Effect of urea and osmotic cell shrinkage on Ca2+ entry and contraction of vascular smooth muscle cells.

The present study was performed to elucidate the effects of urea on vascular smooth muscle cells (SMC). Addition of urea (20, 50, 100 mM) to physiological salt solution blunted the vasoconstrictory effect of phenylephrine (by 17, 25 and 30%, respectively) and of an increased extracellular K+ concentration (by 7, 14 and 19%, respectively) without affecting the basal tone of rabbit arterial rings. According to Fura-2 fluorescence in cultured SMC (A7r5), urea had no effect on basal intracellular calcium activity ([Ca2+]i), but significantly blunted the increase of [Ca2+]i following an increase of extracellular K+. Whole-cell patch-clamp studies revealed that the Ca2+ current through voltage-sensitive Ca2+ channels is significantly inhibited in the presence of urea. As evident from calcein fluorescence, addition of urea leads to sustained cell shrinkage. The effects of urea on vascular tone, [Ca2+]i activity, voltage-gated Ca2+ channels and cell volume are mimicked by addition of raffinose or NaCl. However, the cell shrinkage induced by urea is sustained, whereas the addition of equiosmolar NaCl is only transient and followed by a regulatory cell volume increase. Moreover, hypertonic NaCl increases, whereas urea decreases, the transcription of cell-volume-regulated kinase hsgk. In conclusion, urea leads to sustained shrinkage of vascular smooth muscle cells, which is followed by inhibition of voltage-gated Ca2+ channels, a decrease of [Ca2+]i and thus blunts the vasoconstrictory action of phenylephrine and increased extracellular K+ concentration.

Ion channels involved in insulin release are activated by osmotic swelling of pancreatic B-cells.

Measurements of the membrane potential showed that osmotic swelling (-80 mosmol/l) of pancreatic B-cells led to a transient hyperpolarization followed by a more sustained depolarization of the cell membrane. Cell swelling triggers a transient activation of the K+ATP current and of an inward current, carried by Cl-. This current was inhibited by DIDS, D600, and by omission of extracellular Ca2+. The depolarization opens voltage dependent L-type Ca2+ channels, thereby increasing the intracellular Ca2+ activity ([Ca2+]i). This effect was blunted by D600 or abolished by omission of Ca2+. Moreover, osmotic swelling transiently increased the amplitude of the Ca2+ currents. Replacement of NaCl by d-mannitol proved that the observed effects are due to an increase in cell volume and not to a reduction of extracellular Na+ or Cl-. Our results suggest that regulatory volume decrease is achieved by activation of K+ and Cl- currents. The Cl- current is responsible for the previously described depolarization and increase in insulin release induced by osmotic cell swelling.

Effects of indapamide on Ca2+ entry into vascular smooth muscle cells.

Part of the antihypertensive action of indapamide has been attributed to a direct inhibitory action on Ca2+ entry into vascular smooth muscle cells. The present study has been performed to identify the possible mechanisms involved. To this end the effect of indapamide on intracellular Ca2+ activity - [Ca2+]i - has been tested under control conditions and under conditions known to increase [Ca2+]i such as osmotic cell swelling (mimicking mechanical stress), depolarization (increase of extracellular K+ concentration) and oxidative stress (H2O2). Indapamide (10 micromol/l) was without effect on control [Ca2+]i, but significantly blunted the increase of [Ca2+]i following potassium-induced depolarization or following osmotic cell swelling. It did not significantly modify the increase of [Ca2+]i induced by H2O2. The effects on cell membrane potential induced by increased [K+], osmotic cell swelling, or H2O2 were not significantly modified by indapamide (10 micromol/l). Voltage-gated Ca2+ currents were not significantly modified by 10 micromol/l indapamide, but were significantly reduced by 100 micromol/l and blunted by 1 mmol/l. In conclusion, indapamide at high concentrations (100 micromol/l) inhibits voltage-gated Ca2+ channels, an effect which blunts the increase of [Ca2+]i during depolarization of the cell membrane at increased extracellular [K+] or osmotic stress. Whether these effects at high concentrations of indapamide are relevant to the antihypertensive action, however, cannot be established from these in vitro studies.

Effect of cellular hydration on protein metabolism.

