Caterina Pastori

Intralymphocyte free magnesium in patients with primary aldosteronism: aldosterone and lymphocyte magnesium homeostasis.

It is known that hyperaldosteronism has been associated with magnesium deficiency, yet there are no data on the intracellular concentration of ionized magnesium ([Mg(2+)(i)]) in subjects with primary aldosteronism (PA). We measured intralymphocyte free magnesium ([Mg(2+)(i)]) and intralymphocyte free calcium ([Ca(2+)(i)]) in 16 patients with PA and 26 normotensive control subjects (NCs). [Mg(2+)(i)] and [Ca(2+)(i)] were also measured in blood lymphocytes incubated in vitro with aldosterone, according to a fluorimetric method. In subjects with PA, [Mg(2+)(i)] was significantly lower than that in NCs (mean+/-SD; PA 203+/-56 micromol/L, NCs 291+/-43 micromol/L, 95% confidence interval 57 to 119, P=0.001). In the patients, [Ca(2+)(i)] did not prove to be statistically different from that of NCs (mean+/-SD; PA 47.2+/-10.6 nmol/L, NCs 53.2+/-11 nmol/L). The lymphocytes exposed to the action of aldosterone showed a significant reduction in [Mg(2+)(i)] (n=15, NCs 271+/-28 micromol/L, aldosterone treatment 188+/-39 micromol/L, P=0.001, 95% confidence interval 57 to 108). The dose-effect curve of aldosterone on [Mg(2+)(i)] showed an EC(50) value of approximately 0.5 to 1 nmol/L aldosterone. The reduction in [Mg(2+)(i)] mediated by aldosterone is antagonized by the receptor inhibitor of aldosterone; it is inhibited by inhibitors of protein synthesis and is not measurable when the lymphocytes are incubated in an Na(+)-free medium. The data are consistent with the hypothesis that aldosterone affects the cellular homeostasis of magnesium, probably through modification of the activity of the Na(+)-Mg(2+) antiporter.

Erythrocyte Na(+)-H+ exchange activity in essential hypertensive and obese patients: role of excess body weight.

Introduction: Several authors have described increased Na + — H + exchanger activity in essential hypertension, and an increase in activity of this transport system has also been postulated in situations of hyperinsulinism, such as obesity and essential hypertension Methods: We measured Na + — H + exchanger activity in a group of 37 subjects with essential hypertension (18 obese, 19 non-obese), in a group of nine normotensive obese subjects and in a control group of 16 healthy volunteers. Plasma insulin and glucose values during an oral glucose tolerance test were evaluated, together with other variables such as plasma aldosterone, plasma renin activity and plasma potassium Results: Na+—H+ exchanger system activity did not appear to be abnormally raised in the hypertensive subjects, but was significantly increased in the normotensive obese group. Upon dividing the hypertensive subjects into two subgroups on the basis of body mass index, it was noted that, whereas the non-obese hypertensives showed Na+—H + exchanger activity patterns similar to those in controls, the obese hypertensive subjects exhibited increased activity of the transport system. Na+—H + activity correlates with body mass index and shows a significant inverse correlation with plasma potassium. No correlations were found between Na + — H + exchanger activity and the sum of plasma insulin values during the oral glucose tolerance test Conclusion: Na + — H + exchanger overactivity appears to be characteristic in overweight subjects, but would not appear to be a specific feature of essential hypertension. The increased Na + — H + exchanger activity observed in obese subjects may be postulated to be related to the hypermineralocorticoidism characteristic of this condition

Collagen I and III mRNA gene expression and cell growth potential of skin fibroblasts in patients with essential hypertension

