Mechanisms of Sinoatrial Node Dysfunction in Heart Failure with Preserved Ejection Fraction

Background: The ability to increase heart rate (HR) during exercise and other stressors is a key homeostatic feature of the sinoatrial node (SAN). When the physiologic HR response is blunted, chronotropic incompetence limits exercise capacity, a common problem in patients with heart failure (HF) and preserved ejection fraction (HFpEF). Despite its clinical relevance, the mechanisms of chronotropic incompetence remain unknown. Methods: Dahl salt-sensitive rats fed with a high-salt diet and C57Bl6 mice fed with high fat and an inhibitor of constitutive nitric oxide synthase (L-NAME, 2-hit) were used as models of HFpEF. Myocardial infarction was created to induce HF with reduced ejection fraction (HFrEF). Rats and mice fed with a normal diet or having a sham surgery served as respective controls. A comprehensive characterization of SAN function and chronotropic response was conducted by in vivo, ex vivo, and single-cell electrophysiological studies. RNA sequencing of SAN was performed to identify transcriptomic changes. Computational modeling of biophysically-detailed human HFpEF SAN was created. Results: Rats with phenotypically-verified HFpEF exhibited limited chronotropic response associated with intrinsic SAN dysfunction, including impaired β-adrenergic responsiveness and an alternating leading pacemaker within the SAN. Prolonged SAN recovery time and reduced SAN sensitivity to isoproterenol were confirmed in the 2-hit mouse model. Adenosine challenge unmasked conduction blocks within the SAN, which were associated with structural remodeling. Chronotropic incompetence and SAN dysfunction were also found in HFrEF rats. Single-cell studies and transcriptomic profiling revealed HFpEF-related alterations in both the "membrane clock" (ion channels) and the "Ca 2+ clock" (spontaneous Ca 2+ release events). The physiological impairments were reproduced in silico by empirically-constrained quantitative modeling of human SAN function. Conclusions: Thus, chronotropic incompetence and SAN dysfunction were seen in both models of HF. We identified that intrinsic abnormalities of SAN structure and function underlie the chronotropic response in HFpEF.