Confocal microscopic observation of cytoskeletal reorganizations in cultured shark rectal gland cells following treatment with hypotonic shock and high external K+.

The dogfish shark (Squalus acanthias) rectal gland (SRG) cell has served as a model experimental system for investigating the relationship between the actin cytoskeleton and cell volume regulation. Previous reports employing conventional fluorescence microscopy of tissue slices have shown that cells exposed to high external K+ and hypotonically-induced cell swelling displayed a fading of F-actin staining intensity, particularly at the basolateral cell borders. However, spectroscopic measurement of the F-actin present in similarly treated rectal gland slices failed to demonstrate a net change in F-actin amount. In an effort to resolve the structural reorganizations of F-actin which may be occurring during high K+ and hypotonic shock treatments, we have used cultured SRG cells in conjunction with confocal microscopic immunocytochemical localization techniques to examine actin filament, microtubule, and cytokeratin filament dynamics under these two experimental conditions. The results reveal that F-actin in control cells exists in an array of parallel linear bundles (which do not appear to be stress fiber-like given their lack of staining for myosin II or alpha-actinin) that is reorganized to a punctate pattern in hypotonic shock and a dense meshwork in high K+. The linear bundle pattern of F-actin returns in cells undergoing regulatory volume decrease. Quantitative western blotting of F-actin in SRG cell detergent extracted cytoskeletons indicates no significant difference in the relative amounts of F-actin present in control, hypotonic shocked, or high K+ cells. Anti-tubulin and anti-cytokeratin labeling of the treated SRG cells suggest that these other major cytoskeletal elements are not significantly altered by the treatments. Taken together, our results reinforce the concept that there is an association between the structural organization of the actin cytoskeleton and cell volume regulation in the SRG epithelial cells.

William Hewson's studies of red blood corpuscles and the evolving concept of a cell membrane.

The botanist Carl Nägeli is generally considered to have laid the basis for the cell membrane concept by his 1855 study of the osmotic properties of plant cells. It is shown here that William Hewson in 1773 presented cogent experimental evidence for the concept of a cell membrane in red blood corpuscles. Although his work was largely confirmed in subsequent studies, and a cell membrane became an attribute of the cell in T. Schwann's cell theory, the idea of a cell membrane was rejected by anatomists in 1861 essentially on theoretical grounds, and plant physiologists did not mention Hewson's pioneering endeavour. As a consequence, Hewson's work has been ignored to this day. A broad cell membrane concept then had to await the ingenious work of Overton, started in 1895. The possible reasons for these lapses in scientific recognition are analyzed.

Na(+)-dependent and Na(+)-independent systems of choline transport by plasma membrane vesicles of A549 cell line.

Membrane vesicles of A549 lung cells accumulate choline by two pathways: the Na(+)-independent uphill uptake of choline [Michaelis-Menten constant (Km) approximately 44 microM; steady-state gradient approximately 45 at 5 microM external choline] is dependent on a transmembrane H+ gradient, is relatively insensitive to hemicholinium-3, is amiloride sensitive, and is abolished by valinomycin plus carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP). The Na(+)-dependent active choline uptake (Km approximately 4 microM, inhibitor constant for hemicholinium-3 approximately 0.1 microM), is specific for Na+, is amiloride and FCCP sensitive, and is electrogenic: the overshoot using K(+)-loaded vesicles and NaCl gradient was increased by valinomycin. The time of the overshoot peak, T was approximately 90 s in a NaSCN medium (or in presence of other lipid-soluble anions), a value close to that for alpha-aminoisobutyrate as substrate (T = approximately 1.5 min). T was lengthened in NaCl medium to approximately 10 min, and the overshoot was abolished by impermeant anions. External Cl- is not required for the choline uptake: valinomycin produced an overshoot in the presence of only impermeant anions, with T approximately 90 s. Most of the above properties are shared by the high-affinity Na(+)-dependent choline transport in synaptosomes. The characteristics of the Na(+)-dependent choline uptake by membrane vesicles of A549 cells are consistent with an electrogenic choline(+)-Na+ cotransport, with the rate-limiting anion (e.g., Cl-) influx balancing the positive charges transferred into the vesicles. The data are also consistent with an involvement of an amiloride-sensitive choline+/H+ antiport (or choline(+)-OH- symport) in the low- and high-affinity choline uptake pathways.

