Homozygous G650del nexilin variant causes cardiomyopathy in mice
Canzhao Liu, Simone Spinozzi, Wei Feng, Ze’e Chen, Lunfeng Zhang, Siting Zhu, Tongbin Wu, Xi Fang, Kunfu Ouyang, Sylvia M. Evans, Ju Chen
Canzhao Liu, Simone Spinozzi, Wei Feng, Ze’e Chen, Lunfeng Zhang, Siting Zhu, Tongbin Wu, Xi Fang, Kunfu Ouyang, Sylvia M. Evans, Ju Chen
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Research Article Cardiology Genetics

Homozygous G650del nexilin variant causes cardiomyopathy in mice

Abstract

Nexilin (NEXN) was recently identified as a component of the junctional membrane complex required for development and maintenance of cardiac T-tubules. Loss of Nexn in mice leads to a rapidly progressive dilated cardiomyopathy (DCM) and premature death. A 3 bp deletion (1948–1950del) leading to loss of the glycine in position 650 (G650del) is classified as a variant of uncertain significance in humans and may function as an intermediate risk allele. To determine the effect of the G650del variant on cardiac structure and function, we generated a G645del-knockin (G645del is equivalent to human G650del) mouse model. Homozygous G645del mice express about 30% of the Nexn expressed by WT controls and exhibited a progressive DCM characterized by reduced T-tubule formation, with disorganization of the transverse-axial tubular system. On the other hand, heterozygous Nexn global KO mice and genetically engineered mice encoding a truncated Nexn missing the first N-terminal actin-binding domain exhibited normal cardiac function, despite expressing only 50% and 20% of the Nexn, respectively, expressed by WT controls, suggesting that not only quantity but also quality of Nexn is necessary for a proper function. These findings demonstrated that Nexn G645 is crucial for Nexn’s function in tubular system organization and normal cardiac function.

Authors

Canzhao Liu, Simone Spinozzi, Wei Feng, Ze’e Chen, Lunfeng Zhang, Siting Zhu, Tongbin Wu, Xi Fang, Kunfu Ouyang, Sylvia M. Evans, Ju Chen

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Figure 4

NexnG645Δ/G645Δ mice have a disorganized transverse-axial tubule system.

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NexnG645Δ/G645Δ mice have a disorganized transverse-axial tubule system...
(A and D) Representative live confocal images of cardiomyocytes stained with Di-8 Anepps isolated from NexnWT/WT and NexnG645Δ/G645Δ mice at P10 (n = 3). Scale bar: 10 μm. (B and E) Relative skeletonized images, oriented in a x-y fashion: T-tubules represent the 90° component and axial tubules the 0° component. (C and F) Directionality histograms derived from Fourier transforms of all the analyzed cardiomyocytes images. (G) Comparison between directionality histograms from C and F. (H) NexnWT/WT and NexnG645Δ/G645Δ comparison of area under curve from 90° and 0° tubular Fourier components Gaussian distribution. (I) Distribution of cardiomyocytes with a formed transverse-axial tubule system (A-tubules + T-tubules) and immature cardiomyocytes presenting only with a longitudinal tubular component (A-tubules only) in NexnWT/WT and NexnG645Δ/G645Δ mice at P10. *P < 0.05. Data represent mean ± SEM; differences between groups were analyzed by 2-tailed Student’s t test.