Abstract
Heart disease remains the number one killer of women in the US. Nonetheless, studies in women and female animal models continue to be underrepresented in cardiac research. Hypertrophic cardiomyopathy (HCM), the most commonly inherited cardiac disorder, has been tied to sarcomeric protein variants in both sexes. Among the susceptible genes, TNNC1—encoding cardiac troponin C (cTnC)—causes a substantial HCM phenotype in mice. Mice bearing an HCM‐associated cTnC‐A8V point mutation exhibited a significant decrease in stroke volume and left ventricular diameter and volume. Importantly, isovolumetric contraction time was significantly higher for female HCM mice. We utilized a transcriptomic approach to investigate the basis underlying the sexual dimorphism observed in the cardiac physiology of adult male and female HCM mice. RNA sequencing revealed several altered canonical pathways within the HCM mice versus WT groups including an increase in eukaryotic initiation factor 2 signaling, integrin‐linked kinase signaling, actin nucleation by actin‐related protein‐Wiskott‐Aldrich syndrome family protein complex, regulation of actin‐based motility by Rho kinase, vitamin D receptor/retinoid X receptor activation, and glutathione redox reaction pathways. In contrast, valine degradation, tricarboxylic acid cycle II, methionine degradation, and inositol phosphate compound pathways were notably down‐regulated in HCM mice. These down‐regulated pathways may be reduced in response to altered energetics in the hypertrophied hearts and may represent conservation of energy as the heart is compensating to meet increased contractile demands. HCM male versus female mice followed similar trends of the canonical pathways altered between HCM and WT. In addition, seven of the differentially expressed genes in both WT and HCM male versus female comparisons swapped directions in fold‐change between the sexes. These findings suggest a sexually‐dimorphic HCM phenotype due to a sarcomeric mutation and pinpoint several key targetable pathways and genes that may provide the means to alleviate the more severe decline in female cardiac function.
Highlights
Cardiac disease has remained a leading cause of death worldwide for the past 15 years
Our study further aims to pinpoint common and unique pathways associated with sex differences in the development of cardiac hypertrophy due to altered Ca2+ binding properties of cardiac troponin C (cTnC)
Several studies have delved into the changes in gene expression of genes normally expressed at low levels that are suddenly activated as the heart hypertrophies
Summary
Cardiac disease has remained a leading cause of death worldwide for the past 15 years A prior study on mice with an HCM-associated mutation in cTnT has shown sex-based differences in their capacity to respond to stress In these studies, adrenergic agonists caused sudden cardiac death in all male mice studied, with no effect in female mice with mutated cTnT (Maass, Ikeda, Oberdorf-Maass, Maier, & Leinwand, 2004). Based on our physiological results in mice of different sexes, we wanted to determine whether some effects of a specific mutation in cTnC that cause HCM may be exacerbated in women. Our study further aims to pinpoint common and unique pathways associated with sex differences in the development of cardiac hypertrophy due to altered Ca2+ binding properties of cTnC These investigations afford a more thorough understanding of sex-dependent vulnerabilities, and provide pathways to consider as possible targets for treating cardiomyopathic disease
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