scholarly journals Proximal tubule volume regulation in hypo-osmotic media: intracellular K+, Na+, and Cl-.

1990 ◽  
Vol 1 (2) ◽  
pp. 211-218
Author(s):  
L Rome ◽  
C Lechene ◽  
J J Grantham
Keyword(s):  
Cell Volume ◽  
Volume Regulation ◽  
Cell Volume Regulation ◽  
Rabbit Kidney ◽  
Kidney Cortex ◽  
Volume Regulatory Decrease ◽  
Osmotic Change ◽  
Electrolyte Loss ◽  
The Difference

This study sought to measure the net loss of intracellular K+, Na+, and Cl- that accompanied isosmotic cell volume regulation in hypotonic media and to determine if electrolyte loss depended on the rate at which the extracellular osmolality was reduced. Isolated nonperfused proximal S2 segments from rabbit kidney cortex were studied in vitro. Gradual lowering of osmolality from 295 to 150 mOsm/kg at a rate of 2 mOsm/kg/min did not cause an increase in tubule cell volume until the medium osmolality decreased below 190 mOsm/kg. By contrast, tubules rapidly bathed in low osmolality media exhibited classical osmometric swelling followed by incomplete volume regulatory decrease. Volume regulation associated with gradual and rapid lowering of osmolality was accompanied by the net loss of intracellular K+, Na+, and Cl- (measured by electron probe); however, the temporal pattern of electrolyte loss depended on the rate of osmotic change. With gradual lowering of osmolality, cell K+ content did not decrease significantly until osmolality was lowered below 200 mOsm/kg, whereas Cl- was lost at the 200 mOsm/kg level and below. With rapid lowering of osmolality, cell K+ content was strikingly decreased at the 200 mOsm/kg level, but Cl- did not change appreciably until osmolality was decreased to 150 mOsm/kg. Cell Na+ content decreased in hypo-osmotic media, but the magnitude was relatively small. During volume regulation that accompanied either gradual or rapid lowering of medium osmolality from 295 to 150 mOsm/kg, intracellular osmolal gap, the difference between medium osmolality and the sum of intracellular concentrations of K+, Na+, and Cl- decreased 87 and 58 mOsm/kg, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

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

1992 ◽  
Vol 263 (3) ◽  
pp. F353-F362
Author(s):  
L. F. Onuchic ◽  
I. R. Arenstein ◽  
A. G. Lopes
Keyword(s):  
Cell Volume ◽  
Volume Regulation ◽  
Osmotic Shock ◽  
Basolateral Membrane ◽  
Cell Volume Regulation ◽  
Tetraacetic Acid ◽  
Volume Regulatory Decrease ◽  
Henle's Loop ◽  
Volume Regulatory Increase

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.

Effect of hemorrhagic shock on hepatic transmembrane potentials and intracellular electrolytes, in vivo

1981 ◽  
Vol 240 (3) ◽  
pp. R211-R219 ◽  
Author(s):  
M. M. Sayeed ◽  
R. J. Adler ◽  
I. H. Chaudry ◽  
A. E. Baue
Keyword(s):  
Hemorrhagic Shock ◽  
Cell Volume ◽  
Volume Regulation ◽  
Cell Volume Regulation ◽  
Shed Blood ◽  
Average Value ◽  
Transmembrane Potentials ◽  
Relative Membrane Permeability

In this study we investigated in vivo changes in hepatic cellular electrolytes and resting transmembrane potentials (Em) during hemorrhagic shock. Hepatic Na-K transport and cell volume regulation were assessed in vitro. Rats were bled and the ensuing hypotension (40 mmHg) was maintained by returning 25-30% (intermediate-shock, IS) or 55-60% (late-shock, LS) of the shed blood. We resuscitated IS rats by reinfusion of all of the remaining shed blood and Ringer's lactate solution. Hepatic cellular Na and Cl increased and K decreased progressively with shock. Resuscitation of IS rats restored cell K and Cl but not Na to preshock levels. Em decreased from the control average value of -40 (mV) to -31 in IS and -19 in LS. Em was partially restored (-36 mV) after resuscitation. We evaluated changes in relative membrane permeability to Na and K (PNa/PK) with shock by assuming Em either to be a Na-K exchange diffusion potential or due to an unequally coupled movement of Na and K. These evaluations show a lack of effect of shock (IS, with or without resuscitation) on PNa/PK. Our observations are compatible with failure of an electrogenic Na pump in shock. This may be related to loss of hepatic cell volume regulation in shock.

