Effects of osmotic stresses on isolated rat hepatocytes. II. Modulation of intracellular pH

Increased intracellular crowding during hyperosmotic stress

Hyperosmotic stress activates in live cells numerous processes and also promotes intracellular protein/RNA aggregation and phase separation. However, the time course and the extent of these changes remain largely uncharacterized. To investigate dynamic changes in intracellular macromolecular crowding (MMC) induced by hyperosmotic stress in live cells, we used fluorescence lifetime imaging microscopy and fluorescence correlation spectroscopy (FCS) to quantify changes in the local environment by measuring the fluorescence lifetime and the diffusion of the monomeric enhanced green fluorescent protein (eGFP), respectively. Real-time monitoring of eGFP fluorescence lifetime showed that a faster response to environmental changes due to MMC is observed than when measuring the acceptor/donor emission ratio using the MMC-sensitive Förster resonance energy transfer sensor (GimRET). This suggests that eGFP molecular electronic states and/or collision frequency are affected by changes in the immediate surroundings due to MMC without requiring conformational changes as is the case for the GimRET sensor. Furthermore, eGFP diffusion assessed by FCS indicated higher intracellular viscosity due to increased MMC during hyperosmotic stress. Our findings reveal that changes in eGFP fluorescence lifetime and diffusion are early indicators of elevated intracellular MMC. Our approach can therefore be used to reveal in live cells short-lived transient states through which MMC builds over time, which could not be observed when measuring changes in other physical properties that occur at slower time scales.

Cell volume regulation in the perfused liver of a freshwater air-breathing cat fish Clarias batrachus under aniso-osmotic conditions: roles of inorganic ions and taurine

The roles of various inorganic ions and taurine, an organic osmolyte, in cell volume regulation were investigated in the perfused liver of a freshwater air-breathing catfish Clarias batrachus under aniso-osmotic conditions. There was a transient increase and decrease of liver cell volume following hypotonic (-80 mOsmol/l) and hypertonic (+80 mOsmol/l) exposures,respectively, which gradually decreased/increased near to the control level due to release/uptake of water within a period of 25-30 min. Liver volume decrease was accompanied by enhanced efflux of K+ (9.45 +/- 0.54 micromol/g liver) due to activation of Ba(2+)- and quinidine-sensitive K(+) channel, and to a lesser extent due to enhanced efflux of Cl(-) (4.35+/- 0.25 micromol/g liver) and Na+ (3.68+/- 0.37 micromol/g liver). Conversely, upon hypertonic exposure, there was amiloride-and ouabain-sensitive uptake of K+ (9.78+/- 0.65 micromol/g liver), and also Cl(-) (3.72 +/- 0.25 micromol/g liver).The alkalization/acidification of the liver effluents under hypo-/hypertonicity was mainly due to movement of various ions during volume regulatory processes. Taurine,an important organic osmolyte, appears also to play a very important role in hepatocyte cell volume regulation in the walking catfish as evidenced by the fact that hypo- and hyper-osmolarity caused transient efflux (5.68 +/- 0.38 micromol/g liver) and uptake (6.38 +/- 0.45 micromol/g liver) of taurine, respectively. The taurine efflux was sensitive to 4,4' -di-isothiocyanatostilbene-2,2'-disulphonic acid (DIDS, an anion channel blocker), but the uptake was insensitive to DIDS, thus indicating that the release and uptake of taurine during volume regulatory processes are unidirectional. Although the liver of walking catfish possesses the RVD and RVI mechanisms, it is to be noted that liver cells remain partly swollen and shrunken during anisotonic exposures,thereby possibly causing various volume-sensitive metabolic changes in the liver as reported earlier.

