Objective: We recently discovered that activation of oxidized soluble guanylate cyclase with ataciguat (ATA) slows valve calcification and dysfunction in mice and humans with moderate aortic valve stenosis (AVS). We examined if ATA would attenuate multiple mechanisms contributing to AVS and end organ dysfunction associated with AVS, and hypothesized: 1) ATA attenuates osteogenic signaling in valve tissue from mice with AVS, thereby attenuating calcification and valve dysfunction, 2) AVS increases rates of sudden cardiac death in our model, and 3) treatment with ATA prevents QT prolongation and deleterious electrical remodeling commonly observed in AVS. Methods: Functional, molecular, and histopathological changes in valve tissue along with QT interval duration were measured in 3 independent groups of mice: non-AVS, AVS, and AVS+ATA (WD for 6 months then WD+ATA for 3 months (AVS+ATA). We gave 5 mg/kg isoproterenol (ISO, i.p.) to ldlr -/- /ApoB100-only mice fed normal chow (non-AVS) or western diet (AVS, fed WD for 9 months) to assess risk for malignant arrhythmias. Retrospective analysis of QT interval was also done on data from our recent Phase 1 clinical trial. Results: AVS+ATA mice had less valve calcification and slower progression of valve dysfunction through attenuation of canonical BMP signaling and reductions in Runx2 and SPP1 compared to AVS mice. QT prolongation was evident in AVS mice, and was significantly attenuated by treatment with ATA (p= 0.001) and coarsely associated with severity of valvular or ventricular function. While all non-AVS mice survived for 24 hours after ISO, 40% of mice with AVS reached a moribund equivalent within 4 hours. Retrospective analyses also showed reductions in QT interval duration in patients treated with 200 mg/day ATA for 14 days (p < 0.05). Conclusion: Collectively, this is the first study reporting increased propensity for malignant arrhythmias in our mouse model of AVS, QT prolongation as a likely underlying mechanism, and restoration of cardiac conduction dynamics with targeted restoration of nitric oxide signaling. Future studies focused on the role of sGC in the evolution and prevention of AVS and consequent deleterious electrical remodeling/malignant arrhythmia risk is warranted.