Objectives Despite the claimed disregulation of extracellular matrix synthesis and the increased proliferation rate of different cell types in experimental models of hypertension, very few data are available on collagen synthesis and the proliferation rate of fibroblasts in essential hypertensive patients. Design We measured collagen I, collagen III, histone H3 mRNA gene expression, collagen protein concentration and thymidine incorporation in fibroblasts from 17 essential hypertensive patients (EH) and 13 healthy normotensive control subjects (NC). Methods A Northern blot analysis was performed on fibroblasts in culture obtained from skin biopsies. Collagen protein concentration and DNA synthesis were measured by means of incorporation of tritiated proline and tritiated thymidine, respectively. Results In cultivated fibroblasts from hypertensives, the expression of collagen III mRNA after addition of fetal calf serum was significantly increased in comparison with that of normotensive-derived cells. After addition of fetal calf serum, collagen protein was statistically increased in cultures from EH patients as compared to NC. In hypertensives, the expression of histone H3 mRNA as well as tritiated thymidine incorporation were both increased as compared to normotensives. Conclusions Our data suggest that cultivated fibroblasts from essential hypertensive patients are characterized by an increased expression of type III collagen mRNA and collagen protein synthesis in response to fetal serum, as compared to normotensive-derived cells. Cells from hypertensives are characterized by an increased rate of proliferation after addition of fetal serum, as ascertained by increased thymidine incorporation and increased histone H3 mRNA gene expression, as compared to normotensive-derived cells. This phenotype could be genetically determined and may have an important role in the pathogenesis of essential hypertension.

Intralymphocyte Free Magnesium in a Group of Subjects With Essential Hypertension

Despite the importance of magnesium in essential hypertension, few data are available on the ionized intracellular concentration of this ion. We therefore studied intralymphocyte free intracellular magnesium (Mgi) in 32 untreated essential hypertensive subjects and 27 normotensive control subjects by means of a fluorimetric technique based on the use of the new magnesium-sensitive dye furaptra. We also measured intralymphocyte ionized calcium (Cai) with fura 2. No statistically significant differences were found in Mgi in hypertensive compared with normotensive subjects (essential hypertensive, 0.291 +/- 0.053 mmol/L; normotensive, 0.293 +/- 0.043 [mean +/- SD]). A statistically significant inverse correlation was established between Mgi and plasma triglycerides in essential hypertensive subjects (r = -.521, P = .002). The hypertensive group was arbitrarily divided into two subgroups according to plasma triglyceride levels (> 2 [n = 10] or < 2 mmol/L [n = 22]), and Mgi proved to be significantly lower in the subgroup with high plasma triglyceride levels compared with either the subgroup with normal triglycerides (P = .009; 95% confidence interval, 0.013-0.088) or the normotensive control group as a whole (P = .03; 95% confidence interval, 0.003-0.069) (high-triglyceride hypertensive subgroup, Mgi = 0.256 +/- 0.045 mmol/L; normal-triglyceride hypertensive subgroup, Mgi = 0.307 +/- 0.049). No statistically significant differences were found in Cai in hypertensive compared with normotensive subjects (hypertensive, 53 +/- 12 nmol/L; normotensive, 54 +/- 14). We did not find statistically significant correlations between Cai and plasma triglycerides, nor did we find any differences in Cai between the subgroup of hypertensive subjects with high plasma triglyceride levels and either the subgroup of hypertensive subjects with normal triglycerides or the normotensive control group as a whole. The discrepancies between our results in lymphocytes and data relating to either erythrocytes or platelets emphasize the need for caution before the results are extrapolated from one tissue to the other. The decreased Mgi levels in the subgroup of high-triglyceride hypertensive subjects may suggest a role for magnesium in plurimetabolic syndrome.

Catecholamine-induced regulation in vitro and ex vivo of intralymphocyte ionized magnesium.