In the past few years, the paramount importance of cell volume for the regulation of cell function, including protein metabolism, has been recognized. Among many other effects, cell swelling inhibits proteolysis and stimulates protein synthesis, whereas cell shrinkage stimulates proteolysis and inhibits protein synthesis. Moreover, cell swelling and cell shrinkage influence the expression of a number of genes, including carriers, enzymes, and signaling molecules. Hormones exploit the influence of cell volume on metabolism to exert their effects. Insulin swells hepatocytes by activation of Na-/H+ exchange and Na+,K+,2Cl- cotransport, while glucagon shrinks hepatocytes by activation of ion channels. The effects of these hormones on hepatic proteolysis completely depend on their influence on cell volume. The effects of cell volume are mediated in part by alterations of lysosomal pH, which modifies the activity of acidic lysosomal proteases. Transforming growth factor-beta 1, as other growth factors, activates the Na+/H+ exchanger, swells cells, leads to lysosomal alkalinization, inhibits proteolysis and may thus contribute to renal hypertrophy in chronic renal disease. Moreover, a decrease in cell volume correlates with catabolic states in a variety of diseases.

Expression of a renal type I sodium/phosphate transporter (NaPi-1) induces a conductance in Xenopus oocytes permeable for organic and inorganic anions.

Two distinct molecular types (I and II) of renal proximal tubular brush border Na+/Pi cotransporters have been identified by expression cloning on the basis of their capacity to induce Na+-dependent Pi influx in tracer experiments. Whereas the type II transporters (e.g., NaPi-2 and NaPi-3) resemble well known characteristics of brush border Na+/Pi cotransport, little is known about the properties of the type I transporter (NaPi-1). In contrast to type II, type I transporters produced electrogenic transport only at high extracellular Pi concentrations (> or =3 mM). On the other hand, expression of NaPi-1 induced a Cl- conductance in Xenopus laevis oocytes, which was inhibited by Cl- channel blockers [5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB) > niflumic acid >> 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid]. Further, the Cl- conductance was inhibited by the organic anions phenol red, benzylpenicillin (penicillin G), and probenecid. These organic anions induced outwardly directed currents in the absence of Cl-. In tracer studies, we observed uptake of benzylpenicillin with a Km of 0.22 mM; benzylpenicillin uptake was inhibited by NPPB and niflumic acid. These findings suggest that the type I Na+/Pi cotransporter functions also as a novel type of anion channel permeable not only for Cl- but also for organic anions. Such an apical anion channel could serve an important role in the transport of Cl- and the excretion of anionic xenobiotics.

The effects of nitric oxide on the membrane potential and ionic currents of mouse pancreatic B cells.

Nitric oxide (NO) is considered to contribute to the impairment of B cell function in insulin-dependent diabetes mellitus. The effects of compounds that release NO were tested on the membrane potential and ionic currents of mouse pancreatic B cells using intracellular microelectrodes and the whole-cell patch-clamp technique. S-Nitrosocysteine led to a concentration-dependent reduction of electrical activity induced by 15 mM glucose. At a concentration of 1 mM, S-nitrosocysteine cause a hyperpolarization of the plasma membrane with complete suppression of electrical activity. In about half of the cells tested, electrical activity reappeared during treatment with S-nitroso-cysteine or after wash-out. However, in the other cells the hyperpolarization was followed by a slow depolarization and electrical activity did not reappear. The perforated-patch whole-cell K+ATP current first increased and subsequently decreased again during exposure to 1 mM S-nitroso-cysteine. With 0.1 and 0.01 mM S-nitroso-cysteine, only the rise of the current amplitude was observed. S-nitroso-cysteine (1 mM) almost completely abolished the current through voltage-dependent Ca2+ channels (measured with Ba2+ as charge carrier). Like S-nitroso-cysteine, 100 microM sodium-nitroprusside, another donor, evoked a marked hyperpolarization of the membrane potential that was at least in part reversible. To further ascertain that the effect of S-nitroso-cysteine was mediated by NO, we tested the decomposition products of S-nitroso-cysteine. Nitrite and denitrosylated S-nitroso-cystein (1 mM) did not alter electrical activity of B cells, whereas cysteine (1 mM) caused a slight depolarization. It is concluded that exogenous NO evokes rapid changes of B cell function by influencing the activity of ion channels.

Ca2+ entry and vasoconstriction during osmotic swelling of vascular smooth muscle cells.

