者心脏中,我们发现BIN1也减少了50%,且P-RyR与BIN1的结合减少。
在β-AR激活时,BIN1诱导的微区重组将P-RyR募集至二联体,增加钙瞬变同时保持电稳定性。当BIN1如在人类获得性心力衰竭中那样减少时,急性应激会损害微区形成,限制收缩力并促进心律失常。
