ISSN:1420-4096    

DOI:10.1159/000173155

出版商:S. Karger AG    

年代:1988

数据来源: Karger

ISSN:1420-4096    

DOI:10.1159/000173156

出版商:S. Karger AG    

年代:1988

数据来源: Karger

ISSN:1420-4096    

DOI:10.1159/000173157

出版商:S. Karger AG    

年代:1988

数据来源: Karger

摘要:

Cell volume is determined by the content of osmotically active solute (cell osmoles) and the osmolarity of the extracellular fluid. Cell osmoles consist of non-diffusible and diffusible solutes. A large fraction of the diffusible cation content balances negative charges on the non-diffusible solutes. The content of diffusible solutes is determined by the electrochemical gradients driving them across the plasma membrane and the availability and activity of transport pathways in the membrane. The classical view that the sodium pump offsets passive leaks must be modified to accomodate the contributions of a number of secondary active transport processes, as well as to allow for changes in cell nondiffusible osmoles and in their net negative charge. The behaviour of cells in anisosmotic media is often different from that predicted for a perfect osmometer. In many cases this is a consequence of changes in cell osmole content. However, caution is required in extrapolating from in vitro responses of isolated cells to large, acutely induced changes in medium osmolality to the responses of tissues in vivo to more subtle changes in extracellular osmolality.

ISSN:1420-4096    

DOI:10.1159/000173158

出版商:S. Karger AG    

年代:1988

数据来源: Karger

摘要:

There is good evidence that the three main compartments of the brain, i.e. extracellular space, neurones and glial cells, change their volume during physiological and pathophysiological neuronal activity. However, there is strikingly little knowledge about the mechanisms underlying such alterations in cell volume. For this purpose, a better understanding of the electrophysiological behavior of the neurones and glial cells during volume changes is necessary. Examples are discussed for which changes in cell volume can be derived from the underlying changes in membrane permeabilities. Volume regulatory mechanisms in the brain have not been described under isotonic conditions. However, a rapid volume regulatory decrease is occurring in cultured glial cells during exposure to hypotonic solutions. In contrast, in these cells no volume regulatory increase was found during superfusion with hypertonic media. On the other hand, the entire brain is able to compensate chronic hypertonic perturbations within hours to days. Interestingly, not only ion fluxes induce cellular volume changes but, in turn, water movements can also influence ion fluxes in both neurones and glial cells. With respect to this it should be considered that volume regulatory membrane processes might not exclusively be activated by changes in transmembranal ion gradients, but also by changes of membrane surface shape. Future studies on cellular mechanisms of volume regulation in the brain should imply a combined use of recent techniques such as computerized video-imaging, radiotracer flux measurements and ion-sensitive microelectrodes in defined cell cultures. Optical monitoring and ion-sensitive microelectrodes should enable measurements of volume changes in identified cellular elements of intact nervous structures such as brain slices.

ISSN:1420-4096    

DOI:10.1159/000173159

出版商:S. Karger AG    

年代:1988

数据来源: Karger

摘要:

Both proximal renal tubule cells and cultured Madin-Darby canine kidney (MDCK) cells are capable of regulating their volume in hypotonic media. Regulatory cell volume decrease in proximal straight tubules is impaired by barium, amiloride and acetazolamide and depends on the presence of bicarbonate and of sodium, whereas it is unaffected by complete removal of extracellular chloride. The observations may point to parallel loss of potassium through potassium channels as well as of bicarbonate and sodium via a bicarbonate-sodium cotransport. Alternatively, potassium/hydrogen ion exchange or potassium bicarbonate cotransport could be involved. In MDCK cells, exposure to hypotonic media apparently leads to the activation of an anion channel, while potassium conductance is rather decreased. In both proximal tubules and MDCK cells, volume regulatory decrease is possibly triggered by leucotrienes, which may be released during cell swelling. Cell volume is altered in a variety of conditions even at isotonic extracellular fluid and cell volume-regulatory mechanisms are likely to participate in regulation of renal transepithelial transport.

ISSN:1420-4096    

DOI:10.1159/000173160

出版商:S. Karger AG    

年代:1988

数据来源: Karger

摘要:

Cells of the renal medulla adapt osmotically to varying external electrolyte concentrations mainly by changing the intracellular content of small organic osmoeffectors (osmolytes) such as sorbitol, inositol and trimethylamines. This implies that despite extreme variations in extracellular tonicity the intracellular concentrations of monovalent electrolytes are stabilized at levels optimal for enzyme function and cell metabolism. In contrast to inorganic electrolytes these organic osmolytes are metabolically neutral and thus do not affect cell metabolism. In addition, some of these organic osmoeffectors, the trimethylamine compounds, are known to counteract the deleterious effects of high urea concentrations (prevailing in antidiuresis) on structure and function of cell proteins.