Despite the importance of the adrenergic activity and of the metabolism of magnesium in some important cardiovascular pathologies, very little is known about how intracellular ionized magnesium (Mgi2+) is regulated by catecholamines. We made an in-vitro study of the variations in the concentration of ionized magnesium in human lymphocytes using the fluorescent probe furaptra in response to different catecholamines. We also made an ex-vivo study of the changes in intracellular ionized magnesium in lymphocytes in 20 subjects with essential arterial hypertension, 10 treated with 120 mg/d of propranolol and 10 with placebo. Norepinephrine and isoproterenol significantly decrease Mgi2+ and this effect is blocked by β-blockers but not by α-blockers. The EC50 of the effect of norepinephrine is within the range of concentrations physiologically present in plasma. The substitution of extracellular sodium with choline blocks the decrease in intracellular ionized magnesium induced by norepinephrine, which leads us to suppose that the magnesium-reducing effect of catecholamines is a result of the activation of a Na+-Mg2+ exchanger. We were not able to demonstrate any change in intracellular ionized magnesium after 1 and 17 days of active treatment in essential hypertensives. The impossibility of demonstrating ex vivo the mechanism of catecholamine-mediated regulation that is evident in vitro is perhaps due to our experimental conditions or to substances which in vivo inhibit the action of the catecholamines on magnesium, such as insulin and/or glucose.

Intralymphocyte free magnesium and plasma triglycerides

To evaluate the relative effect of hypertension and plasma triglycerides on intralymphocyte magnesium we measured ionized intralymphocyte magnesium (Mg(i)) concentration by means of a fluorimetric method based on the dye Furaptra in 4 groups of subjects: 18 normotensive normotriglyceridemic controls (NTNC), 9 hypertriglyceridemic normotensive patients (HTN), 8 hypertriglyceridemic essential hypertensive patients (HTEH), 17 normotriglyceridemic essential hypertensive patients (NTEH). Hypercholesterolemic, diabetic patients and alcoholics were excluded from the study. Mg(i) was found to be statistically reduced (ANOVA test F=10.41, P=0.0001) in both HTN and HTEH (M+/- SD, HTN: 0.235 +/- 0.01, HTEH: 0.236 +/- 0.01 mmol/l) as compared to both NTNC and NTEH (M +/- SD, NTNC: 0.294 +/- 0.008, NTEH: 0.297 +/- 0.009 mmol/l). A statistically significant negative correlation was found in the population as a whole between Mg(i) and plasma triglycerides (n=52, R= -541, P=0.00004). Our data suggest that hypertriglyceridemia per se and possibly the so-called plurimetabolic syndrome is characterized by low intralymphocyte free magnesium.

Glucose-induced alterations of intracellular ionized magnesium in human lymphocytes.

The intracellular ionic content of human erythrocytes may be altered by hyperglycaemia. Despite this, very little is known about the cellular mechanisms linking glucose and cellular magnesium homeostasis. We measured intracellular ionized magnesium in human lymphocytes, by means of a fluorimetric technique, total intracellular magnesium by means of atomic absorption spectrophotometry and intracellular ATP by means of HPLC. The incubation of lymphocytes with D-glucose in the absence of insulin was followed by a significant decrease in intracellular ionized magnesium; this effect did not occur when the cells were incubated with L-glucose. The effect of glucose on intracellular ionized magnesium was blocked by amphotericin B and the EC(50) of the effect of glucose on intracellular ionized magnesium was about 5 mmol/l of glucose. The increase of intracellular ionized magnesium in cells incubated in the absence of glucose was followed by a decrease in intracellular ATP. In a Na(+)-free medium the decrease of intracellular ionized magnesium in the presence of glucose was still present and the incubation of lymphocytes with glucose did not modify total intralymphocyte magnesium. By selective permeabilization of cell membranes, we established that glucose could not increase compartmentalized intracellular ionized magnesium. Our data supports the hypothesis that glucose per se induces a substantial decrease in intracellular ionized magnesium, which is probably due to an augmented binding of intracellular ionized magnesium to cellular ATP.

In Vitro Effect of Glucose on Intralymphocyte Free Magnesium

It has been known from some time that diabetes mellitus and the plurimetabolic syndrome are characterized by a decrease of intracellular magnesium [1,2]. Despite the in vivo important role of magnesium on glucose metabolism, very little is known on the mechanisms linking glucose and magnesium intracellular homeostasis. It has been reported that in vitro incubation of non-nucleated cells (erythrocytes) in the presence of glucose was followed by a decrease of ionized magnesium as measured by a NMR technique [3]. The recent synthesis of a new fluorescent magnesium-sensitive dye has allowed the measurement of intracellular free magnesium in nucleated cells. We therefore measured lymphocythe free magnesium in nucleated cells, i.e. human lymphocytes, incubated in the presence or in the absence of glucose.