Transport of choline by plasma membrane vesicles from lung-derived epithelial cells.

A549 cells, a lung epithelium-derived cell line, were used as a model system to study choline transport by granular pneumocytes. Intact cells accumulated free choline against a concentration gradient by a low-affinity transport system with kinetic characteristics similar to that previously described for granular pneumocytes (Am. J. Respir. Cell Mol. Biol. 1: 455, 1989). Membrane vesicles prepared from these cells showed a 10-fold enrichment in plasma membrane marker enzymes with a vesicular H2O space of 5.7 +/- 0.05 (SE) microliters/mg protein. Vesicles showed a time- and concentration-dependent uptake of free [3H]choline in Na(+)-free medium. With 5 microM choline, choline uptake reached an apparent steady-state concentration gradient (inside/outside) of 50. 3H that was membrane associated ("bound" choline) represented approximately 5% of total uptake. In the presence of an initial gradient of NaCl, choline uptake showed an overshoot with a plateau value similar to Na(+)-free conditions; a similar effect was observed for plasma membrane vesicles from rat lung type 2 epithelial cells. The steady-state uptake of choline was inhibited at low pH (6.5) and by the presence of valinomycin or carbonyl cyanide p-tri-fluoromethoxyphenylhydrazone and was abolished when both were present. These results show that plasma membrane vesicles from A549 cells accumulate choline by binding to the membranes and by Na(+)-dependent and -independent transport mechanisms, the latter apparently reflecting a transmembrane proton gradient.

Polarity of transport of 2-deoxy-D-glucose and D-glucose by cultured renal epithelia (LLC-PK1).

At least two types of glucose transporter exist in cultured renal epithelial cells, a Na(+)-glucose cotransporter (SGLT), capable of interacting with D-glucose but not 2-deoxy-D-glucose (2dglc) and a facilitated transporter (GLUT) capable of interacting with both D-glucose and 2dglc. In order to examine the polarity of transport in cultured renal epithelia, 2dglc and D-glucose uptakes were measured in confluent cultures of LLC-PK1 cells grown on collagen-coated filters that permitted access of medium to both sides of the monolayer. The rates of basolateral uptake of both 1 mM glucose (Km 3.6 mM) and 1 mM 2dglc (Km 1.5 mM) were greater than apical uptake rates and the (apical-to-basolateral)/(basolateral-to-apical) flux ratio was high for glucose (9.4) and low for 2dglc (0.8), thus, confirming the lack of interaction of 2dglc with the apical SGLT. Specific glucose transport inhibitor studies using phlorizin, phloretin and cytochalasin B confirmed the polarised distribution of SGLT and GLUT in LLC-PK1 cells. Basolateral sugar uptake could be altered by addition of insulin (1 mU/ml) which increased 2dglc uptake by 72% and glucose uptake by 50% and by addition of 20 mM glucose to the medium during cell culture which decreased 2dglc uptake capacity at confluence by 30%. During growth to confluence, 2dglc uptake increased to a maximum, then decreased at the time of confluence, coincident with a rise in uptake capacity for alpha-methyl-D-glucoside, a hexose that interacts only with the apical SGLT. It was concluded that the non-metabolisable sugar 2dglc was a useful, specific probe for GLUT in LLC-PK1 cells and that GLUT was localised at the basolateral membrane after confluence.

Inhibitors of choline transport in alveolar type II epithelial cells.

Isolated alveolar type II epithelial cells (granular pneumocytes) from rat lung accumulate free choline against a concentration gradient by an energy-dependent saturable transport process with apparent Km approximately 18 microM. In order to evaluate the structural requirements for choline transport by these cells, the inhibition of the initial rate of cellular uptake of [3H]choline (5 microM) by its analogue was measured. There was no significant inhibition of substrate uptake by analogues lacking an amino group while the presence of a quaternary nitrogen was most effective. N,N'-dimethylethanolamine (apparent Ki, 7 microM) and n-decylcholine (apparent Ki, 0.5 microM) were potent competitive inhibitors of choline transport. Substitution of the hydroxyl group in choline greatly diminished the inhibitory effect; fluorocholine, thiocholine, betaine, and betaine aldehyde showed little or no inhibition. This requirement for a hydroxyl group raises the possibility of hydrogen bonding of choline with the transport protein. The choline transport system in granular pneumocytes appears to differ from that in synaptosomes by the lower affinity of the carrier for substrate and for hemicholinium-3 and from that in erythrocytes by the role of the hydroxyl in the substrate molecule. The availability of inhibitory analogues for choline transport will facilitate isolation and study of the granular pneumocyte choline transport protein.

