Inhibition of connexin 43 in cardiac muscle during intense physical exercise.

Endurance training is accompanied by important adaptations in both cardiovascular and autonomic nervous systems. Previous works have shown that the main component of gap junctions in the ventricular myocardium (connexin 43 (Cx43) can be regulated by adrenergic stimulus. On the other hand, training raises vagal and decreases sympathetic tone, while augmenting myocardial sensitivity to sympathetic stimulation during exercise. We therefore evaluated the regulation of Cx43 expression by sympathetic tone during exercise in trained and sedentary mice. Training induced an increase in the protein level of Cx43 by 45-70% under resting conditions. The expression of Cx43 was inhibited in trained but not in untrained mice in response to a 60 min exercise bout. Normal basal expression was restored after 60 min of resting. Cx43 reached a minimum that was not different from basal expression in untrained mice. In accordance, electrocardiography and action potential analysis did not reveal major electrophysiological implications for the drop in Cx43 abundance in trained-exercise mice. We prevented Cx43 inhibition using propranolol, and observed increased basal mRNA levels of ß-adrenergic receptors without significant changes in the ratio ß1 to ß2. In conclusion, we showed that Cx43 expression is transiently inhibited by ß-adrenergic stimulus in trained mice during acute exercise.

Changes in intracellular pH caused by high K in normal and acidified frog muscle. Relation to metabolic changes.

We examined the effect of depolarization on intracellular pH (pHi) of normal (pHi approximately 7.37) and acidified (pHi 5.90-6.70) frog semitendinosus muscle using microelectrodes. A small bundle was superfused with a Na(+)-free buffered solution (10 mM HEPES, 100% O2, pH 7.35) containing either 2.5 or 25 mM K+. An NH4Cl prepulse was used to lower pHi. At normal pHi, depolarization usually produced a slight (0.04) alkalinization, followed by a fall in pHi of approximately 0.2. In contrast, in all 25 acidified bundles pHi rose by 0.1-0.7. The rise was greater the lower the initial pHi. It could be imitated by caffeine and blocked by tetracaine and thus was, most likely, initiated by release of calcium. We ascribed the alkalinization to hydrolysis of phosphocreatine (PCr); 2,4-dinitrofluorobenzene abolished it. Biochemical analysis on fibers at the peak of alkalinization showed PCr to be reduced by one-half, while PCr in normal fibers that had been depolarized for the same period (4-6 min) showed no change. We postulated that low pHi slows glycolysis with its associated ATP formation by reducing glycogenolysis and particularly by reducing conversion of fructose-6-phosphate to fructose-1,6-diphosphate through inhibition of phosphofructokinase (PFK), an enzyme which is known to be highly pH sensitive. Thus PCr hydrolysis would be required to replace much of the hydrolyzed ATP. This postulated effect on PFK is in agreement with the finding that glucose-6-phosphate (in near-equilibrium with fructose-6-phosphate) was increased nearly fivefold in the depolarized acid fibers, but not in the depolarized normal fibers. However, fructose-1,6-diphosphate also increased significantly; 3-phosphoglycerate was not affected. This suggests an additional acid-induced bottleneck between the latter two substrates. We measured the intrinsic buffering power, beta, of frog semitendinosus muscle with small pulses of NH4Cl. It was found to vary with pHi according to beta = 144.6 - 17.2 (pHi).

Natriuretic response to saline load in one-kidney/one-clip hypertensive rats.

Parameters of renal function were studied in conscious and anesthetized one-kidney (1K) and one-kidney/one-clip (1K-1C) rats. Effective renal blood flow (ERBF) was significantly lower in anesthetized 1K-1C rats than in conscious ones (12.1 +/- 1.6 vs. 16.4 +/- 1.2 ml/min). Renal function was evaluated in two-kidney (2K), 1K and 1K-1C unanesthetized rats. ERBF was lower in 1K and 1K-1C animals than in 2K rats. Glomerular filtration rate (GFR) and urinary sodium excretion (UNa.V) were not affected by uninephrectomy with or without clipping the renal artery. In 1K-1C rats, mean arterial pressure (MAP) increased from 100 +/- 2 to 140 +/- 1 mm Hg. Subsequently, the renal ability of unanesthetized rats to handle Na was studied by a sustained extracellular fluid volume expansion (EFVE) in all groups. During EFVE, MAP remained unchanged in the 2K and 1K groups and decreased significantly in the 1K-1C group, ERBF did not change and GFR increased to the same extent in all groups. The increase in UNa.V was 40% higher in 2K than in 1K or 1K-1C rats. These findings indicate that the relatively smaller natriuretic response to a saline load of 1K rats with or without a clip in the renal artery, as compared with 2K rats, could be ascribed to renal mass reduction. Finally, the study shows the advantage of performing studies of renal function in hypertension in conscious rather than anesthetized rats.

Amiloride prevents the metabolic acidosis of a KCl load in nephrectomized rats.

1. Counter movements of K+ and H+ across cell membranes were studied in nephrectomized KCl-loaded rats. In one group of animals, the movements of K+ and H+ were determined during and after a KCl load, and in another group, amiloride was used in order to evaluate Na+ participation in K+/H+ exchange. 2. After a KCl load at constant PCO2, 79% of infused K+ left the inulin space, half of which was in exchange for H+. As a result, blood pH fell from 7.40 +/- 0.01 to 7.30 +/- 0.01 (mean +/- SEM; P less than 0.001). 3. During KCl infusion, the K+/H+ exchange ratio varied between 1.3 and 6.8, showing that the coupling ratio is not fixed. 4. Amiloride did not change blood pH and plasma [K+], but prevented the metabolic acidosis produced by the KCl load without affecting K+ entry into the non-inulin space. Therefore, K+ and H+ movements became completely dissociated. 5. The results indicate that KCl activates an amiloride-sensitive H+ extrusion from the cells. This finding is compatible with the view that Na+/H+ exchange participates in the metabolic acidosis produced by a KCl load.