Extracellular pH alkalinization by Cl-/HCO3- exchanger is crucial for TASK2 activation by hypotonic shock in proximal cell lines from mouse kidney

We have previously shown that K(+)-selective TASK2 channels and swelling-activated Cl(-) currents are involved in a regulatory volume decrease (RVD; Barriere H, Belfodil R, Rubera I, Tauc M, Lesage F, Poujeol C, Guy N, Barhanin J, Poujeol P. J Gen Physiol 122: 177-190, 2003; Belfodil R, Barriere H, Rubera I, Tauc M, Poujeol C, Bidet M, Poujeol P. Am J Physiol Renal Physiol 284: F812-F828, 2003). The aim of this study was to determine the mechanism responsible for the activation of TASK2 channels during RVD in proximal cell lines from mouse kidney. For this purpose, the patch-clamp whole-cell technique was used to test the effect of pH and the buffering capacity of external bath on Cl(-) and K(+) currents during hypotonic shock. In the presence of a high buffer concentration (30 mM HEPES), the cells did not undergo RVD and did not develop outward K(+) currents (TASK2). Interestingly, the hypotonic shock reduced the cytosolic pH (pH(i)) and increased the external pH (pH(e)) in wild-type but not in cftr (-/-) cells. The inhibitory effect of DIDS suggests that the acidification of pH(i) and the alkalinization of pH(e) induced by hypotonicity in wild-type cells could be due to an exit of HCO(3)(-). In conclusion, these results indicate that Cl(-) influx will be the driving force for HCO(3)(-) exit through the activation of the Cl(-)/HCO(3)(-) exchanger. This efflux of HCO(3)(-) then alkalinizes pH(e), which in turn activates TASK2 channels.

Role of Na+ conductance, Na(+)-H+ exchange, and Na(+)-K(+)-2Cl- symport in the regulatory volume increase of rat hepatocytes

1. In rat hepatocytes under hypertonic stress, the entry of Na+ (which is thereafter exchanged for K+ via Na(+)-K(+)-ATPase) plays the key role in regulatory volume increase (RVI). 2. In the present study, the contributions of Na+ conductance, Na(+)-H+ exchange and Na(+)-K(+)-2Cl- symport to this process were quantified in confluent primary cultures by means of intracellular microelectrodes and cable analysis, microfluorometric determinations of cell pH and buffer capacity, and measurements of frusemide (furosemide)/bumetanide-sensitive 86Rb+ uptake, respectively. Osmolarity was increased from 300 to 400 mosmol l-1 by addition of sucrose. 3. The experiments indicate a relative contribution of approximately 4:1:1 to hypertonicity-induced Na+ entry for the above-mentioned transporters and the overall Na+ yield equalled 51 mmol l-1 (10 min)-1. 4. This Na+ gain is in good agreement with the stimulation of Na+ extrusion via Na(+)-K(+)-ATPase plus the actual increase in cell Na+, namely 55 mmol l-1 (10 min)-1, as we determined on the basis of ouabain-sensitive 86Rb+ uptake and by means of Na(+)-sensitive microelectrodes, respectively. 5. The overall increase in Na+ and K+ activity plus the expected concomitant increase in cell Cl- equalled 68 mmol l-1, which fits well with the increase in osmotic activity expected to occur from an initial cell shrinkage to 87.5% and a RVI to 92.6% of control, namely 53 mosmol l-1. 6. The prominent role of Na+ conductance in the RVI of rat hepatocytes could be confirmed on the basis of the pharmacological profile of this process, which was characterized by means of confocal laser-scanning microscopy.

Modulation of Na(+)-H+ exchange by altered cell volume in perfused rat mandibular salivary gland

1. Intracellular pH (pHi) was measured by spectrofluorometry in perfused mandibular salivary glands isolated from the rat and loaded with the pH-sensitive fluoroprobe 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF). Cell volume changes were estimated from changes in intracellular water content measured by proton NMR spectroscopy. 2. Stimulation with 1 microM acetylcholine (ACh) led to a 15 +/- 2% decrease in cell volume. A transient decrease in pHi was followed by a sustained increase (0.17 +/- 0.03 pH units) that has previously been attributed to the upregulation of the Na(+)-H+ exchanger. 3. Increasing perfusate osmolarity by addition of 60 mM sucrose caused a 19 +/- 2% decrease in cell volume and a sustained increase in pHi (0.12 +/- 0.01 pH units) that was abolished by 1 mM amiloride. Acid loading experiments indicated that the increase in pHi was due to an alkaline shift in the pH dependence of the Na(+)-H+ exchanger. 4. A 20% reduction in perfusate osmolarity prevented the cell shrinkage normally associated with ACh stimulation and largely abolished the ACh-induced increase in pHi. 5. Steady-state Na(+)-H+ exchanger activity, estimated from the initial rate of change in pHi following addition of amiloride, increased 9-fold during stimulation with ACh. When cell shrinkage was prevented by simultaneous exposure to the hypotonic solution, the activity of the exchanger still increased 7-fold in response to ACh. 6. We conclude that, although cell shrinkage leads to upregulation of the Na(+)-H+ exchanger, this factor alone is insufficient to account for the marked increase in exchanger activity that follows muscarinic stimulation.