Hypotonicity and cell volume regulation in shark rectal gland: role of organic osmolytes and F-actin.

Hypotonic stress (reduction of external tonicity from approximately 900 mosM and 295 mM NaCl to approximately 600 mosM and 135 mM NaCl) produced a relatively slow regulatory volume decrease (RVD) in dogfish shark (Squalus acanthias) rectal gland cells. During the 5-h experiment, cell K+ content remained unchanged; cell content of Na+ and Cl- dropped in the initial swelling phase by some 50% (reflecting the corresponding reduction in medium NaCl), and then remained unchanged during volume recovery phase. Also, cellular fluxes of 86Rb+ and urea were not affected by hypotonic stress. However, hypotonicity enhanced 10- to 20-fold the efflux of organic cell osmolytes taurine, betaine, and trimethyloxamine, and this accounted for the loss of osmotically obliged water during RVD. Enhancement of osmolyte efflux by hypotonic stress was abolished by readjusting the low-Na+ saline to isotonicity (approximately 900 mosM) with innocuous cations (choline+, Li+, or N-methylglucamine+). The results suggest that reduction of medium tonicity may be the determinant for the RVD response to hypotonic stress. The above properties of the observed RVD were also displayed when studying changes on cell F-actin at the basolateral cell face; hypotonic stress (medium with 135 mM NaCl) produced a rapid disappearance of fluorescence related to this cytoskeletal component, whereas no such changes were seen in low-Na+ salines made isotonic with choline or N-methylglucamine chloride nor in a saline made hyposmolar by omitting urea. Hence, hypotonicity is required to affect F-actin organization (depolymerization?). These changes of F-actin fluorescence are transient; they were completed within 5-10 min of hypotonic stress, and afterwards a gradual reconstitution of cell F-actin organization was seen. The above observations are consistent with the assumption that, in shark rectal gland cells, transient loss of cytoskeleton (F-actin) organization at the basolateral cell face, induced by hypotonicity, brings about a selective efflux of organic osmolytes, thus producing the observed RVD.

pCMBS-induced swelling of dogfish (Squalus acanthias) rectal gland cells: role of the Na+,K(+)-ATPase and the cytoskeleton.

(1) 0.1-1.0 mM p-chloromercuribenzene sulfonate (pCMBS) and some other organic mercurials produce a swelling of slices of dogfish shark (Squalus acanthias) rectal glands, with an uptake of cell Na+ and a loss of K+. In contrast, 1 mM N-ethylmaleimide (NEM) does not swell rectal gland cells (RGC), while affecting cell cations. (2) The slow entry of [203Hg]pCMBS is linearly related to its external concentration (10 microM-1 mM) and a small accumulation of pCMBS (apparent gradient about 3) in the cells occurs in 2 h. Cell 203Hg rapidly washes out of the cells (fast rate constant 0.153.min-1; slow rate constant 0.0067.min-1), and this efflux is accelerated by 1mM dithiothreitol. Thus, a major portion of pCMBS inter-acts rather loosely with cell components. (3) pCMBS and NEM share: (a) a negligible effect on the efflux of 86Rb+ and of [14C]urea; (b) a gradual inhibition of the cell Na+,K(+)-ATPase activity. (4) NEM as well as agents lowering cell glutathione accelerate and increase the pCMBS-induced cell swelling. Conditions inhibiting the Na+,K(+)-ATPase (ouabain, absence of Na+) have the same effect. (5) pCMBS, but not NEM produce a disappearance of the F-actin-phalloidin fluorescence independent of cell volume changes, particularly at the basolateral RGC membrane. (6) The data are consistent with the following set of events: (a) pCMBS (but not NEM) affects the cell membrane by increasing the efflux of the cell osmolyte taurine (Ziyadeh et al. (1988) Biochim. Biophys. Acta 943, 43-52 and unpublished data); (b) on entry into the cells, pCMBS and NEM interact with cell -SH, including those of the Na+,K(+)-ATPase; this action produces the observed changes in cell cations. Also, pCMBS, but not NEM, decrease F-actin at the membrane; (c) the inhibition of the Na+,K(+)-ATPase activity together with the decreased resistance of the cell membrane to stretch (absence of F-actin) produces the observed pCMBS-induced cell swelling by osmotic forces (intracellular non-diffusible anions).

