Biochemical and biophysical properties of an unreported T96R mutation causing transthyretin cardiac amyloidosis.

IF 5.2 2区医学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Amyloid-Journal of Protein Folding Disorders Pub Date : 2023-06-01 DOI:10.1080/13506129.2022.2142109

Meng Jiang, Mengdie Wang, Zhengyu Tao, Yezi Chai, Qiming Liu, Qifan Lu, Qizhen Wu, Xiaoying Ying, Yanan Huang, Ying Nie, Yuqi Tang, Xin Zhang, Yu Liu, Jun Pu

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Abstract

Objectives: We presented an unreported T96R mutation induced transthyretin cardiac amyloidosis (ATTR). The biochemical and biophysical properties were explored to support its pathogenicity.

Background: Understanding the biochemical and biophysical nature of genetically mutated transthyretin (TTR) proteins is key to provide precise medical cares for ATTR patients.

Results: Genetic testing showed heterozygosity for the T96R pathogenic variant c.347C > G (ATTR p.T116R) after myocardial biopsy confirmed amyloid deposition. Biochemical characterizations revealed slight perturbation of its thermodynamic stability (C_m=3.7 M for T96R, 3.4 M for WT and 2.3 M for L55P (commonly studied TTR mutant)) and kinetic stability (t_1/2=39.8 h for T96R, 42 h for WT and 4.4 h in L55P). Crosslinking experiment demonstrated heterozygous subunit exchange between wild-type and TTR T96R protein destabilized the tetramer. Inhibitory effect of tafamidis and diflunisal on TTR T96R fibril formation was slightly less effective compared to WT and L55P.

Conclusions: A novel T96R mutation was identified for TTR protein. Biochemical and biophysical analyses revealed slightly destabilized kinetic stability. T96R mutation destabilized heterozygous protein but not proteolytic degradation, explaining its pathogenicity. Inhibitory effect of small molecule drugs on T96R mutation was different, suggesting personalized treatment may be required.

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未报道的T96R突变引起转甲状腺素心脏淀粉样变性的生化和生物物理特性。

目的:我们报道了一个未报道的T96R突变引起的转甲状腺素型心脏淀粉样变性(ATTR)。探讨了其生物化学和生物物理特性，以支持其致病性。背景:了解基因突变的转甲状腺素(TTR)蛋白的生化和生物物理性质是为ATTR患者提供精准医疗护理的关键。结果:心肌活检证实淀粉样蛋白沉积，基因检测显示T96R致病变异c.347C > G (ATTR p.T116R)杂合性。生化表征显示，其热力学稳定性(T96R为3.7 M, WT为3.4 M, L55P为2.3 M(通常研究的TTR突变体))和动力学稳定性(T96R为39.8 h, WT为42 h, L55P为4.4 h)略有扰动。交联实验表明，野生型与TTR之间的杂合亚基交换使T96R蛋白四聚体不稳定。与WT和L55P相比，他非他司和二氟尼松对TTR - T96R纤维形成的抑制作用稍弱。结论:发现了一种新的TTR蛋白T96R突变。生化和生物物理分析显示其动力学稳定性略有不稳定。T96R突变使杂合蛋白失稳，但不发生蛋白水解降解，解释了其致病性。小分子药物对T96R突变的抑制效果不同，可能需要个性化治疗。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Amyloid-Journal of Protein Folding Disorders 生物-生化与分子生物学

CiteScore

10.60

自引率

10.90%

发文量

审稿时长

6-12 weeks

期刊介绍： Amyloid: the Journal of Protein Folding Disorders is dedicated to the study of all aspects of the protein groups and associated disorders that are classified as the amyloidoses as well as other disorders associated with abnormal protein folding. The journals major focus points are: etiology, pathogenesis, histopathology, chemical structure, nature of fibrillogenesis; whilst also publishing papers on the basic and chemical genetic aspects of many of these disorders. Amyloid is recognised as one of the leading publications on amyloid protein classifications and the associated disorders, as well as clinical studies on all aspects of amyloid related neurodegenerative diseases and major clinical studies on inherited amyloidosis, especially those related to transthyretin. The Journal also publishes book reviews, meeting reports, editorials, thesis abstracts, review articles and symposia in the various areas listed above.