Hypertonic stress increases the Na+ conductance of rat hepatocytes in primary culture

We studied the ionic mechanisms underlying the regulatory volume increase of rat hepatocytes in primary culture by use of confocal laser scanning microscopy, conventional and ion-sensitive microelectrodes, cable analysis, microfluorometry, and measurements of 86Rb+ uptake. Increasing osmolarity from 300 to 400 mosm/liter by addition of sucrose decreased cell volumes to 88.6% within 1 min; thereafter, cell volumes increased to 94.1% of control within 10 min, equivalent to a regulatory volume increase (RVI) by 44.5%. This RVI was paralleled by a decrease in cell input resistance and in specific cell membrane resistance to 88 and 60%, respectively. Ion substitution experiments (high K+, low Na+, low Cl-) revealed that these membrane effects are due to an increase in hepatocyte Na+ conductance. During RVI, ouabain-sensitive 86Rb+ uptake was augmented to 141% of control, and cell Na+ and cell K+ increased to 148 and 180%, respectively. The RVI, the increases in Na+ conductance and cell Na+, as well as the activation of Na+/K(+)-ATPase were completely blocked by 10(-5) mol/liter amiloride. At this concentration, amiloride had no effect on osmotically induced cell alkalinization via Na+/H+ exchange. When osmolarity was increased from 220 to 300 mosm/liter (by readdition of sucrose after a preperiod of 15 min in which the cells underwent a regulatory volume decrease, RVD) cell volumes initially decreased to 81.5%; thereafter cell volumes increased to 90.8% of control. This post-RVD-RVI of 55.0% is also mediated by an increase in Na+ conductance. We conclude that rat hepatocytes in confluent primary culture are capable of RVI as well as of post-RVD-RVI. In this system, hypertonic stress leads to a considerable increase in cell membrane Na+ conductance. In concert with conductive Na+ influx, cell K+ is then increased via activation of Na+/K(+)-ATPase. An additional role of Na+/H+ exchange in the volume regulation of rat hepatocytes remains to be defined.

Effects of aniso-osmolarity and hydroperoxides on intracellular pH in isolated rat hepatocytes as assessed by (2',7')-bis(carboxyethyl)-5(6)-carboxyfluorescein and fluorescein isothiocyanate-dextran fluorescence

Freshly isolated rat hepatocytes were plated for 4-6 h and either loaded with (2',7)-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF) or allowed to endocytose fluorescein isothiocyanate (FITC)-coupled dextran in order to study the effects of aniso-osmotic exposure and oxidative stress on cytosolic (pHcyt) and apparent vesicular pH (pHves) by single-cell fluorescence recordings. In the presence of normo-osmotic (305 mosmol/l) medium pHcyt was 7.23 +/- 0.03 (n = 108), whereas an apparent pH of 6.07 +/- 0.02 (n = 156) was found in the vesicular compartment accessible to endocytosed FITC-dextran. Substitution of 60 mM NaCl against 120 mM raffinose had no effect on pHcyt or apparent pHves, whereas addition of NH4Cl increased both pHcyt and apparent pHves. Hypo-osmotic cell swelling lowered pHcyt, whereas simultaneously apparent pHves increased. These effects were rapidly reversible upon re-institution of normo-osmotic media. Similarly, an increase of apparent pHves was observed when cell swelling was induced by Ba2+, glutamine or histidine. Conversely, hyperosmotic cell shrinkage due to addition of NaCl or raffinose led to a cytosolic alkalinization and a vesicular acidification. Both, H2O2 (0.2 mmol/l) and t-butyl-hydroperoxide (0.2 mmol/l) were without effect on pHcyt, but lowered apparent pHves by about 0.2 pH units. Ba2+ (1 mmol/l) diminished the acidifying effect of the hydroperoxides by about 50%. Pretreatment of the cells with colchicine, but not with lumicolchicine, largely abolished the effects of aniso-osmolarity and hydroperoxides on pHves. The data suggest that hepatocellular hydration affects the proton gradients built up across the membranes of endocytotic FITC-dextran-accessible compartments in a microtubule-dependent way. They further suggest that hydroperoxides induce vesicular acidification in a colchicine- and Ba(2+)-sensitive way. Because hydroperoxides induce Ba(2+)-sensitive cell shrinkage [Hallbrucker, Ritter, Lang, Gerok and Häussinger (1992) Eur. J. Biochem. 211, 449-458], the results are compatible with the view that hydroperoxide-induced cell shrinkage mediates vesicular acidification. It is concluded that modulation of vesicular pH by the hepatocellular hydration state may play a role in triggering some metabolic changes in response to cell swelling/shrinkage.

