Modulation of myosin isoenzyme populations and activities of monoamine oxidase and phenylethanolamine-N-methyltransferase in pressure loaded and normal rat heart by swimming exercise and stress arising from electrostimulation in pairs

Abstract

The question of whether the effects of physical exercise on the heart of 15-weeks normotensive and hypertensive rats can be modulated by additional stressors was studied. Intermittent swimming (33–35 °C water, maximum 2 × 1.5 h/day, 2–6 weeks) was employed as a model of exercise. Electrostimulation of rats in pairs (maximum 2 × 1.5 h/day, 6 weeks) served as a model leading predominantly to stress. When the above procedures were combined, electrostimulation in pairs was performed in one session and was followed up by swimming. The myosin isoenzyme population was used as a marker of changes in contractile performance of myofibrils. Activities of the catecholamine-degrading enzyme monoamine oxidase (MAO) and the adrenaline-synthesizing enzyme phenylethanolamine-N-methyl transferase (PNMT) served to monitor chronic alterations of catecholamine turnover in myocardium. Redistribution in favour of VM-1 (ventricular myosin isoenzyme 1) occurred as early as 2 weeks after the onset of intermittent swimming and was observed under several experimental conditions. The redirection of genetic expression of the isoenzymes was not linked to the presence of an increased ratio of right to left ventricular weight, most probably arising from intermittent hypoxia during drownproofing. The myosin isoenzyme population of swimming spontaneously hypertensive rats (SHR) resembled that of sedentary Wistar rats. The enzyme activities of MAO and PNMT were both significantly reduced following 6 weeks intermittent swimming in Wistar rats and SHR. This can most probably be attributed to the exercise component of swimming which, on average, led to reduced catecholamine turnover in heart. Electrostimulation of rats in pairs for 6 weeks, which resulted in aggressivity and aggressions, did not alter the myosin isoenzyme population in Wistar rats; in SHR, it further augmented the proportion of VM-3 (ventricular myosin isoenzyme 3), which had already increased in the sedentary state. Furthermore, electrostimulation increased PNMT activity, but did not affect MAO activity. Electrostimulation in pairs, followed by swimming, altered the myosin isoenzyme population in the same way as did swimming alone. However, the activities of PNMT and MAO seemed to be governed by the routine involving stress and not by the exercise routine. This demonstrates that stressors supplementing exercise can decisively modify or even prevent reactions of the organism in response to exercise. With regards to the functional consequences for contractile performance, it can be concluded that swimming exercise applied in addition to stressors can induce transformation of myocardium towards a fast-type muscle which would appear to be better adapted for such demands as high heart rate encountered during stress.