The diversity of volume regulatory mechanisms

Mammalian cells utilize a wide variety of cell volume regulatory mechanisms. For rapid adjustment of cell volume cells release or accumulate ions through respective channels and transport systems across the cell membrane. The most widely used mechanisms of cell volume regulatory ion release include ion channels and KCl symport. Ion uptake is most frequently mediated by Na+ channels, Na+, K+, 2Cl- cotransport, and Na+/H+ exchange. Chronic adjustment of cell osmolarity is accomplished by the formation or accumulation of organic osmolytes, molecules specifically designed to create intracellular osmolarity without interfering with cellular function. The most widely occurring osmolytes are sorbitol, inositol, glycerophosphorylcholine, betaine, taurine, and amino acids. The osmolytes are either synthesized by or transported into shrunken cells. During cell swelling osmolytes can be rapidly degraded or released. Any given cell may utilize several volume-regulatory mechanisms. Moreover, different mechanisms are utilized in different tissues. The diversity of cell volume regulatory mechanisms allows the cells to defend the constancy of cell volume against a myriad of challenges with relatively little impairment of cellular function.

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.

Mesangial cell hypertrophy induced by NH4Cl: role of depressed activities of cathepsins due to elevated lysosomal pH

Enhanced ammoniagenesis is currently thought to play an important role in renal hypertrophy and subsequent tubulointerstitial fibrosis. Under certain conditions glomeruli also may be affected by ammonia toxicity. Exposure of glomeruli to augmented ammonia levels may occur: (i) in advanced liver diseases due to elevated blood ammonia concentrations; (ii) in conditions of enhanced tubular ammoniagenesis following cortical "trapping;" and (iii) due to increased ammonia formation in the glomeruli in the presence of impaired renal function. To elucidate the potential role of ammonia in glomerular injury, we investigated the effect of NH4Cl on protein turnover as well as on activities of various cathepsins in cultured rat mesangial cells. The results show that NH4Cl (20 mM) induced cell hypertrophy as defined by an increase in both cell protein content and cell volume (+38% and +10.1%, respectively, after 48 hr). This hypertrophy was associated with suppression of the activities of cathepsins B and L + B (-56.8% and -51.3% after 48 hr) and reduction of protein degradation rate (-61% after 48 hr), but without enhanced protein synthesis. Inhibition of Na+/H+ antiport by amiloride (1 mM) neither prevented the reduction of cathepsin activities nor the hypertrophy of the mesangial cells. Upon NH4Cl application lysosomal pH was elevated. This alkalinization may be causatively involved in the impairment of cathepsin B and L + B due to shifting the lysosomal pH above the optimum of their activities. In conclusion, NH4Cl induces hypertrophy but not hyperplasia in mesangial cells. This hypertrophy is caused by the reduction of protein degradation, mainly due to depressed activities of cathepsin B and L + B in the absence of enhanced protein synthesis. A shift of lysosomal pH above the optimum of the acidic cathepsins seems to be a key factor in their impaired activities in mesangial cells.

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.

Functional significance of cell volume regulatory mechanisms

To survive, cells have to avoid excessive alterations of cell volume that jeopardize structural integrity and constancy of intracellular milieu. The function of cellular proteins seems specifically sensitive to dilution and concentration, determining the extent of macromolecular crowding. Even at constant extracellular osmolarity, volume constancy of any mammalian cell is permanently challenged by transport of osmotically active substances across the cell membrane and formation or disappearance of cellular osmolarity by metabolism. Thus cell volume constancy requires the continued operation of cell volume regulatory mechanisms, including ion transport across the cell membrane as well as accumulation or disposal of organic osmolytes and metabolites. The various cell volume regulatory mechanisms are triggered by a multitude of intracellular signaling events including alterations of cell membrane potential and of intracellular ion composition, various second messenger cascades, phosphorylation of diverse target proteins, and altered gene expression. Hormones and mediators have been shown to exploit the volume regulatory machinery to exert their effects. Thus cell volume may be considered a second message in the transmission of hormonal signals. Accordingly, alterations of cell volume and volume regulatory mechanisms participate in a wide variety of cellular functions including epithelial transport, metabolism, excitation, hormone release, migration, cell proliferation, and cell death.

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.