Mechanism of cadmium-induced cytotoxicity in rat hepatocytes. Cd-induced acidification causes alkalinization accompanied by membrane damage

Exposure of rat hepatocytes to cadmium below 50 microM for a short period (10 min) resulted in cellular acidification. Conversely, exposure to Cd more than 50 microM for a long period (60 min) caused cellular alkalinization accompanied by membrane damage as reflected by decrease in cellular K content and loss of intracellular lactic dehydrogenase. In hepatocytes exposed to 5 microM Cd, a concentration sufficient to induce acidification without cytotoxicity, the metal was preferentially associated with the crude nuclei and cell debris fractions, suggesting an interaction between Cd and cell membranes to cause acidification. Omission of bicarbonate from the incubation medium induced cellular acidification. The presence of Cd in this medium did not potentiate the medium-induced acidification. Mg-ATP (25 microM) induced cellular acidification in relation to an increase in the concentration of cytosolic free Ca. The coexistence of Mg-ATP and Cd at the concentrations which had no effect on cellular pH in the presence of either agants induced cellular acidification. These observations suggest that Cd induced cellular acidification by modulating the process connected with the rise in cytosolic free Ca via interaction with plasma membranes. This acidification had no strong immediate cytotoxic actions but led to subsequent cellular alkalinization accompanied with severe cytotoxicity and membrane breakage.

Regulation of glycogen synthesis and glycolysis by insulin, pH and cell volume. Interactions between swelling and alkalinization in mediating the effects of insulin

The effects of changes in cell volume and pH on glycogen synthesis and glycolysis and their control by insulin were investigated in hepatocyte cultures. 1. Cell acidification, by increasing [CO2] from 2.5% to 5%, inhibited glycolysis and stimulated glycogen synthesis. The inhibition of glycolysis was also observed in Na(+)-free media and when K+ uptake was inhibited, but the stimulation of glycogen synthesis was abolished under these conditions, suggesting that it is secondary to ionic or volume changes. Alkalinization had converse effects on glycolysis and glycogen synthesis. 2. In HCO3(-)-containing media, replacement of NaCl with sodium acetate or potassium acetate, like acidification with CO2, inhibited glycolysis and stimulated glycogen synthesis. The latter correlated with an increase in cation content. Amiloride, an inhibitor of Na+/H+ exchange, inhibited both the increase in cation content and the stimulation of glycogen synthesis, suggesting that the latter is secondary to cell swelling. 3. Hypo-osmotic swelling increased glycogen synthesis in HCO3(-)-containing media, in both the absence and the presence of Na+ and at both 2.5% and 5% CO2, but it increased glycolysis in the presence of Na+ and at 2.5%, but not at 5%, CO2. In HCO3(-)-free media, during acidification and swelling, glycogen synthesis correlated with pH and not with cell volume, indicating that inhibition by acidification over-rides stimulation by swelling. 4. Stimulation of glycolysis by insulin was not additive with stimulation by alkalinization. The stimulation of glycogen synthesis by insulin was partially suppressed under alkaline conditions; it was markedly suppressed in isosmolar Na(+)-free media and restored by hypo-osmotic swelling. In hypo-osmolar Na(+)-free media insulin prevented the decrease in glycogen synthesis with decreasing [HCO3-], suggesting that it counteracts inhibition by acidification. 5. It is concluded that glycogen synthesis and glycolysis are both stimulated by cell swelling and inhibited by acidification, under certain conditions, but glycolysis is more sensitive to inhibition by acidification and glycogen synthesis to stimulation by swelling. Consequently, simultaneous swelling and acidification is associated with inhibition of glycolysis and stimulation of glycogen synthesis. Stimuli that cause swelling and alkalinization activate both glycogen synthesis and glycolysis, alkalinization being more important in control of glycolysis and swelling in control of glycogen synthesis. Both cell swelling and alkalinization are components of the mechanism by which insulin controls glycogen synthesis and glycolysis.

