Abstract Body: Despite causing 1 in 3 deaths worldwide, cardiovascular disease and the heart have only recently been studied in women. Contrary to previous belief, the female heart is not just a smaller replica of a male heart. Almost all heart diseases show sexual differences in risk, treatment, and symptoms. Even with these differences there is a lack of female models in animal and cellular studies. Human induced pluripotent stem cell derived cardiomyocytes (hiPSC-CMs) are a powerful human model to test baseline and stressed sex differences at the cellular level. We hypothesized that using stressors that mimic disease conditions (drugs, substrate stiffness) in multiple male and female hiPSC-CMs will result in differential sex-based responses.
We ran Traction Force Microscopy on 3 male (n = 424 cells, 3 batches) and 3 female (n = 318 cells, 3 batches) cell lines on 10 kPa polyacrylamide hydrogels. Male cells had 42% higher twitch force (p = 8.8E-6) with 25% higher contraction (p = 1.77E-5) and relaxation (p = 0.0006) velocities. However, female cells had a larger spread area (823 +/- 17.32 µm² vs. 756 +/- 21.64 µm², p = 0.0018). To validate hiPSC-CMs as a model we compared preliminary RNA-seq to publicly available Heart Cell Atlas sc/snRNA-seq data sets of primary ventricular cardiomyocytes. They had similar differentially expressed genes (DEGs) as our hiPSC-CMs. Furthermore, DEGs had significantly enriched gene sets including a 25-fold enrichment in hypertrophic cardiomyopathy (FDR = 1.6E-7), 23-fold in dilated cardiomyopathy (FDR = 1.6E-7), and 16-fold in cardiac muscle contraction (FDR = 6.3E-4). We analyzed stiffness by differentiating and culturing hiPSC-CMs on 10 kPa and 100 kPa stiffness hydrogels. Our RNA-seq analysis at day 10 and 30 after differentiation found 7000 DEGs at 10 kPa while only 556 DEGs at 100 kPa. We looked hypercontractility caused stres and performed RNA-seq on day 60 wild type and hypercontractile mutant hiPSC-CMs. The wild type was dosed with positive inotrope levosimendan to induce hypercontractility while the hypercontractile mutant was dosed with negative inotrope verapamil to lower contractility. Hypercontractility had significant upregulation of the cellular response to stress including ER stress, stress-activated MAPK cascades, stress fibers, and cardiac muscle hypertrophy in response to stress. These differences can identify possible gene targets for preventing cardiovascular disease and inform personalized medicine.