Erythrocyte lithium transport changes induced by deoxycorticosterone acetate treatment in pigs.

Ouabain-insensitive lithium efflux from lithium-loaded pig erythrocytes has sodium-dependent and sodium-independent components. Lithium effluxes into sodium (total efflux) and sodium-free (leak) media, sodium-dependent lithium efflux, defined as the difference between total and leak fluxes, and changes in red cell cation and water contents as well as blood pressure were assessed serially for 3 weeks in pigs implanted with Silastic strips impregnated with deoxycorticosterone acetate or with Silastic alone and maintained on a high salt diet (200 mEq/day). Significant differences developed between the groups in blood pressure, red cell sodium content, red cell water content, leak flux, and sodium-dependent lithium efflux (maximal difference: 648 +/- 60 vs 256 +/- 81 mumoles of lithium per liter of cells per hour, deoxycorticosterone acetate vs controls; p less than 0.01). Increased sodium-dependent lithium efflux paralleled a decrease of the diffusional leak component of lithium efflux; total lithium efflux was unchanged. Deoxycorticosterone acetate hypertension in pigs is a useful model in which to study factors modulating erythrocyte cation content and lithium transport in vivo. Changes in lithium transport characterized in red blood cells in this form of experimental hypertension may reflect generalized membrane phenomena.

Racial differences in erythrocyte cation transport.

Erythrocyte contents and ouabain-insensitive transport pathways were measured in 120 white and black normotensives and hypertensives. Mean maximal sodium-stimulated lithium-sodium countertransport rate was higher in white hypertensives than in white normotensives, and countertransport was significantly positively correlated with mean arterial pressure in whites. Values similar to those in white normotensives were found in both black normotensives and hypertensives, and countertransport was not significantly correlated with blood pressure in blacks. The rate constant for passive lithium efflux was greater in whites as compared to blacks, and the difference was not related to blood pressure level or sex. Ouabain-insensitive, furosemide-sensitive sodium and potassium effluxes were not found to be altered in hypertension. Furosemide-sensitive sodium efflux rate was lower in blacks but furosemide-sensitive potassium efflux was not similarly depressed. While white subjects demonstrated a close correlation between sodium and potassium effluxes, blacks did not. Further study of these differences in the cellular metabolism of sodium and potassium may provide clues to the pathogenesis of racial dissimilarities in total body sodium handling.

Effects of lovastatin treatment on red blood cell and platelet cation transport.

Hypercholesterolemia frequently accompanies hypertension, and it has been suggested that by affecting membrane lipid composition, hypercholesterolemia may cause or accentuate abnormalities in several red blood cell transports associated with hypertension. Such an effect might obfuscate the relation of membrane markers to hypertension and decrease their usefulness in genetic studies of the heritable basis of hypertension. To determine if changing plasma lipids affects membrane transport, we studied the effects of the cholesterol-lowering agent lovastatin on red blood cell lithium-sodium countertransport and sodium-potassium-chloride cotransport, red blood cell sodium and water content, and platelet amiloride-sensitive volume responsiveness to cytoplasmic acidification, an indirect measure of sodium-proton exchange that has been proposed as a new membrane marker for hypertension. In a 24-week, placebo-controlled, double-blinded, randomized trial, lovastatin significantly lowered total and low density lipoprotein cholesterol and raised high density lipoprotein cholesterol. Red blood cell lithium-sodium countertransport and sodium-potassium-chloride cotransport were not significantly altered. Red blood cell sodium content decreased significantly in the lovastatin-treated group, probably as a result of an increase in red blood cell sodium-potassium pump activity. Platelet amiloride-sensitive responses to cytoplasmic acidification were significantly depressed by lovastatin treatment, suggesting that lowering plasma cholesterol may suppress platelet sodium-proton exchange. It has been hypothesized that the hyperlipidemias frequently observed in essential hypertensive patients may alter membrane lipid composition and affect membrane cation transport activities.(ABSTRACT TRUNCATED AT 250 WORDS)

Red blood cell Li+-Na+ countertransport, Na+-K+ cotransport, and the hemodynamics of hypertension.

