Cell volume regulation in rat thin ascending limb of Henle's loop

Thin ascending limb cells of Henle's loop from Wistar rats were studied with in vitro microperfusion and video-optical techniques to investigate their ability in regulating cell volume during osmotic shock and to identify mechanisms of ion transport involved in the process. These cells showed a clear volume regulatory decrease (VRD) response in hyposmotic medium, but no volume regulatory increase in hyperosmotic medium. The presence of barium in the bath abolished VRD. Removal of K+ from bath and perfusate also inhibited the VRD response. Reintroduction of K+ in hyposmotic conditions reestablished cell volume regulation. Introduction of anthracene-9-COOH to the basolateral medium blocked cell volume regulatory response. Cl- removal from perfusate and bath solutions also inhibited VRD, probably because of a significant intracellular Cl- depletion. Exposure of cells to ethylene glycol-bis(beta-aminoethyl ether)-N,N,N'N'-tetraacetic acid in perfusate and bath solutions reduced significantly Ca2+ concentration and impaired VRD. Reintroduction of Ca2+ in hyposmotic conditions restored volume regulation. The presence of ouabain in basolateral medium also inhibited VRD. These data suggest that the following mechanisms in the basolateral membrane are involved in VRD response: K+ and Cl- conductive pathways, which might be Ca2+ dependent for activation, and an Na(+)-K(+)-adenosinetriphosphatase.

Cell volume regulation of rabbit cortical collecting tubule in anisotonic media

Volume regulation of nonperfused rabbit cortical collecting tubules in anisotonic bathing media was examined in vitro. When media osmolality is abruptly increased by 150 mosmol/kgH2O with the addition of NaCl, tubules shrink by 20% but do not volume regulate. However, volume regulatory increase (VRI) is observed when 1 mM butyrate is present in the bathing media or when tubules are pretreated with hypotonic media. When media osmolality is increased, butyrate-treated tubules shrink to 74% of their isotonic control volume. As evidence of volume regulation, butyrate-treated tubules swell while still bathed in hypertonic media, recovering in 30 min 78% of the volume lost due to osmotic shrinkage. The butyrate effect requires external Na+ and is inhibited by amiloride. When media osmolality is lowered to 150 mosmol/kgH2O, nonbutyrate tubules swell before showing typical volume regulatory decrease. When these tubules are returned to isotonic media, they immediately shrink to 78% of control volume before showing evidence of VRI. These results suggest that, under the appropriate conditions, cortical collecting tubules are capable of VRI.

Polarity of volume-regulatory increase by Necturus gallbladder epithelium

Necturus gallbladder epithelial cells respond to the presence of a hypertonic perfusate in either bathing solution by first shrinking due to osmotic water loss and then swelling back to their original volume (volume-regulatory increase). Previous investigations involving increases in the osmolality of the mucosal bath had suggested that volume-regulatory increase was due to the activation of ion exchangers in the apical cell membrane. In the present study the sidedness of the transport processes involved in volume-regulatory increase was investigated. The osmolality of the serosal bath was increased by 18% either in the absence of HCO3- or when an inhibitor of volume-regulatory increase, 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS), was added to the mucosal or serosal bath. Volume regulation was HCO3- dependent. DIDS was only effective in inhibiting volume regulation when it was added to mucosal bathing solution, suggesting that volume-regulatory increase depended on transport across the apical membrane. Volume-regulatory increase could also be activated by first swelling the cells in hypotonic solution and then returning the tissue to control Ringer solution. The volume-regulatory increase that occurred upon return to control Ringer was also shown to be sensitive to DIDS in the mucosal bath.

Further studies of the volume-regulatory response of Amphiuma red cells in hypertonic media. Evidence for amiloride-sensitive Na/H exchange.