The role of cell swelling in the stimulation of glycogen synthesis by insulin

In hepatocyte cultures, insulin stimulates cellular accumulation of K+, partly (approximately 20%) by net replacement of cell Na+, but largely (approximately 80%) by increasing the cell K++Na+ content, with a consequent increase in cell volume. An increase in cation content occurred within 5 min of exposure to insulin and was not secondary to metabolic changes. Insulin also increased the cation content, by increasing the Na+ content, in a K(+)-free medium or when K+ uptake was inhibited with 1 mM-ouabain. However, insulin did not increase the cation content in a Na(+)-free medium. The stimulation of glycogen synthesis by insulin, like the increase in cation content, was blocked in a Na(+)-free medium, but not when K+ uptake was inhibited. Hypo-osmotic swelling restored the stimulation of glycogen synthesis in a Na(+)-free medium, indicating that the lack of effect of insulin in the iso-osmotic Na(+)-free medium was not due to a direct requirement for Na+ for glycogen synthesis, but to a secondary mechanism, dependent on Na+ entry, that can be mimicked by hypo-osmotic swelling. Quinine increased cell volume further and caused a further increase in glycogen synthesis. The hypothesis that cellular uptake of K+ may be part of the mechanism by which insulin controls metabolism was discounted, because inhibition of K+ uptake does not block the metabolic effects of insulin [Czech (1977) Annu. Rev. Biochem. 46, 359-384]. The present results support the hypothesis that an increase in cell cation content, and thereby cell volume, rather than K+ uptake, is part of the mechanism by which insulin stimulates glycogen synthesis in hepatocytes.

Intracellular pH rises and astrocytes swell after portacaval anastomosis in rats

The basis for astrocytic swelling after the early period after portacaval anastomosis (PCA) is poorly defined. In other eukaryotic cells intracellular pH (pHi) and volume are determined, in part, by the same general mechanisms, yet how astrocytic pHi varies with enlargement of these cells after PCA is unknown. Therefore, direct measurements of pHi in astrocytes were made and compared with pericapillary astrocytic area as determined from electron micrographs in rats 5-8 days after PCA. Astrocytic area (n = 14 measurements for each group) was found to be significantly (P less than 0.0009) greater in PCA animals (n = 3) than in sham-operated control animals. (n = 3). Double-barrel pH-sensitive microelectrodes were used to measure pHi in neocortical cells defined by electrophysiological criteria to be astrocytic. Astrocytes (n = 25) from PCA animals (n = 5) had a resting membrane potential of 72 +/- 5 mV (mean +/- SD) and an pHi of 7.11 +/- 0.11 while comparable cells (n = 12) from sham-operated controls (n = 2) had a membrane potential of 81 +/- 6 mV and an pHi of 7.00 +/- 0.10. Astrocytes from PCA animals were significantly more depolarized (P less than 0.001) and alkaline (P less than 0.009), at a time when they were also significantly larger than those from sham-operated controls. Astrocytes are known to become more alkaline when they are activated by brief depolarizing stimuli. However, this is the first demonstration that such an interrelationship can also exist for steady-state conditions of these cells.(ABSTRACT TRUNCATED AT 250 WORDS)