Frameshift variants in C10orf71 cause dilated cardiomyopathy in human, mouse, and organoid models
Yang Li, … , Wendy K. Chung, Yulin Li
Yang Li, … , Wendy K. Chung, Yulin Li
Published June 17, 2024
Citation Information: J Clin Invest. 2024;134(12):e177172. https://doi.org/10.1172/JCI177172.
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Frameshift variants in C10orf71 cause dilated cardiomyopathy in human, mouse, and organoid models

Abstract

Research advances over the past 30 years have confirmed a critical role for genetics in the etiology of dilated cardiomyopathies (DCMs). However, full knowledge of the genetic architecture of DCM remains incomplete. We identified candidate DCM causal gene, C10orf71, in a large family with 8 patients with DCM by whole-exome sequencing. Four loss-of-function variants of C10orf71 were subsequently identified in an additional group of492 patients with sporadic DCM from 2 independent cohorts. C10orf71 was found to be an intrinsically disordered protein specifically expressed in cardiomyocytes. C10orf71-KO mice had abnormal heart morphogenesis during embryonic development and cardiac dysfunction as adults with altered expression and splicing of contractile cardiac genes. C10orf71-null cardiomyocytes exhibited impaired contractile function with unaffected sarcomere structure. Cardiomyocytes and heart organoids derived from human induced pluripotent stem cells with C10orf71 frameshift variants also had contractile defects with normal electrophysiological activity. A rescue study using a cardiac myosin activator, omecamtiv mecarbil, restored contractile function in C10orf71-KO mice. These data support C10orf71 as a causal gene for DCM by contributing to the contractile function of cardiomyocytes. Mutation-specific pathophysiology may suggest therapeutic targets and more individualized therapy.

Authors

Yang Li, Ke Ma, Zhujun Dong, Shijuan Gao, Jing Zhang, Shan Huang, Jie Yang, Guangming Fang, Yujie Li, Xiaowei Li, Carrie Welch, Emily L. Griffin, Prema Ramaswamy, Zaheer Valivullah, Xiuying Liu, Jianzeng Dong, Dao Wen Wang, Jie Du, Wendy K. Chung, Yulin Li

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Figure 4

Phenotypes of heart in adult mC10orf71–/– mice.

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Phenotypes of heart in adult mC10orf71–/– mice. (A) Survival rate of WT ...
(A) Survival rate of WT and mC10orf71–/– (n = 10 per group) mice. (B) A photograph of hearts from 4 and 8-month-old mice (4 mo; 8 mo). Scale bar: 2.5 mm.(C) Histological analysis of hearts by H&E staining. Scale bar: 2 mm. (D) Quantification of cross-sectional area of left ventricle shown in panel C (n = 10 per group at 4 months; n = 7–8 at 8 months). *P < 0.05, **P < 0.01 in t test. (E) Representative echocardiographic images. (F) Echocardiographic parameters (n = 16 per group at 4 months; n = 7–8 at 8 months). EF, ejection fraction; FS, fraction shortening; SV, stroke volume; LVID-s, internal dimension of left ventricle at end systole; LVVOL-s, left ventricular volume at end-systole; LVPW-s, posterior wall thickness of LV at end-systole. **P < 0.01, ***P < 0.001 in t test. (G) Masson staining of hearts. Scale bar: 150 μm. (H) Quantification of fibrosis area at 8 months shown in panel G. ***P < 0.001 in t test. (I) WGA staining of hearts. (J) Quantification of cross-sectional area of CMs shown in panel I (n = 10 per group at 4 months; n = 7–8 at 8 months, n = 250–350 cells per mouse). ***P < 0.001 in t test. Scale bar: 20 μm. (K) Relative mRNA levels of Acta1 and Nppb in hearts (n = 5 per group at 4 months; n = 7–8 at 8 months). **P < 0.01 in Mann-Whitney test. ***P < 0.001 in t test. (L and M) TT power analyses of the sarcomere organization were carried out with TTorg plugin in ImageJ. TTorg workflow of the sample images: magnification of an original image, 2D fast Fourier transformation (FFT) spectrum of the image, grey level profile of the FFT spectrum and analysis results. AU, arbitrary units. Each dot represents 1 biological repeat. Data is represented as mean ± SD.