Mechanisms of Sinoatrial Node Dysfunction in Heart Failure With Preserved Ejection Fraction.
Publication Year:
2022
PubMed ID:
34905696
Funding Grants:
Public Summary:
This study explored why people with heart failure, especially those with preserved ejection fraction (HFpEF), often struggle to increase their heart rate during exercise—a condition known as chronotropic incompetence. Using rat and mouse models that mimic HFpEF and other forms of heart failure, researchers found that the heart’s natural pacemaker (the sinoatrial node, or SAN) doesn’t work properly in these conditions. The SAN showed signs of structural damage, poor responsiveness to signals that normally speed up the heart, and disrupted electrical activity. These issues were linked to changes in both ion channels and calcium handling inside SAN cells. Computer models confirmed that these changes could explain the impaired heart rate response.
Scientific Abstract:
BACKGROUND: The ability to increase heart rate during exercise and other stressors is a key homeostatic feature of the sinoatrial node (SAN). When the physiological heart rate response is blunted, chronotropic incompetence limits exercise capacity, a common problem in patients with heart failure with preserved ejection fraction (HFpEF). Despite its clinical relevance, the mechanisms of chronotropic incompetence remain unknown. METHODS: Dahl salt-sensitive rats fed a high-salt diet and C57Bl6 mice fed a high-fat diet and an inhibitor of constitutive nitric oxide synthase (Nomega-nitro-L-arginine methyl ester [L-NAME]; 2-hit) were used as models of HFpEF. Myocardial infarction was created to induce HF with reduced ejection fraction. Rats and mice fed with a normal diet or those that had 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 electrophysiologic 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 beta-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 rats with HF with reduced ejection fraction. 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 physiologic impairments were reproduced in silico by empirically-constrained quantitative modeling of human SAN function. CONCLUSIONS: 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.