Transient AMPK activation by nutrient stress of high fat diet preserves cardiac electrophysiological stability and protects against arrhythmias
Listed in
This article is not in any list yet, why not save it to one of your lists.Abstract
Sudden cardiac death (SCD) is a major complication of obesity, yet it remains unclear whether early metabolic stress, prior to the onset of overt obesity or structural remodeling, can independently promote arrhythmias. In vitro studies suggest that fatty acids can allosterically stimulate AMP-activated protein kinase (AMPK), a key metabolic sensor known to preserve myocardial viability and mitochondrial function following ischemia-reperfusion (I/R) injury. We hypothesized that AMPK signaling critically modulates the electrophysiological (EP) response to high-fat diet (HFD)-induced metabolic stress.
Methods
To test this, wild-type (WT) and AMPK kinase-dead (AMPK-KD) mice were subjected to an 8-week HFD regimen beginning at 4 weeks of age. Controls remained on normal diet (ND) for the same duration. Arrhythmia susceptibility was assessed ex vivo using rapid pacing and I/R challenge protocols. Changes in the EP substrate were defined by high-resolution optical action potential mapping. Underlying mechanisms were probed using western blotting, confocal and transmission electron microscopy.
Results
HFD-fed wild-type (WT) hearts did not display increased arrhythmia susceptibility in response to either burst pacing or I/R challenge. On the contrary, they exhibited a paradoxical enhancement in post-ischemic EP recovery compared to ND-fed controls. This improvement was associated with increased phosphorylation of canonical AMPK targets, including acetyl-CoA carboxylase (ACC) and raptor, consistent with the activation of a cardioprotective metabolic program. In sharp contrast, AMPK-deficient (AMPK-KD) hearts demonstrated heightened vulnerability to inducible ventricular tachycardia (VT), irrespective of diet. Conduction slowing emerged as an early EP abnormality in these hearts and served as the initial substrate (or ‘first hit’) that promoted their increased incidence of non-sustained VT. Notably, this conduction impairment arose in conjunction with an increase (rather than decrease) in Cx43 and Nav1.5 protein expression. Mechanistically, defective conduction in AMPK-KD hearts was linked to impaired autophagic degradation of intercalated disc proteins resulting from reduced phosphorylation of ULK1, a downstream effector of AMPK. Consequently, unphosphorylated Cx43 accumulated at the intercalated disc, likely replacing phosphorylated isoforms (p-Cx43). In addition, AMPK-KD hearts exhibited swollen, fragmented mitochondria and reduced levels of mitochondrial fusion proteins. Upon HFD challenge, this vulnerable mitochondrial substrate generated excessive reactive oxygen species (ROS) coinciding with accelerated repolarization. Together, impaired conduction and action potential shortening promoted VT sustenance in HFD-fed AMPK-deficient hearts.
Conclusions
Our findings identify AMPK as a key metabolic regulator that integrates redox balance, mitochondrial integrity, and protein homeostasis to preserve cardiac excitability during early nutrient overload. Loss of AMPK signaling, as occurs with aging and advanced metabolic disease, may therefore represent a pivotal mechanism linking HFD to increased SCD risk.