When Amphiuma red cells are shrunken in hypertonic media, they return toward their original volume by gaining Na through an amiloride-sensitive pathway. As cells recover their volume during this volume-regulatory increase (VRI) response, acid is extruded into the medium. Medium acidification is correlated with cell Na uptake. Both medium acidification and cell Na uptake are blocked by 10(-3) M amiloride or by replacing medium Na with K or choline. Perturbations that increase cell Na uptake (such as increasing medium osmolality) also increase medium acidification. As the medium becomes more acidic, the cells become more alkaline. These changes in cell and medium pH are increased if pH equilibration across the cell membrane is prevented by inhibiting the anion exchanger with SITS (4-acetamido-4'-isothiocyano-2,2'-stilbene disulfonic acid). The quantity of acid extruded by SITS-treated cells is the same as the quantity of Na gained, which strongly suggests 1:1 exchange of Na for H. Cell enlargement in SITS-treated cells results from the exchange of osmotically active Na ions for H ions that are not osmotically active when combined with cellular buffers. Previous evidence indicates that the normal VRI response involves an increase in the cellular content of Cl as well as Na. We show that SITS completely blocks net Cl uptake, which suggests that Cl enters via the anion exchanger. SITS also slows Na entry, presumably as a result of the above-mentioned increase in cell pH caused by SITS. We suggest that the initial event in the VRI response is net Na uptake via a Na/H exchanger, and that net Cl uptake results from secondary Cl/HCO3 exchange via the anion exchanger.

Volume-regulatory responses of Amphiuma red cells in anisotonic media. The effect of amiloride.

Amphiuma red cells were incubated for several hours in hypotonic or hypertonic media. They regulate their volume in both media by using ouabain-insensitive salt transport mechanisms. After initially enlarging osmotically, cells in hypotonic media return toward their original size by losing K, Cl, and H2O. During this volume-regulatory decrease (VRD) response, K loss results from a greater than 10-fold increase in K efflux. Cells in hypertonic media initially shrink osmotically, but then return toward their original volume by gaining Na, Cl, and H2O. The volume-regulatory increase (VRI) response involves a large (greater than 100-fold) increase in Na uptake that is entirely blocked by the diuretic amiloride (10(-3) M). Na transport in the VRI response shares many of the characteristics of amiloride-sensitive transport in epithelia: (a) amiloride inhibition is reversible; (b) removal of amiloride from cells pretreated with amiloride enhances Na uptake relative to untreated controls; (c) amiloride appears to act as a competitive inhibitor (Ki = 1-3 microM) of Na uptake; (d) Na uptake is a saturable function of external Na (Km approximately 29 mM); (e) Li can substitute for Na but K cannot. Anomalous Na/K pump behavior is observed in both the VRD and the VRI responses. In the VRD response, pump activity increases 3-fold despite a decrease in intracellular Na concentration, while in the VRI response, a 10-fold increase in pump activity is observed when only a doubling is predicted from increases in intracellular Na.

Volume regulation by Necturus gallbladder: apical Na+-H+ and Cl(-)-HCO-3 exchange

Necturus gallbladder epithelial cells exhibited volume regulatory swelling when exposed to a hypertonic mucosal bathing solution. The initial, osmotically induced shrinkage was followed by a rapid increase in cell volume back to the control value despite continuing hypertonicity of the mucosal perfusate. This volume regulatory increase occurred by osmotic water flow accompanying the transient cellular uptake of NaCl from the mucosal bathing solution. Volume regulatory increase required Na+ and Cl- in the mucosal bath; it was inhibited by amiloride or 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid but not by bumetanide or ouabain. The K1/2 for Na+ was 2.8 mM, the K1/2 for Cl- was 1.9 mM, and maximum velocity of fluid flow into the cell for both ions was greater than 10 x 10(-6) cm/s. Both volume regulatory increase and transepithelial fluid absorption involve NaCl flux across the apical membrane into the cells, but the nature of the NaCl fluxes differ in the two processes. During volume regulatory increase NaCl enters the cells by parallel Na+-H+ and Cl(-)-HCO-3 exchanges, whereas during transepithelial fluid absorption NaCl enters the cell by the coupled flux of NaCl.