Cardioprotection by triiodothyronine following caloric restriction via long noncoding RNAs.

Severe caloric-restriction compromises thyroid hormone (TH) status, apparently to save energy and proteins for enduring stress stimulus. However, a persistent decrease in TH levels may compromise heart function. We hypothesized that supplementation of low dose active TH or targeting hypoxia-inducible factor-1-alpha, HIF-1α (a strong activator of deiodinase enzyme that degrades peripheral active THs) will prevent deterioration of cardiac performance. Adult mice were subjected to acute fasting based on institutional animal protocols with ad libitum access to water. The following groups were studied: Control mice with free access to food; severe caloric restriction fasting only group; Fasting with Triiodo-l-Thyronine (T3); Fasting with HIF-1α inhibitor (BAY). Cardiac hemodynamic and electrophysiological studies were performed and role of long noncoding RNAs were explored. Following severe caloric-restriction, we found that body weights, and heart weights to a partial extent, were decreased. Low-dose T3 treatment attenuated left ventricular hemodynamic impairment in indices of cardiac contractility and relaxation. In electrophysiology studies, fasting mice developed atrial tachyarrhythmias upon induction. This reverted to control levels following T3 treatment. There was a significant increase in atrioventricular conduction time and significant decrease in heart rate following fasting. Both these changes were attenuated following T3 treatment. Furthermore, BAY partially improved hemodynamics. Compared to the severe caloric-restriction group, both T3 and BAY reduced MALAT1 and GAS5 long noncoding RNA expression. These new findings indicate that T3 and BAY protect from cardiac decompensation secondary to acute severe caloric-restriction partly mediated by long noncoding RNAs.

Modified Low-Dose Triiodo-L-thyronine Therapy Safely Improves Function Following Myocardial Ischemia-Reperfusion Injury.

Background: We have shown that thyroid hormones (THs) are cardioprotective and can be potentially used as safe therapeutic agents for diabetic cardiomyopathy and permanent infarction. However, no reliable, clinically translatable protocol exists for TH treatment of myocardial ischemia-reperfusion (IR) injury. We hypothesized that modified low-dose triiodo-L-thyronine (T3) therapy would confer safe therapeutic benefits against IR injury. Methods: Adult female rats underwent left coronary artery ligation for 60 min or sham surgeries. At 2 months following surgery and T3 treatment (described below), the rats were subjected to functional, morphological, and molecular examination. Results: Following surgery, the rats were treated with T3 (8 µg/kg/day) or vehicle in drinking water ad libitum following IR for 2 months. Oral T3 significantly improved left ventricular (LV) contractility, relaxation, and relaxation time constant, and decreased beta-myosin heavy chain gene expression. As it takes rats ~6 h post-surgery to begin drinking water, we then investigated whether modified T3 dosing initiated immediately upon reperfusion confers additional improvement. We injected an intraperitoneal bolus of T3 (12 µg/kg) upon reperfusion, along with low-dose oral T3 (4.5 µg/kg/day) in drinking water for 2 months. Continuous T3 therapy (bolus + low-dose oral) enhanced LV contractility compared with oral T3 alone. Relaxation parameters were also improved compared to vehicle. Importantly, these were accomplished without significant increases in hypertrophy, serum free T3 levels, or blood pressure. Conclusions: This is the first study to provide a safe cardiac therapeutic window and optimized, clinically translatable treatment-monitoring protocol for myocardial IR using commercially available and inexpensive T3. Low-dose oral T3 therapy supplemented with bolus treatment initiated upon reperfusion is safer and more efficacious.