Hemorrhagic shock impairs myocardial cell volume regulation and membrane integrity in dogs

1987 ◽  
Vol 252 (6) ◽  
pp. H1203-H1210
Author(s):  
J. W. Horton
Keyword(s):  
Hemorrhagic Shock ◽  
Cell Volume ◽  
Volume Regulation ◽  
Membrane Integrity ◽  
Cell Volume Regulation ◽  
Calcium Entry ◽  
Tissue Water ◽  
Total Tissue

An in vitro myocardial slice technique was used to quantitate alterations in cell volume regulation and membrane integrity after 2 h of hemorrhagic shock. After in vitro incubation in Krebs-Ringer-phosphate medium containing trace [14C]inulin, values (ml H2O/g dry wt) for control nonshocked myocardial slices were 4.03 +/- 0.11 (SE) for total water, 2.16 +/- 0.07 for inulin impermeable space, and 1.76 +/- 0.15 for inulin diffusible space. Shocked myocardial slices showed impaired response to cold incubation (0 degrees C, 60 min). After 2 h of in vivo shock, total tissue water, inulin diffusible space, and inulin impermeable space increased significantly (+19.2 +/- 2.4, +8.1 +/- 1.9, +34.4 +/- 6.1%, respectively) for subendocardium, whereas changes in subepicardium parameters were minimal. Shock-induced cellular swelling was accompanied by an increased total tissue sodium, but no change in tissue potassium. Calcium entry blockade in vivo (lidoflazine, 20 micrograms X kg-1 X min-1 during the last 60 min of shock) significantly reduced subendocardial total tissue water as compared with shock-untreated dogs. In addition, calcium entry blockade reduced shock-induced increases in inulin impermeable space and inulin diffusible space. In vitro myocardial slice studies confirm alterations in subendocardial membrane integrity after 2 h of in vivo hemorrhagic shock. Shock-induced abnormalities in myocardial cell volume regulation are reduced by calcium entry blockade in vivo.

Hypertonic cell volume regulation in mouse thick limbs. I. ADH dependency and nephron heterogeneity

1986 ◽  
Vol 250 (6) ◽  
pp. C907-C919 ◽  
Author(s):  
S. C. Hebert
Keyword(s):  
Cell Volume ◽  
Volume Regulation ◽  
Cell Volume Regulation ◽  
Differential Interference Contrast Microscopy ◽  
Cyclic Monophosphate ◽  
Nacl Absorption ◽  
Nephron Segment ◽  
Interference Contrast Microscopy ◽  
Total Cell Volume

Differential interference contrast microscopy was used in combination with standard electrophysiological techniques in the in vitro perfused mouse medullary (mTALH) and cortical (cTALH) thick ascending limbs of Henle to evaluate the cell volume responses of these nephron segments to sudden increases in peritubular osmolality and to assess the role of antidiuretic hormone (ADH) and net NaCl absorption on hypertonic volume regulation. In the absence of CO2/HCO3- in external media, the cells of the mTALH behaved in a simple osmometric fashion, with an osmotic space equivalent to 70-80% of the total cell volume. However, in CO2/HCO3- -containing media, the cells of the mTALH, but not the cTALH, were able to increase their cell volume to the original volume after shrinkage in peritubular media made hypertonic with either NaCl or mannitol. This volume-regulatory increase response (VRI) in the mTALH was mediated by an increase in intracellular osmoles, and required peritubular ADH, at concentrations that stimulate maximally the rate of net NaCl absorption. This ADH effect on VRI could be mimicked by addition of dibutyryladenosine 3',5'-cyclic monophosphate to the bath in the absence of hormone. However, 10(-4) M luminal furosemide, a concentration that abolishes ADH-dependent NaCl absorption in the mTALH, had no effect on the VRI response. These results indicate that the cells of the mTALH, but not the cTALH, are capable of hypertonic volume regulation, that ADH (via adenosine 3',5'-cyclic monophosphate) is required for expression of the VRI response in the mTALH, and that the effects of ADH on net NaCl absorption and the VRI response in the mTALH are completely dissociable. Thus these results are consistent with a role for ADH in hypertonic VRI in the mammalian mTALH, which may operate to maintain constant cell volume in this nephron segment during antidiuresis.