ISSN:1420-4096    

DOI:10.1159/000173161

出版商:S. Karger AG    

年代:1988

数据来源: Karger

摘要:

Cell volume regulation occurs in both tight, Na+-transporting epithelia (e.g., frog skin) and in leaky, NaCl-transporting epithelia (e.g., amphibian gallbladder). In tight epithelia volume regulation occurs only in response to cell swelling, i.e. only regulatory volume decrease (RVD) is observed, whereas in leaky epithelia cell volume regulation has been observed in response to osmotic challenges that either swell or shrink the cells. In other words, both RVD and regulatory volume increase (RVI) are present. Both volume regulatory responses involve stimulation of ion transport in a polarized fashion: in RVD the response is basolateral KC1 efflux, whereas in RVI it is apical membrane NaCl uptake. The loss of KCl during RVD appears to result in most instances from increases in basolateral electrodiffusive K+ and Cl- permeabilities. In gallbladder, concomitant activation of coupled KCl efflux may also occur. The RVI response includes activation of apical membrane cation (Na+/H+) and anion (Cl-/HCO-3) exchangers. It is presently unclear whether the net ion fluxes resulting from activation of these transporters, during either RVD or RVI, account for the measured rates of restoration of cell volume. In gallbladder epithelium, RVD is inhibited by agents which disrupt microfilaments or interfere with the Ca2+-calmodulin system. These pharmacologic effects are absent in RVI. Some steps in the chain of events resulting in either RVI or RVD have been established, but the signals involved remain largely unknown. There is reason to suspect a role of intracellular pH in the case of RVI and of membrane insertion of transporters in the case of RVD, possibly with causal roles of both intracellular Ca2+ and the cytoskeleton in the latter.

ISSN:1420-4096    

DOI:10.1159/000173162

出版商:S. Karger AG    

年代:1988

数据来源: Karger

摘要:

The maintenance of liver cell volume in isotonic extracellular fluid requires the continuous supply of energy: sodium is extruded in exchange for potassium by the sodium/potassium ATPase, conductive potassium efflux creates a cell-negative membrane potential, which expelles chloride through conductive pathways. Thus, the various organic substances accumulated within the cell are osmotically counterbalanced in large part by the large difference of chloride concentration across the cell membrane. Impairment of energy supply leads to dissipation of ion gradients, depolarization and cell swelling. However, even in the presence of ouabain the liver cell can extrude ions by furosemide-sensitive transport in intracellular vesicles and subsequent exocytosis. In isotonic extracellular fluid cell swelling may follow an increase in extracellular potassium concentration, which impairs potassium efflux and depolarizes the cell membrane leading to chloride accumulation. Replacement of extracellular chloride with impermeable anions leads to cell shrinkage. During excessive sodium-coupled entry of amino acids and subsequent stimulation of sodium/potassium-ATPase by increase in intracellular sodium activity, an increase in cell volume is blunted by activation of potassium channels, which maintain cell membrane potential and allow for loss of cellular potassium. Cell swelling induced by exposure of liver cells to hypotonic extracellular fluid is followed by regulatory volume decrease (RVD), cell shrinkage induced by reexposure to isotonic perfusate is followed by regulatory volume increase (RVI). Available evidence suggests that RVD is accomplished by activation of potassium channels, hyperpolarization and subsequent extrusion of chloride along with potassium, and that RVI depends on the activation of sodium hydrogen ion exchange with subsequent activation of sodium/potassium-ATPase leading to the respective accumulation of potassium and bicarbonate. In addition, exposure of liver to anisotonic perfusates alters glycogen degradation, glycolysis and probably urea formation, which are enhanced by exposure to hypertonic perfusates and depressed by hypotonic perfusates.

ISSN:1420-4096    

DOI:10.1159/000173163

出版商:S. Karger AG    

年代:1988

数据来源: Karger

摘要:

The Ehrlich ascites tumor cell has been used as a model of an unspecialized mammalian cell, in an attempt to disclose the mechanisms involved in the regulation of cellular water and salt content. In hypotonic medium Ehrlich cells initially swell as nearly perfect osmometers, but subsequently recover their volume within about 10 min with an associated net loss of KC1, amino acids, taurine and cell water. The net loss of KCl takes place mainly via separate, conductive K+ and Cl- transport pathways, and the net loss of taurine through a passive leak pathway. Ca2+ and calmodulin appear to be involved in the activation of the K+ and Cl- channels, as well as the taurine leak pathway. In hypertonic medium Ehrlich cells initially shrink as osmometers, but subsequently recover their volume with an associated net uptake of KCl and water. In this case, the net uptake of KC1 is the result of the activation of an electroneutral, Na+- and Cl-dependent cotransport system with subsequent replacement of cellular Na+ by extracellular K+ via the Na+/K+ pump. In the present review we describe the ion and taurine transporting systems which have been identified in the plasma membrane of the Ehrlich ascites tumor cell. We have emphasized the selectivity of these transport pathways and their activation mechanisms. Finally, we propose a model for the activation of the conductive K+ and Cl- transport pathways in Ehrlich cells which includes Ca2+, leukotrienes, and inositol phosphate as intracellular second messengers.

ISSN:1420-4096    

DOI:10.1159/000173164

出版商:S. Karger AG    

年代:1988

数据来源: Karger