Effects of training on biochemical and functional properties of rodent neonatal heart

Abstract

This study was undertaken to determine biochemical and functional (in vivo) adaptations of the rodent neonatal heart in response to a training program of endurance running. Ten day-old rats were progressively trained on a treadmill (final intensity, 21 m/min, 30% grade, 1 h/day) until 75 days of age. The training program induced 14, 57, and 24% increases in relative heart mass, skeletal muscle citrate synthase activity, and whole-body maximal O2 uptake, respectively (P less than 0.05). Cardiac myosin (ATPase) and Ca2+-regulated myofibril ATPase were both reduced by approximately 15% in trained vs. sedentary animals (P less than 0.05). In the majority of trained hearts examined, the myosin isozyme profile reflected an estimated 14 +/- 3% shift toward the V3 or low ATPase isozyme. Left ventricular functional indices during submaximal exercise, derived from a fluid-filled indwelling cannula, indicated that the trained animals maintained similar left ventricular (LV) systolic pressure, LV + the time derivative of pressure, and systemic arterial mean blood pressure compared with their sedentary counterparts. These functional parameters were maintained even though the trained animals performed with lower submaximal exercise heart rate. These findings suggest that maximal exercise capacity can be enhanced in neonatal rats even though the biochemical potential for ATP degradation in the cardiac contractile system is lowered. We speculate that the trend to maintain the myosin isozyme pattern further in the direction of the V3 isozyme in the trained neonatal rat heart may reflect a means to economize cross-bridge cycling while maintaining normal levels of ventricle performance at a given submaximal work load.