Effect of osmotic shocks on rabbit kidney cortex slices

1983 ◽  
Vol 244 (6) ◽  
pp. F696-F705
Author(s):  
R. Gilles ◽  
C. Duchene ◽  
I. Lambert
Keyword(s):  
Cell Volume ◽  
Volume Regulation ◽  
Rabbit Kidney ◽  
Kidney Cortex ◽  
Regulation Mechanism ◽  
Kidney Slices ◽  
Regulation Process ◽  
Maximum Cell ◽  
Cortex Slices ◽  
Kidney Cortex Slices

Rabbit kidney cortex slices behave an osmometers when withstanding hyperosmotic or hyposmotic shocks of amplitude up to pi 1/pi 2 = 1.25. For hyposmotic shocks of amplitude larger than or equal to pi 1/pi 2 = 1.50, the maximum swelling achieved is less than what can be expected on the basis of the van't Hoff relation, thereby indicating that a volume regulation process is taking place. Volume regulation in kidney slices can be dissociated into two distinct phases. The first one, of swelling limitation, is very rapid and keeps maximum cell volume at values lower than expected when the tissue is considered as an osmometer. This phase is followed by a slow volume readjustment process during which volume progressively decreases towards control values. The major intracellular osmotic effector loss during both swelling limitation and volume readjustment is Na+. The overall volume regulation process is insensitive to furosemide, vanadate, and bumetanide. Swelling limitation is blocked by addition of ouabain. Contrary to what has been believed previously, there is, however, no need to implicate control of the activity of a ouabain-sensitive, Na+/K+ pump in the Na-dependent volume regulation mechanism.

Correlation between osmoregulation and cell volume regulation

1987 ◽  
Vol 252 (4) ◽  
pp. R768-R773
Author(s):  
M. A. Lang
Keyword(s):  
Amino Acids ◽  
Amino Acid ◽  
Osmotic Pressure ◽  
Cell Volume ◽  
Free Amino Acids ◽  
Volume Regulation ◽  
Free Amino ◽  
Cell Volume Regulation

The euryhaline crab, Callinectes sapidus, behaves both as an osmoregulator when equilibrated in salines in the range of 800 mosM and below and an osmoconformer when equilibrated in salines above 800 mosM. There exists a close correlation between osmoregulation seen in the whole animal in vivo and cell volume regulation studied in vitro. Hyperregulation of the hemolymph osmotic pressure and cell volume regulation both occurred in salines at approximately 800 mosM and below. During long-term equilibration of the crabs to a wide range of saline environments, the total concentration of hemolymph amino acids plus taurine remained below 3 mM. During the first 6 h after an acute osmotic stress to the whole animal, the hemolymph osmotic pressure and Na activity gradually decreased, whereas the free amino acids remained below 3 mM. As the hemolymph osmotic pressure decreased below approximately 850 mosM, the amino acid level began to increase to 17-25 mM. This change was primarily due to increases in glycine, proline, taurine, and alanine. The likely source of the increase in hemolymph free amino acids in vivo is the free amino acid loss from muscle cells observed during cell volume regulation in vitro.