Red blood cell Li+-Na+ countertransport and Na+-K+ cotransport activities, home blood pressure, invasive systemic hemodynamics, and limb venous compliance were measured in 65 white men (23 normotensive, 22 borderline hypertensive, and 20 mild essential hypertensive subjects). Li+-Na+ countertransport activity was positively and significantly correlated with subject-determined home systolic blood pressure (r = 0.31, p less than 0.02) and with directly measured systolic (r = 0.29, p less than 0.02) and diastolic (r = 0.27, p less than 0.03) blood pressures in the hemodynamic laboratory, independent of potential confounding variables. Analysis of the hemodynamic determinants of blood pressure revealed a significant positive correlation of countertransport with vascular resistance (r = 0.30, p less than 0.02) but not with cardiac output or cardiac index. High red blood cell Na+-K+ cotransport activity was not independently associated with hypertension or with a characteristic hemodynamic pattern but was related to decreased venous compliance. Red blood cell Li+-Na+ countertransport deserves further study as a marker for the genetic substrate of human essential hypertension. Red cell Na+-K+ cotransport may be altered secondarily by factors related to high blood pressure and seems to be a valid marker for abnormalities of the venous system in hypertension.

Platelet volume responses to cytoplasmic acidification in essential hypertension.

Using a Coulter-based cell sizing method, we have previously demonstrated that, in response to cytoplasmic acidification by 140 mmol/l sodium propionate, both the mean initial rate of amiloride-sensitive platelet volume swelling and the net volume change achieved at steady-state are greater in essential hypertensives than in normotensives. In the present study, we extend this observation by showing that, in response to graded propionate exposure (56-140 mmol/l), steady-state amiloride-sensitive volume responsiveness (as percentage increase over baseline) increases linearly, and the mean slope of the line relating amiloride-sensitive volume change and propionate concentration is increased in hypertensives (0.40 +/- 0.02 versus 0.32 +/- 0.02% per mmol/l propionate, P less than 0.003). In 56 mmol/l propionate, average amiloride-sensitive platelet swelling is significantly less in hypertensives than in normotensives (7.6 +/- 0.8 versus 11.1 +/- 0.9%, P less than 0.05), but in 140 mmol/l propionate, swelling is significantly increased in hypertensives (40.8 +/- 1.7 versus 36.2 +/- 1.5%, P less than 0.05). Since platelet intracellular calcium concentration is elevated in some hypertensives and Ca2+ is known to stimulate Na(+)-H+ antiport, the transport system that is the primary determinant of amiloride-sensitive cell swelling during propionate incubation, we studied the effects of the Ca2+ ionophore, ionomycin, on volume regulation. In both normotensives and hypertensives, ionomycin (2 x 10(-10 to 2 x 10(-7) mol/l) causes dose-related increases in amiloride-sensitive platelet swelling during graded propionate exposure.(ABSTRACT TRUNCATED AT 250 WORDS)

The antihypertensive effect of calorie restriction in obese adolescents: dissociation of effects on erythrocyte countertransport and cotransport.

Measures of maximal rates of lithium-sodium countertransport and frusemide-sensitive sodium and potassium cotransport have been proposed as biochemical markers for human essential hypertension. The stability of these functions over time within the same individuals has led to the suggestion that maximal transport capacities are genetically determined. The present study confirms the reproducibility of functional assays of countertransport and cotransport in human erythrocytes after overnight storage and over a six-month period in normal volunteers and provides estimates of the magnitude of technical error for each assay. A long-term dietary intervention study in a group of obese adolescents demonstrated marked increases in erythrocyte sodium levels and maximal frusemide-sensitive sodium and potassium fluxes but no changes in cell potassium or water and no effect on lithium-sodium countertransport. A correlation between the decrease in percentage of body fat and the increase in cell sodium content suggests a link between the metabolic effects of dieting and control of erythrocyte cation handling. Although the mechanism linking dietary calorie restriction and changes in erythrocyte cation metabolism is unknown, evaluation of body weight, and especially recent weight loss, is important in studies of erythrocyte transport. Conclusions regarding genetic contributions to the activities of lithium-sodium countertransport and sodium-potassium cotransport systems will be strengthened by clarification of environmental regulators.

Racial differences in bumetanide-sensitive cotransport and N-ethylmaleimide-stimulated potassium efflux.

Racial differences in erythrocyte potassium effluxes mediated by two loop-diuretic sensitive modes of cotransport were compared. In red cells loaded to contain approximately equimolar amounts of sodium and potassium, black subjects had lower bumetanide-sensitive sodium-dependent net potassium effluxes as compared to whites. In fresh, washed erythrocytes pretreated with N-ethylmaleimide (NEM), maximal net potassium efflux was greater in blacks than in whites. NEM-stimulated potassium efflux was partially inhibited by bumetanide but only at very high concentrations. The quantitative differences in these two modes of potassium efflux suggest that NEM-stimulated potassium efflux is not an altered mode of sodium-dependent potassium efflux.