Exposure of aortic strips from guinea-pigs to hypotonic extracellular fluid is followed by marked vasoconstriction, which is inhibited by D-600 (3 microM), a blocker of voltage-sensitive Ca2+ channels. Conventional electrophysiology, patch-clamp studies, pH determination with 2',7' bis(2-carboxyethyl)-5,6-carboxyfluorescein (BCECF) and Ca2+ measurements with Fura-2 have been performed on smooth muscle cells cultured either from rat or human aorta to further elucidate the underlying mechanisms. Exposure of the cells to a 25% hypotonic extracellular fluid leads to a rapid and fully reversible depolarization, paralleled by an increase of the selectivity and conductance of the cell membrane to Cl-, an acidification of the cytoplasm and an increase of intracellular Ca2+ concentration ([Ca2+]i). The latter is inhibited by the Ca2+ channel blocker D-600 (1-3 microM). It is concluded that osmotic cell swelling leads to the activation of an anion channel. The subsequent depolarization of the cell membrane activates voltage-sensitive Ca2+ channels which increases [Ca2+]i, thus stimulating the contraction of vascular smooth muscle cells.

Effects of membrane-permeant and -impermeant thiol reagents on Ca2+ and K+ channel currents of mouse pancreatic B cells.

The membrane permeant thiol reagent diazene dicarboxylic acid bis-(N'-methylpiperazide) (DIP) has been shown to inhibit insulin secretion and Ca2+ uptake in pancreatic B cells in the presence of a stimulating glucose concentration (20 mM), whereas the nonpenetrating analog of DIP (bis-N'-methyliodide; DIP + 2) stimulates insulin release and Ca2+ uptake at a low glucose concentration (3 mM). The effects of DIP and DIP + 2 were tested on currents through ATP-sensitive K+ (K+ATP) channels and voltage-dependent Ca2+ channels (with Ba2+ as the charge carrier) in mouse pancreatic B cells in the whole-cell mode of the patch-clamp technique. DIP (0.1 mM) almost completely inhibited both the K+ATP and Ca2+ channel currents. In contrast, DIP + 2 (0.1 mM) did not affect the Ca2+ channel current but reduced the whole-cell K+ATP current by about 40%. The data strongly suggest that the suppression of insulin secretion previously observed with DIP is due to a reduction of the current through voltage-dependent Ca2+ channels, whereas the stimulation of hormone release induced by DIP + 2 is caused by the partial inhibition of K+ATP channel current.

Growth inhibition of oncogene-transformed rat fibroblasts by cocultured normal cells: relevance of metabolic cooperation mediated by gap junctions.

We have studied the proliferation of rat 208F cells (a derivative of Rat-1 cells) transformed by activated c-Ha-ras, v-fgr, v-raf, v-fms, or v-src oncogenes during cocultivation with an excess of early passage rat embryonic fibroblasts or immortal 208F cells. The total number and size of foci formed by oncogene-transformed 208F cells were strongly reduced by cocultured normal fibroblasts. The extent of growth suppression of transformed foci appears to be dependent on the type of transforming oncogene and on the type of normal fibroblasts rather than on the extent of gap-junctional communication between transformed and normal cells. Total inhibition of fluorescent dye transfer between normal and transformed cells by the 3 beta-O-hemisuccinate of 18 alpha-glycyrrhetinic acid (18 alpha-carbenoxolone), an inhibitor of gap-junctional communication in human fibroblasts, did not prevent growth inhibition of transformed cells in the cocultivation assay. Since adjacent cells remained electrically coupled in the presence of this inhibitor it is possible that the strongly reduced metabolic cooperation, as indicated by the lack of fluorescent dye transfer, is sufficient for mediating the growth-inhibitory effect of normal fibroblasts. 208F cell-conditioned medium, however, also caused strong growth inhibition of transformed derivatives, suggesting that the effect is in part mediated by release of stable growth inhibitor(s) from 208F cells.

Retinoic acid modulates gap junctional permeability: a comparative study of dye spreading and ionic coupling in cultured cells.

All-trans retinoic acid (RA), which was recently identified as a morphogen, affects gap junctional permeability in a dose- and time-dependent manner. In five different established mammalian cell lines (FL, BRL, BICR/M1Rk, HEL37, BT5C1) 100 mumol/liter RA reduced Lucifer yellow spreading within 30 min to 20-50% of the control. Ionic coupling, however, remained almost unaffected under the same conditions. Freeze-fractured membranes of untreated and RA-treated cells were similar with regard to frequency and sizes of gap junction plaques. With concentrations of less than 10 mumol/liter RA the dye spreading increased significantly in the human amniotic cell line FL, pointing to a possible modulatory effect of RA on junctional communication.