Allele-specific differences in transcriptome, miRNome, and mitochondrial function in two hypertrophic cardiomyopathy mouse models
Styliani Vakrou, … , Miguel A. Aon, M. Roselle Abraham
Styliani Vakrou, … , Miguel A. Aon, M. Roselle Abraham
Published March 22, 2018
Citation Information: JCI Insight. 2018;3(6):e94493. https://doi.org/10.1172/jci.insight.94493.
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Research Article Cardiology Cell biology

Allele-specific differences in transcriptome, miRNome, and mitochondrial function in two hypertrophic cardiomyopathy mouse models

Abstract

Hypertrophic cardiomyopathy (HCM) stems from mutations in sarcomeric proteins that elicit distinct biophysical sequelae, which in turn may yield radically different intracellular signaling and molecular pathologic profiles. These signaling events remain largely unaddressed by clinical trials that have selected patients based on clinical HCM diagnosis, irrespective of genotype. In this study, we determined how two mouse models of HCM differ, with respect to cellular/mitochondrial function and molecular biosignatures, at an early stage of disease. We show that hearts from young R92W-TnT and R403Q-αMyHC mutation–bearing mice differ in their transcriptome, miRNome, intracellular redox environment, mitochondrial antioxidant defense mechanisms, and susceptibility to mitochondrial permeability transition pore opening. Pathway analysis of mRNA-sequencing data and microRNA profiles indicate that R92W-TnT mutants exhibit a biosignature consistent with activation of profibrotic TGF-β signaling. Our results suggest that the oxidative environment and mitochondrial impairment in young R92W-TnT mice promote activation of TGF-β signaling that foreshadows a pernicious phenotype in young individuals. Of the two mutations, R92W-TnT is more likely to benefit from anti–TGF-β signaling effects conferred by angiotensin receptor blockers and may be responsive to mitochondrial antioxidant strategies in the early stage of disease. Molecular and functional profiling may therefore serve as aids to guide precision therapy for HCM.

Authors

Styliani Vakrou, Ryuya Fukunaga, D. Brian Foster, Lars Sorensen, Yamin Liu, Yufan Guan, Kirubel Woldemichael, Roberto Pineda-Reyes, Ting Liu, Jill C. Tardiff, Leslie A. Leinwand, Carlo G. Tocchetti, Theodore P. Abraham, Brian O’Rourke, Miguel A. Aon, M. Roselle Abraham

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Figure 9

Mitochondrial studies.

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Mitochondrial studies. Respirometry: Mitochondria were freshly isolated ...
Respirometry: Mitochondria were freshly isolated from mutant and littermate control hearts, in parallel. An XF96 analyzer was used to measure function of complexes I, II, and IV at 37°C. Oxygen consumption rate (OCR) was measured in state 4 (no ADP) and/or state 3 (with 1 mM ADP) using substrates for the electron transport chain (ETC) complex I (5 mM glutamate/malate), complex II (5 mM succinate, in the presence of rotenone, an ETC-complex I inhibitor), and complex IV (0.5 mM TMPD [N,N,N,N′-tetramethyl-p-phenylenediamine]). Coupling of O2 consumption to ADP phosphorylation was estimated by computing the respiratory control ratio (RCR; state 3/state 4 respiration). (A) Complex I respiration: MyHC mutants had higher state 3 respiration and higher RCR, whereas TnT mutants had higher state 4 respiration and lower RCR, when compared with respective littermate controls. (B) Complex II respiration: MyHC mutants had lower state 4 respiration, but complex II RCR of MyHC mutants was similar to that of controls. No difference was noted between TnT mutants/controls. (C) Complex IV respiration in both mutants was similar to respective littermate controls. Data are presented as mean ± SEM. n = 15 experiments from 5 mitochondrial preparations/10 mice in each group for control-M/MyHC, and n = 21 experiments from 7 mitochondrial preparations/14 mice in each group for control-T/TnT. *P < 0.05, **P < 0.001, using 2-sided unpaired Student’s t test and Bonferroni’s correction for multiple testing. (D) Mitochondrial number: Total DNA was isolated from whole hearts for qRT-PCR of COX-1 (mitochondrial gene) and GAPDH (nuclear gene). Mitochondrial DNA (Mito-DNA) copy number is presented as relative copy number of COX-I/GAPDH. Copy numbers in each mutant were normalized to copy numbers in respective littermate controls. MyHC hearts had similar mitochondrial DNA copy number, whereas TnT mutants had lower mitochondrial DNA copy number, when compared with respective littermate controls. Data are presented as mean ± SD. n = 8 hearts in each group. *P < 0.05, **P < 0.01, using 2-sided unpaired Student’s t test.