In vitro effects of cathecolamines on intracellular free magnesium in human lymphocytes

A catecholamine-induced Mg efflux has been described, nevertheless no changes of intracellular free magnesium (Mgi) following b-agonist addition have been reported in human cell types. We in vitro measured Mgi in human lymphocytes incubated with either norepinephrine (NE) or isoproterenol (IS). Peripheral blood lymphocytes from healthy donors were isolated and Mgi was measured using a method based on the dye furaptra. Lymphocytes incubated with NE (10 mmol/l) or isoproterenol (100 mmol/l) showed significantly reduced Mgi values as compared to control cells (M 6 SD, n 5 9, Mgi, control: 242 6 26 mmol/l; NE: 186 6 29 mmol/l, P 5 0.002; IS: 163 6 28 mmol/l, P 5 0.0001). The NE-induced Mgi decrease was prevented by incubating the cells with propanolol (PR), 2 mmol/l (M 6 SD, n 5 6, Mgi, control: 238 6 32 mmol/l; NE and PR: Mgi 239 6 30 mmol/l, N.S.). The cathecolamine-induced Mgi decrease is abolished by incubating the cells in a Na-free solution (M 6 SD, n 5 6, Mgi, Na 1 solution: 233 6 172 mmol/l; Na solution and NE: 172 6 42 mmol/l, p 5 0.01; Na-free solution: 538 6 89 mmol/l; Na-free solution and NE: 530 mmol/l 6 93, NS). By artificially increasing intralymphocyte AMPc, we found a Mgi decrease similar to the cathecolamine-induced effect (M 6 SD, n 5 3, control: 265 6 21 mmol/l; AMPc cells: 199 6 13 mmol/l, P , 0.01). These data are in agreement with data collected in non-human cell types and are in favour of the hypothesis that cathecolamines may regulate Mgi by means of binding to membrane b-adrenergic receptors, AMP cyclic stimulation and activation of membrane Na-Mg exchanger.

Intralymphocyte free magnesium and calcium and insulin tolerance test in a group of essential hypertensive patients

In order to assess the links which are claimed to exist between peripheral insulin resistance and intracellular magnesium and calcium concentrations, we measured free intralymphocyte magnesium (Mg(i)) and calcium (Ca(i)) concentrations as well as the rate constant of plasma glucose disappearance (K(itt)) after insulin injection (insulin tolerance test: ITT) in a group of 16 normotensive control subjects (NC) and 34 essential hypertensive subjects (EH). Mg(i) and Ca(i) were measured in triplicate by means of a fluorimetric technique based on the dyes furaptra and fura-2 respectively. K(itt) values proved significantly reduced in EH as compared to NC (M +/- SD, EH: 4.49 +/- 1.31 vs 5.28 +/- 1.19, P <0.05; 95% confidence limits: 0.23-1.5). Mg(i) and Ca(i) were not statistically different in EH as compared to NC subjects (Mg(i), NC: 266 +/- 20 micromol/l; EH: 245 +/- 50 micromol/l; Ca(i), NC: 47 +/- 9 nmol/l EH: 46 +/- 13 nmol/l). We found a statistically significant inverse correlation in the whole study group between K(itt) and body mass index (R= -0.363, P<0.01) and a statistically significant positive correlation between K(itt) and Mg(i) (R=0.347, P=0.013) was found. In a step-up multivariate regression analysis including blood pressure, plasma lipids, BMI, plasma magnesium, fasting insulin, fasting glucose, Mg(i) and Ca(i), the dependent variable K(itt) is statistically significantly correlated with body mass index and Mg(i). In a first attempt to study the relationships between insulin resistance, Mg(i) and Ca(i) in nucleated cells, the chosen index of peripheral resistance seems to be linked to intracellular free magnesium.