De Zio Roberta, Pietrafesa Giusy, Milano Serena, Procino Giuseppe, Bramerio Manuela, Pepe Martino, Forleo Cinzia, Favale Stefano, Svelto Maria, Gerbino Andrea, Carmosino Monica
Department of Biosciences, Biotechnologies and Biopharmaceutics, University of Bari, Bari, Italy.
Department of Sciences, University of Basilicata, Potenza, Italy.
Front Cell Dev Biol. 2022 Jun 29;10:918760. doi: 10.3389/fcell.2022.918760. eCollection 2022.
In this work, we studied an nonsense mutation encoding for the C-terminally truncated Lamin A/C (LMNA) variant Q517X, which was described in patients affected by a severe arrhythmogenic cardiomyopathy with history of sudden death. We found that LMNA Q517X stably expressed in HL-1 cardiomyocytes abnormally aggregates at the nuclear envelope and within the nucleoplasm. Whole-cell patch clamp experiments showed that LMNA Q517X-expressing cardiomyocytes generated action potentials with reduced amplitude, overshoot, upstroke velocity and diastolic potential compared with LMNA WT-expressing cardiomyocytes. Moreover, the unique features of these cardiomyocytes were 1) hyper-polymerized tubulin network, 2) upregulated acetylated α-tubulin, and 3) cell surface Nav1.5 downregulation. These findings pointed the light on the role of tubulin and Nav1.5 channel in the abnormal electrical properties of LMNA Q517X-expressing cardiomyocytes. When expressed in HEK293 with Nav1.5 and its β1 subunit, LMNA Q517X reduced the peak Na current (I) up to 63% with a shift toward positive potentials in the activation curve of the channel. Of note, both AP properties in cardiomyocytes and Nav1.5 kinetics in HEK293 cells were rescued in LMNA Q517X-expressing cells upon treatment with colchicine, an FDA-approved inhibitor of tubulin assembly. In conclusion, LMNA Q517X expression is associated with hyper-polymerization and hyper-acetylation of tubulin network with concomitant downregulation of Nav1.5 cell expression and activity, thus revealing 1) new mechanisms by which LMNA may regulate channels at the cell surface in cardiomyocytes and 2) new pathomechanisms and therapeutic targets in cardiac laminopathies.
在本研究中,我们对编码C端截短的核纤层蛋白A/C(LMNA)变体Q517X的无义突变进行了研究,该突变在患有严重致心律失常性心肌病且有猝死病史的患者中被发现。我们发现,在HL-1心肌细胞中稳定表达的LMNA Q517X在核膜和核质内异常聚集。全细胞膜片钳实验表明,与表达LMNA野生型(WT)的心肌细胞相比,表达LMNA Q517X的心肌细胞产生的动作电位幅度降低、超射值降低、上升速度减慢且舒张电位降低。此外,这些心肌细胞的独特特征包括:1)微管蛋白网络过度聚合;2)乙酰化α-微管蛋白上调;3)细胞表面Nav1.5下调。这些发现揭示了微管蛋白和Nav1.5通道在表达LMNA Q517X的心肌细胞异常电特性中的作用。当与Nav1.5及其β1亚基一起在HEK293细胞中表达时,LMNA Q517X使钠电流峰值(I)降低了63%,同时通道激活曲线向正电位方向偏移。值得注意的是,在用秋水仙碱(一种FDA批准的微管蛋白组装抑制剂)处理后,表达LMNA Q517X的细胞中心肌细胞的动作电位特性和HEK293细胞中Nav1.5的动力学均得到了恢复。总之,LMNA Q517X的表达与微管蛋白网络的过度聚合和过度乙酰化以及Nav1.5细胞表达和活性的下调有关,从而揭示了1)LMNA可能调节心肌细胞表面通道的新机制,以及2)心脏核纤层蛋白病的新发病机制和治疗靶点。
