Incorporation of [14C]hypoxanthine into cardiac adenine nucleotides: effect of aging and post-ischemic reperfusion

Changes in ischemic tolerance and effects of ischemic preconditioning in middle-aged rat hearts

BACKGROUND

Although both clinical and animal studies have shown that ischemic tolerance is reduced in the senescent myocardium, it has not been clarified when myocardium becomes more vulnerable to ischemia. Preconditioning protects the hearts of young adult animals of various species, but its effects are not identical in human studies. We investigated whether ischemic tolerance and the effect of preconditioning decreased in isolated hearts of middle-aged rats.

METHODS AND RESULTS

The hearts of young adult rats (12 weeks old: group Y, n = 44) and middle-aged rats (50 weeks old: group M, n = 44) were subjected to global ischemia for 15, 20, or 25 minutes followed by reperfusion. Hearts were also subjected to preconditioning and then to 20 (group Y, n = 22) or 15 (group M, n = 22) minutes of ischemia followed by reperfusion. Left ventricular developed pressure (LVDP) was decreased by 40% to 60%, and the level of ATP was decreased by 60% to 70% in group M compared with group Y. Preconditioning increased LVDP (% LVDP, 40.5% to 72.4%) and levels of high-energy phosphates (ATP, 11.8 to 14.1; creatine phosphate, 17.0 to 23.1 mumol/g dry wt) and reduced left ventricular end-diastolic pressure (LVEDP, 32.8 to 10.3 mm Hg), creatine kinase release (257 to 132 U/g dry wt), and ryanodine-sensitive sarcoplasmic reticulum Ca2+ release after ischemia in group Y. Preconditioning exerted opposite effects in group M (% LVDP, 45.9% to 15.8%; LVEDP, 21.0 to 28.5 mm Hg; ATP, 14.1 to 8.5 mumol/g dry wt; and CK release, 176 to 332 U/g dry wt). Preconditioning was associated with increases in the incidence of reperfusion-induced ventricular fibrillation (0% to 62.5%) and the rate of sarcoplasmic reticulum Ca2+ release in group M.

CONCLUSIONS

These results indicate that hearts became more vulnerable to ischemia with age and that the beneficial effects of preconditioning were reversed in middle-aged rat hearts.

Effects of trimetazidine on the calcium transport and oxidative phosphorylation of isolated rat heart mitochondria

Trimetazidine (TMZ) added in vitro to isolated cardiac mitochondria at concentrations 10-100 microM in the presence of 25-100 nM extramitochondrial Ca2+ increased Ca2+ uptake and matrix Ca2+ concentration. This effect was less evident in the presence of physiologically Na+ and Mg2+ extramitochondrial concentrations since only 100 microM TMZ was able to increase mitochondrial Ca2+ entry in the presence of 100 nM Ca2+. The drug stimulated a Ca(2+)-cooperative effect on mitochondrial Ca2+ transport, but did not modify the rate of Ca2+ egress stimulated by 10 mM NaCl. An increase in mitochondrial Ca2+ level produced by TMZ enhanced oxoglutarate dehydrogenase activity and then ATP synthesis, particularly when 50 nM extramitochondrial Ca2+ was used. These data suggest that a possible cardiac mechanism of action of TMZ at mitochondrial level could support ATP synthesis by elevating the mitochondrial Ca2+ level.

Enzymes involved in guanine monophosphate metabolism of aging chicken heart

The activities of enzymes involved in GMP metabolism were studied in the heart of aging chickens. In newborn (1-day-old) animals, GMP breakdown apparently leads to the final products of purine metabolism, as the activity of hypoxanthine-guanine phosphoribosyl-transferase (HGPRT), the salvage enzyme of GMP is not detectable. On the contrary, HGPRT shows maximal activity in young (20-day-old) chickens, when xanthine oxidase activity is very low, indicating that the metabolic flux converges on the salvage pathway. Again, maximal activity of the catabolic enzymes and a limited resort to the salvage pathway characterize GMP metabolism of adult (12-month-old) hearts. Finally, in aged (30-month-old) chickens, a reduced GMP catabolism and a greater utilization of the salvage pathway might contribute to the maintenance of the guanine nucleotide pool. In conclusion, the pattern of the activities of enzymes relating to GMP metabolism in the aging heart, compared to AMP metabolism, indicates a parallel temporal regulation of the purine pathways.

Role of reactive oxygen species in cardiovascular aging

Biochemical and structural changes occurring in the myocardium with aging are mainly resulting from the association of a general tissue atrophy with the hypertrophy of the remaining myocytes. Whilst hypertrophy seems to be a compensatory process to the loss of cardiomyocytes and to a mild systolic hypertensive condition that accompanies elderly people, atrophy should be the modification more closely related to aging 'per se.' In support to the free radical theory of aging, several signs of oxidative damage have been shown in the aged heart, such as lipofuscin accumulation, decreased phospholipid unsaturation index, greater formation of both hydrogen peroxide and 8-hydroxy-2'deoxyguanosine. As a compensatory reaction, the activities of the main oxygen-radical scavenger enzymes are stimulated in the mitochondria of aged rat heart. Endothelium-mediated vasoregulation is more susceptible to oxidative stress in aged with respect to young rats, suggesting that also the vasculature can be negatively influenced by the oxygen free radicals generated during aging. The possible primary role of oxygen free radicals in the development of myocardial atrophy is also discussed.

Pathways of adenine nucleotide metabolism: degradation and resynthesis of IMP in ageing chicken heart

The activities of enzymes involved in adenine nucleotide metabolism and the concentration of their metabolic products were studied in the hearts of chickens from birth to advanced age. In particular, in order to investigate the main mechanisms which contribute to ensure availability of adenine nucleotides during ageing of the heart, IMP concentration and the activities of enzymes involved in its turnover were studied. In newborn animals, AMP degradation, though limited in amount, was found to lead to the final products of purine metabolism. In fact, the activity of hypoxanthine phosphoribosyl-transferase (HPRT)-the salvage enzyme of IMP-was not detected. On the contrary, in young chickens, the low concentration of final products of purine metabolism, together with a remarkable activity of HPRT and a high concentration of IMP, indicates that metabolic flux converges on the salvage pathway. In adult chickens, an increase of purine catabolism was observed. This, together with an optimal concentration of endogenous adenine nucleotides, is indicative of a particularly high AMP metabolism. Finally, in chickens of advanced age, a reduced purine catabolism appeared to take place, thus contributing to the maintenance of the adenine nucleotide pool. In ageing heart, a major role of IMP turnover probably consists in the preservation of adenine nucleotides and in the recovery of high-energy phosphates.

Age-related changes of AMP breakdown in chicken heart

The activity of adenylate deaminase, adenylate phosphatase and adenosine deaminase, as well as the endogenous content of adenine nucleotides, was examined in the heart of ageing chickens. In new-born (1-day-old) and young (20-day-old) chickens, AMP degradation in the heart seems to proceed preferentially through deamination, while in adult (1-year-old) through dephosphorylation. Compared with the adult heart, a 2-year-old one exhibits a decline of AMP catabolism. The total adenine nucleotide content and the concentration of ATP are higher in adult and aged chicken hearts, than in new-born and young ones. Adaptive mechanisms might occur in the heart of ageing chickens to ensure an adequate availability of adenine nucleotides.