Distinct mechanisms drive divergent phenotypes in hypertrophic and dilated cardiomyopathy associated TPM1 variants.

Saiti S Halder,Michael J Rynkiewicz,Lynne Kim,Meaghan Barry,Ahmed Ga Zied,Lorenzo R Sewanan,Jonathan A Kirk,Jeffrey R Moore,William Lehman,Stuart G Campbell
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Abstract

Hypertrophic and dilated cardiomyopathies (HCM and DCM, respectively) are inherited disorders that may be caused by mutations to the same sarcomeric protein but have completely different clinical phenotypes. The precise mechanisms by which point mutations within the same gene bring about phenotypic diversity remain unclear. Our objective has been to develop a mechanistic explanation of diverging phenotypes in two TPM1 mutations, E62Q (HCM) and E54K (DCM). Drawing on data from the literature and experiments with stem cell-derived cardiomyocytes expressing the TPM1 mutations of interest, we constructed computational simulations that provide plausible explanations of the distinct muscle contractility caused by each variant. In E62Q, increased calcium sensitivity and hypercontractility was explained most accurately by a reduction in effective molecular stiffness of tropomyosin and alterations in its interactions with the actin thin filament that favor the 'closed' regulatory state. By contrast, the E54K mutation appeared to act via long-range allosteric interactions to increase the association rate of the C-terminal troponin I mobile domain to tropomyosin/actin. These mutation-linked molecular events produced diverging alterations in gene expression that can be observed in human engineered heart tissues. Modulators of myosin activity confirmed our proposed mechanisms by rescuing normal contractile behavior in accordance with predictions.
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肥厚型心肌病和扩张型心肌病相关 TPM1 变体的不同表型具有不同的驱动机制。
肥厚型心肌病和扩张型心肌病(分别为 HCM 和 DCM)是一种遗传性疾病,可能由相同的肌浆蛋白突变引起,但临床表型却完全不同。同一基因中的点突变导致表型多样性的确切机制仍不清楚。我们的目标是对两种 TPM1 突变(E62Q(HCM)和 E54K(DCM))的不同表型做出机理解释。我们利用文献数据和表达相关 TPM1 突变的干细胞衍生心肌细胞的实验,构建了计算模拟,为每种变异引起的不同肌肉收缩能力提供了合理的解释。在 E62Q 突变体中,钙敏感性和过度收缩性增加的最准确解释是肌球蛋白有效分子刚度的降低及其与肌动蛋白细丝相互作用的改变,这种改变有利于 "封闭 "调节状态。相比之下,E54K 突变似乎是通过长程异构相互作用来增加 C 端肌钙蛋白 I 移动结构域与肌球蛋白/肌动蛋白的结合率。这些与突变相关的分子事件导致了基因表达的不同变化,这些变化可以在人体工程心脏组织中观察到。肌球蛋白活性调节剂根据预测挽救了正常的收缩行为,从而证实了我们提出的机制。
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