Effect of osmolarity on LDL binding and internalization in hepatocytes

The present study has been performed to elucidate a possible role of cell volume in low-density lipoprotein (LDL) binding and internalization (LDL(b+i)). As shown previously, increase of extracellular osmolarity (OSMe) and K+ depletion, both known to shrink cells, interfere with the formation of clathrin-coated pits and thus with LDL(b+i). On the other hand, alterations of cell volume have been shown to modify lysosomal pH, which is a determinant of LDL(b+i). LDL(b+i) have been estimated from heparin-releasable (binding) or heparin-insensitive (internalization) uptake of 125I-labeled LDL. OSMe was modified by alterations of extracellular concentrations of ions, glucose, urea, or raffinose. When OSMe was altered by varying NaCl concentrations, LDL(b+i) decreased (by 0.5 +/- 0.1%/mM) with increasing OSMe and LDL(b+i) increased (by 1.2 +/- 0.1%/mM) with decreasing OSMe, an effect mainly due to altered affinity; the estimated dissociation constant amounted to 20.6, 48.6, and 131.6 micro/ml at 219, 293, and 435 mosM, respectively. A 25% increase of OSMe increased cytosolic (by 0.46 +/- 0.03) and decreased lysosomal (by 0.14 +/- 0.02) pH. Conversely, a 25% decrease of OSMe decreased cytosolic (by 0.28 +/- 0.02) and increased lysosomal (by 0.17 +/- 0.02) pH. Partial replacement of extracellular Na+ with K+ had little effect on LDL(b+i), although it swelled hepatocytes and increased lysosomal and cytosolic pH. Hypertonic glucose, urea, or raffinose did not exert similar effects despite a shrinking effect of hypertonic raffinose. Monensin, which completely dissipates lysosomal acidity, virtually abolished LDL(b+i). In conclusion, the observations reveal a significant effect of ionic strength on LDL(b+i). The effect is, however, not likely to be mediated by alterations of cell volume or alterations of lysosomal pH.

The role of the IsK protein in the specific pharmacological properties of the IKs channel complex

IKs channels are composed of IsK and KvLQT1 subunits and underly the slowly activating, voltage-dependent IKs conductance in heart. Although it appears clear that the IsK protein affects both the biophysical properties and regulation of IKs channels, its role in channel pharmacology is unclear. In the present study we demonstrate that KvLQT1 homopolymeric K+ channels are inhibited by the IKs blockers 293B, azimilide and 17-beta-oestradiol. However, IKs channels induced by the coexpression of IsK and KvLQT1 subunits have a 6-100 fold higher affinity for these blockers. Moreover, the IKs activators mefenamic acid and DIDS had little effect on KvLQT1 homopolymeric channels, although they dramatically enhanced steady-state currents through heteropolymeric IKs channels by arresting them in an open state. In summary, the IsK protein modulates the effects of both blockers and activators of IKs channels. This finding is important for the action and specificity of these drugs as IsK protein expression in heart and other tissues is regulated during development and by hormones.

L-selectin regulates actin polymerisation via activation of the small G-protein Rac2

L-selectin mediated adhesion to endothelial cells is a crucial step in the immune response to pathogens (1, 2) and in lymphocyte homing (3, 4). Selectin molecules mediate leukocyte rolling on endothelial cells, the initial step of adhesion (5, 6). We have previously shown that stimulation of Jurkat T-lymphocytes via L-selectin results in activation of the p21Ras pathway and synthesis of reactive oxygen intermediates (7). Here, we show that cellular stimulation via L-selectin induces a change of cytoskeleton organisation demonstrated by a tenfold increase of actin filament polymerisation. This actin polymerisation is mediated by a Ras and Rac2 regulated pathway, since inhibition of Ras by transient transfection of transdominant inhibitory N17Ras or suppression of Rac2 protein expression by antisense oligonucleotides prevents L-selectin triggered actin polymerisation. Our results point to a signaling cascade from L-selectin via Ras and Rac2 to actin filaments, which might be important for leukocyte adhesion.

L-selectin activates the Ras pathway via the tyrosine kinase p56lck

Selectins mediate rolling, the initial step of leukocyte adhesion to endothelial cells [Springer, T. A. (1995) Annu. Rev. Physiol. 57, 827-872 and Butcher, E. C. (1991) Cell 67, 1033-1036]. In this study we show that L-selectin triggering of Jurkat cells using different antibodies or glycomimetics resulted in activation of the src-tyrosine kinase p56lck; tyrosine phosphorylation of intracellular proteins, in particular mitogen-activating protein kinase and L-selectin; and association of Grb2/Sos with L-selectin. This association correlated with an activation of p21Ras, mitogen-activating protein kinase, Rac2, and a transient increase of 2-O synthesis. Stimulation of the Ras pathway by L-selectin requires functional p56lck, since p56lck-deficient Jurkat cells (JCaM1.6) do not show tyrosine phosphorylation, association of L-selectin with Grb2/Sos, and activation of Ras upon L-selectin triggering. Transfection of JCaM1.6 cells with p56lck reconstitutes the observed signaling events. Genetic inhibition of Ras or Rac2 prevented Rac2 stimulation and 2-O synthesis, respectively. The specificity and the physiological significance of the observed signaling cascade is indicated by stimulation of L-selectin-transfected P815, L-selectin-positive CEM or peripheral blood lymphocytes resulting in the same activation events as in Jurkat cells. Our results point to a signaling cascade from L-selectin via p56lck, Grb2/Sos, Ras, and Rac2 to 2-O.