Proximal tubule volume regulation in hyperosmotic media: intracellular K+, Na+, and Cl-

1989 ◽  
Vol 257 (6) ◽  
pp. C1093-C1100 ◽  
Author(s):  
L. Rome ◽  
J. Grantham ◽  
V. Savin ◽  
J. Lohr ◽  
C. Lechene
Keyword(s):  
Proximal Tubule ◽  
Cell Volume ◽  
Volume Regulation ◽  
Electron Probe ◽  
Rabbit Kidney ◽  
Kidney Cortex ◽  
Cell Shrinkage ◽  
Volume Increase ◽  
Regulatory Volume Increase ◽  
Expected Increase

Nonperfused proximal S2 segments from rabbit kidney cortex have been shown to keep cell volume constant as medium osmolality is slowly raised but to shrink and not exhibit regulatory volume increase (RVI) if medium osmolality is abruptly elevated (J. Lohr and J. Grantham. J. Clin. Invest. 78: 1165-1172, 1986). In the current study, 0.5 mM butyrate in the medium 1) extended the range from 361 to 450 mosmol/kgH2O over which cells maintained volume constant as osmolality was gradually raised and 2) restored RVI after cell shrinkage when osmolality was rapidly raised from 295 to 400 mosmol/kgH2O. Volume regulation was associated with net increases in intracellular Na+ and Cl- but no change in K+ (measured by electron probe). The increments in Na+ and Cl- were insufficient to account for the total addition of osmolytes required for volume maintenance or restoration. The fraction of the expected increase in intracellular osmoles accounted for by the increase in [(K+)i + (Na+)i + (Cl-)i] was 52 and 21% for gradual and rapid osmotic changes, respectively. We conclude that butyrate enhances the capacity of S2 segments to regulate volume in hyperosmotic medium by promoting addition of Na+ and Cl- and by other undermined factors.

scholarly journals Volume-activated chloride permeability can mediate cell volume regulation in a mathematical model of a tight epithelium.

1990 ◽  
Vol 96 (2) ◽  
pp. 319-344 ◽  
Author(s):  
J Strieter ◽  
J L Stephenson ◽  
L G Palmer ◽  
A M Weinstein
Keyword(s):  
Mathematical Model ◽  
Cell Volume ◽  
Volume Regulation ◽  
Electrical Potential ◽  
Cell Volume Regulation ◽  
York Academy ◽  
Constant Field ◽  
Chloride Permeability ◽  
Volume Regulatory Decrease ◽  
Tight Epithelium

Cell volume regulation during anisotonic challenge is investigated in a mathematical model of a tight epithelium. The epithelium is represented as compliant cellular and paracellular compartments bounded by mucosal and serosal bathing media. Model variables include the concentrations of Na, K, and Cl, hydrostatic pressure, and electrical potential, and the mass conservation equations have been formulated for both steady-state and time-dependent problems. Ionic conductance is represented by the Goldman constant field equation (Civan, M.M., and R.J. Bookman. 1982. Journal of Membrane Biology. 65:63-80). A basolateral cotransporter of Na, K, and Cl with 1:1:2 stoichiometry (Geck, P., and E. Heinz. 1980. Annals of the New York Academy of Sciences. 341:57-62.) and volume-activated basolateral ion permeabilities are incorporated in the model. MacRobbie and Ussing (1961. Acta Physiologica Scandinavica. 53:348-365.) reported that the cells of frog skin exhibit osmotic swelling followed by a volume regulatory decrease (VRD) when the serosal bath is diluted to half the initial osmolality. Similar regulation is achieved in the model epithelium when both a basolateral cotransporter and a volume-activated Cl permeation path are included. The observed transepithelial potential changes could only be simulated by allowing volume activation of the basolateral K permeation path. The fractional VRD, or shrinkage as percent of initial swelling, is examined as a function of the hypotonic challenge. The fractional VRD increases with increasing osmotic challenge, but eventually declines under the most severe circumstances. This analysis demonstrates that the VRD response depends on the presence of adequate intracellular chloride stores and the volume sensitivity of the chloride channel.

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