High-density lipoprotein delivered after myocardial infarction increases cardiac glucose uptake and function in mice.
Sarah E HeywoodAdele L RichartDarren C HenstridgeKaren AltHelen KiriazisClaire ZammitAndrew L CareyHelene L KammounLea M Durham DelbridgeMedini ReddyYi-Ching ChenXiao-Jun DuChristoph Eugen HagemeyerMark A FebbraioAndrew L SiebelBronwyn A KingwellPublished in: Science translational medicine (2018)
Protecting the heart after an acute coronary syndrome is a key therapeutic goal to support cardiac recovery and prevent progression to heart failure. A potential strategy is to target cardiac glucose metabolism at the early stages after ischemia when glycolysis is critical for myocyte survival. Building on our discovery that high-density lipoprotein (HDL) modulates skeletal muscle glucose metabolism, we now demonstrate that a single dose of reconstituted HDL (rHDL) delivered after myocardial ischemia increases cardiac glucose uptake, reduces infarct size, and improves cardiac remodeling in association with enhanced functional recovery in mice. These findings applied equally to metabolically normal and insulin-resistant mice. We further establish direct effects of HDL on cardiomyocyte glucose uptake, glycolysis, and glucose oxidation via the Akt signaling pathway within 15 min of reperfusion. These data support the use of infusible HDL preparations for management of acute coronary syndromes in the setting of primary percutaneous interventions.
Keyphrases
- high density
- left ventricular
- acute coronary syndrome
- heart failure
- signaling pathway
- skeletal muscle
- blood glucose
- type diabetes
- physical activity
- high fat diet induced
- percutaneous coronary intervention
- nitric oxide
- cell proliferation
- epithelial mesenchymal transition
- electronic health record
- high throughput
- atrial fibrillation
- coronary artery disease
- induced apoptosis
- machine learning
- angiotensin ii
- cardiac resynchronization therapy
- radiofrequency ablation
- cerebral ischemia
- deep learning
- metabolic syndrome
- brain injury
- electron transfer
- free survival