Choline transport by lung epithelium.

The uptake of [3H]choline was investigated using isolated perfused rat lungs and primary cultures of granular pneumocytes isolated by tryptic digestion of rat lungs. Metabolic products were separated from free choline by chloroform:methanol extraction and column chromatography. Tissue-associated [3H]choline increased progressively in the perfused lung, and estimated mean intracellular concentration at 2 h was 12 times the extracellular concentration (5 microM). Choline uptake was inhibited by ventilation with CO and by perfusion with the choline analog, hemicholinium-3 (HC-3). Isolated granular pneumocytes also accumulated choline against a concentration gradient by an energy-dependent process. The concentration for half-maximal uptake, after correction for the diffusion component, was estimated at 18 +/- 4 microM (mean +/- SE; n = 3), and the estimated maximal rate of uptake was 213 +/- 44 pmol/min/microliter cell water. HC-3 inhibited uptake by approximately 50% at a concentration of 10(-4) M. There was no effect on uptake when Na+ in the medium was replaced by Li+ or N-methylglucamine+. These results indicate that granular pneumocytes possess a transport system that results in accumulation of choline against a concentration gradient. The characteristics of uptake indicate that this system is similar to the low affinity choline transport system of other organs.

In vitro transport of L-alanine by equine cecal mucosa.

When sheets of mucosa from the cecum of clinically normal horses were incubated in vitro with radiolabeled L-alanine, they could accumulate this amino acid against an apparent concentration gradient after 60 to 150 minutes of incubation. The active transport system for L-alanine was on the serosal surface of the mucosal sheet only. L-Alanine accumulation at 60 minutes was partly inhibited by 20 mM glycine (P less than 0.01), 0.5 mM ouabain (P less than 0.05), and Na deprivation (P less than 0.02). Anoxia for 60 minutes increased L-alanine accumulation, but had adverse effects on cell structure and intracellular cation distributions. Transmucosal fluxes induced a small, but significant (P less than 0.05), net secretion of L-alanine, and the mean (+/- SEM) transmucosal potential difference was 7.3 +/- 0.7 mV over the period of flux measurement. It was concluded that L-alanine was accumulated by the serosal surface of the cecal mucosa, possibly to provide substrate for tissue metabolism. There was no evidence that the cecal mucosa could actively transport this amino acid from the luminal bathing medium.

K+-induced swelling of the dogfish shark (Squalus acanthias) rectal gland cells is associated with changes of the cytoskeleton.

Dogfish shark (Squalus acanthias) rectal gland cells swell massively when incubated in elasmobranch media in which Na+ was equivalently replaced by K+; this swelling was abolished when the impermeant gluconate replaced Cl-, while the cell depolarization was comparable in both media. The K+-effect was associated with (a) an increase of the steady-state 42K (and 86Rb) efflux (particularly of the rate constant of the fast cellular efflux component) and a rearrangement of the respective cellular pools of K+; (b) an alteration of cell morphology and the pattern of the F-actin staining along the basolateral cell membrane as revealed with fluorescent analogs of phallacidin. These changes were independent of cell volume, being identical in KCl and K-gluconate media. The observations were specific for K+ (and Rb+): replacement of media Na+ by Li+ (which is not actively extruded by the cells), or the presence of ouabain, produced only minor swelling without affecting cell morphology and F-acting distribution. The results are consistent with the following view: as opposed to Na+ or Li+ media, the K+-induced changes of the cortical F-actin component of the cytoskeleton permit the observed massive cell swelling due to the osmotic contribution of intracellular impermeant anion(s).

Propionate induces cell swelling and K+ accumulation in shark rectal gland.