Effect of astroglial cell swelling on pH of acidic intracellular compartments

A variety of pathological conditions lead to swelling of astrocytes, which in turn stimulates ion release by activation of ion channels at the plasma membrane. In the present study, acridine orange and fluorescein isothiocyanate coupled to dextran (FITC-dextran) have been used to examine the effect of cell swelling on pH in acidic compartments of cultured astroglial cells. Both NH4Cl (2 mM) and chloroquine (10 microM), known to alkalinize acidic cellular compartments, led to the expected increase in acridine orange fluorescence intensity. Similar, albeit smaller, effects were elicited by a reduction of extracellular osmolarity (-80 mOsm) and treatment of the cells with glutamate (l mM), manoeuvres which enhanced cell volume. Determination of changes in the FITC-dextran fluorescence ratio (485/440 nm) allowed quantification of the pH changes in lysosomal compartments. Treatment with NH4Cl, reduced extracellular osmolarity and glutamate increased lysosomal pH by 0.65 +/- 0.07, 0.85 +/- 0.14 and 0.25 +/- 0.07, respectively. Measurement of cytosolic pH using 2',7',-bis-(2-carboxyethyl)-5- (and -6) carboxyfluorescein (BCECF) demonstrated a pronounced acidification following cell swelling, observed with both reduced extracellular osmolarity (by 0.23 +/- 0.05 pH units) and 1 mM glutamate (by 0.26 +/- 0.02 pH units). In conclusion, pH within lysosomes and possibly other acidic cellular compartments of astrocytes is increased by cell swelling, which may have important consequences for astrocyte function.

Studies on the mechanism of swelling-induced lysosomal alkalinization in vascular smooth muscle cells

Previous studies in renal cells and hepatocytes have shown that cell swelling leads to a rapid and reversible increase in pH in acidic cellular compartments, including lysosomes. Among the consequences are an inhibition of proteolysis. The present study shows that a similar lysosomal alkalinization occurs upon osmotic swelling of vascular smooth muscle cells, as evidenced by acridine orange and fluorescein isothiocyanate fluorescence. Furthermore, we have studied the mechanism underlying lysosomal alkalinization, which had remained unclear. The lysosomal alkalinization was not abolished by inhibition of vacuolar H+-ATPases (100 nM bafilomycin), Cl- channels [100 microM] 5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB), carbonic anhydrase (100 microM acetazolamide) or Na+/H+ exchange (10 microM HOE 694). The Ca2+ ionophore A23187 (10 microM) led to a slight increase in lysosomal pH, but removal of extracellular Ca2+ and depletion of cellular Ca2+ stores (100 nM thapsigargin) did not appreciably blunt the swelling-induced lysosomal alkalinization. In the presence of bafilomycin the alkalinizing effect of osmotic cell swelling was not reversible, in contrast to that of NH4Cl. In conclusion, osmotic swelling of vascular smooth muscle cells leads to lysosomal alkalinization, presumably in large part through activation of a hydrogen ion leak.

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.

Cell Volume: A Second Message in Regulation of Cellular Function

To survive, cells must avoid excessive alterations of cell volume. Thus cells have acquired a variety of strategies to main constancy of their volume, including the modification of ion flux across cell membranes and metabolic pathways. Hormones exploit these mechanisms for regulation of cellular function.

Involvement of microtubules in the link between cell volume and pH of acidic cellular compartments in rat and human hepatocytes

Cell swelling is shown to induce an increase in acridine orange fluorescence intensity, an effect pointing to the alkalinization of acidic vesicles. Since autophagic hepatic proteolysis is accomplished by pH-sensitive proteinases within acidic lysosomes, this effect may contribute to the well-known inhibitory effect of cell swelling on proteolysis. In the present study, the role of microtubules in volume-dependent alterations of pH in acidic vesicles of rat and human hepatocytes was studied. Colcemid and colchicine were used to depolymerize microtubules and vesicular pH was monitored using two different fluorescent dyes, fluorescein isothiocyanate conjugated-dextran and acridine orange. Colcemid and colchicine, but not the inactive stereoisomer gamma-lumicolchicine, blunted the increase of pH during osmotic cell swelling. The alkalinization of acidic vesicles by NH4Cl was not significantly modified by colcemid or colchicine, indicating that the vesicles were still sensitive to alkalinizing procedures other than cell swelling. Further, colchicine, but not gamma-lumicolchicine, inhibited the antiproteolytic action of osmotic cell swelling. The present observations point to an involvement of the microtubule network in the link of cell volume, lysosomal pH, and proteolysis.

Alkalinization of acidic cellular compartments following cell swelling

Osmotic swelling of rat hepatocytes increases fluorescence of Acridine orange and of fluorescein isothiocyanate (FITC)-dextran, both indicative of alkalinization of acidic intracellular vesicles. Similar to osmotic cell swelling, insulin and glutamine lead to an increase in Acridine orange fluorescence, an effect virtually abolished upon osmotic reversal of glutamine-induced cell swelling. Barium, which blocks K+ channels in the plasma membrane, similarly leads to cell swelling and increase of Acridine orange fluorescence. Since proteolysis is governed by lysosomal pH, these observations indicate that the anti-proteolytic action of osmotic cell swelling is mediated by lysosomal alkalinization. Thereby, insulin, glutamine and barium probably exert their anti-proteolytic action by cell swelling and subsequent lysosomal alkalinization.