Cardiomyocyte cytosolic nuclear self-DNA contributes to the pathogenesis of desmoplakin cardiomyopathy
Weiyue Wang, Benjamin Cathcart, Quoc D. Nguyen, Loi Q. Lao, Amelia Bryans, Sara E. Coleman, Leila Rouhi, Priyatansh Gurha, Ali J. Marian
Weiyue Wang, Benjamin Cathcart, Quoc D. Nguyen, Loi Q. Lao, Amelia Bryans, Sara E. Coleman, Leila Rouhi, Priyatansh Gurha, Ali J. Marian
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Research Article Cardiology Genetics

Cardiomyocyte cytosolic nuclear self-DNA contributes to the pathogenesis of desmoplakin cardiomyopathy

Abstract

Hereditary cardiomyopathies are the prototypic forms of heart failure and major causes of sudden cardiac death. The genome in cardiomyopathies is exposed to internal stressors, which damage the DNA and activate the DNA damage response (DDR) pathways. We set out to determine whether the DDR pathways were activated and pathogenic in an established mouse model of desmoplakin (DSP) cardiomyopathy generated upon deletion of the Dsp gene in cardiomyocytes (Myh6-MerCreMerTam Dspfl/fl; Myh6-McmTam Dspfl/fl). The mice exhibited premature death, cardiac dysfunction, myocardial cell death, fibrosis, and increased expression levels of the pro-inflammatory cytokines, consistent with the phenotype of human DSP cardiomyopathy. Cytosolic nuclear self-DNA (nDNA) and mitochondrial DNA (mtDNA) were increased in cardiomyocyte cytosol in the Myh6-McmTam Dspfl/fl mice. Likewise, the DDR pathway proteins, including the cyclic GMP-AMP synthase (CGAS)/stimulator of interferon response 1, were upregulated, as were the transcript levels of interferon response factor 3 and the NF-κB target genes. Deletion of the Mb21d1 gene encoding CGAS in the Myh6-McmTam Dspfl/fl mice prolonged survival, improved cardiac function, attenuated fibrosis, and reduced cell death. Thus, cytosolic nDNA and mtDNA are increased and the DDR pathways are activated and pathogenic in a mouse model of DSP cardiomyopathy, whereas genetic blockade of CGAS is salubrious.

Authors

Weiyue Wang, Benjamin Cathcart, Quoc D. Nguyen, Loi Q. Lao, Amelia Bryans, Sara E. Coleman, Leila Rouhi, Priyatansh Gurha, Ali J. Marian

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Figure 13

Effects of deletion of Mb21d1 gene on myocardial fibrosis.

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Effects of deletion of Mb21d1 gene on myocardial fibrosis. (A) Picrosiri...
(A) Picrosirius-stained thin myocardial sections in the experimental groups. Lower (the upper row) and higher (middle row) magnification sections are shown. The red color indicates fibrosis. (B) IF thin myocardial sections stained with an anti-COL1A1 antibody. The red areas are COL1A1-stained areas representing myocardial fibrosis. (C) Dot blots showing quantitative CVF calculated as the percentage of myocardium stained positive for Picrosirius red. Approximately 10 to 12 fields (20× original magnification) per section and 6 to 10 sections per heart were quantified. Each dot represents the mean value of CVF in 1 mouse. The mean values were compared by ANOVA and the differences between the 2 groups by pairwise Tukey’s test. Only P values < 0.05 are shown. (D) Dot blots showing quantitative COL1A1-stained areas (red), which were calculated and analyzed as described in C. (E) Immunoblots represent the expression of latent (likely) and active TGF-β in the control and experimental groups. Expression of VCL protein is used as a control for loading conditions. (F) Dot plots represent quantitative levels of what seems to be latent TGF-β protein levels in the cardiac protein extracts in the experimental groups. Data were compared as described in C. (G) Dot plots represent quantitative levels of the active mature TGF-β protein in the experimental groups. Data were compared as described in C.