Small organic anions have been reported to induce cell solute accumulation and swelling. To investigate the mechanism of swelling, we utilized preparations of rectal gland cells from Squalus acanthias incubated in medium containing propionate. Propionate causes cells to swell by diffusing across membranes in its nonionic form, acidifying cell contents, and activating the Na+-H+ antiporter. The Na+-H+ exchange process tends to correct intracellular pH (pHi), and thus it maintains a favorable gradient for propionic acid diffusion and allows propionate to accumulate. Activation of the Na+-H+ antiport also facilitates Na+ entry into the cell and Nai accumulation. At the same time Na+-K+-ATPase activity, unaffected by propionate, replaces Nai with Ki, whereas the K+ leak rate, decreased by propionate, allows Ki to accumulate. As judged by 86Rb+ efflux, the reduction in K+ leak was not due to propionate-induced cell acidification or reduction in Cli concentration. Despite inducing cell swelling, propionate did not disrupt cell structural elements and F actin distribution along cell membranes.

Accumulation of some hexoses in adipocytes: properties of the system.

Adipocytes accumulate 2-deoxy-D-glucose (2-DG) against significant chemical gradients (J. Foley and J. Gliemann. Biochim. Biophys. Acta 648: 100-106, 1981). The specificity of this accumulation process was examined. Isolated rat adipocytes incubated at 37 degrees C with 0.1 mM hexoses accumulated free 2-deoxy-D-galactose (2-DGal) or D-galactose (Gal) against steady-state gradients of 5.5 +/- 1.2 and 2.5 +/- 0.7, respectively. Like 2-DG, both 2-DGal and Gal are substrates for phosphorylation. Insulin and insulin-mimetic agents increased steady-state accumulations of Gal, 2-DGal, and free and phosphorylated 2-DG (100 nM insulin increased free 2-DG from 2.1 +/- 0.2 to 6.6 +/- 0.3 mM; external 2-DG = 0.1 mM). Removal of extracellular calcium or sodium or the presence of A23187 or ouabain failed to inhibit 2-DG accumulation. Plasma membrane permeabilization induced by either digitonin or high-voltage discharge produced a loss of cellular 2-DG and 2-DG-phosphate without affecting 3-O-methyl-D-glucose equilibration. The data indicate that neither transmembrane ionic gradients nor intracellular compartmentation suffice as explanations of the mechanism of the accumulation process. The possible role of phosphorylation in the process of hexose accumulation is discussed.

2-Deoxy-D-glucose accumulation in adipocytes: apparent transport discrimination between 2-deoxy-D-glucose and 3-O-methyl-D-glucose.

The uphill accumulation of free 2-deoxy-D-glucose and 2-deoxy-D-glucose 6-phosphate in rat adipocytes was found not to affect the steady-state distribution of 3-O-methyl-D-glucose although both hexoses share a common transport pathway. This observation argues against a possible effect of 2-deoxy-D-glucose phosphate on the equilibrating nature of the carrier. The results are discussed in light of hypotheses advanced to explain free 2-deoxy-D-glucose accumulation in a variety of cells.

The accumulation of free and phosphorylated sugars in adipocytes based on a dynamic diffusion barrier.

The simple theory of a dynamic diffusion barrier is described and it is shown how this could account for the accumulation, in adipocytes, of those free sugars which are also phosphorylated. The standing concentration gradient established by this mechanism depends on the recycling of free sugar and sugar phosphate in submembrane structures which start in juxtaposition to conventional membrane hexose transporters. Although a continual expenditure of metabolic energy is involved, there can be a net gain from the potential-energy store of accumulated substrates. The hypothesis leads to a series of simple equations which can be used as the basis for computer simulations of experimental procedures.

Taurine and cell volume maintenance in the shark rectal gland: cellular fluxes and kinetics.

Tissue slices of shark rectal gland are studied to examine the kinetics of the cellular fluxes of taurine, a major intracellular osmolyte in this organ. Maintenance of high steady-state cell taurine (50 mM) is achieved by a ouabain-sensitive active Na+-dependent uptake process and a relatively slow efflux. Uptake kinetics are described by two saturable taurine transport components (high-affinity, Km 60 microM; and low-affinity, Km 9 mM). [14C]Taurine uptake is enhanced by external Cl-, inhibited by beta-alanine and unaffected by inhibitors of the Na+/K+/2Cl- co-transport system. Two cellular efflux components of taurine are documented. Incubation of slices in p-chloromercuribenzene sulfonate (1 mM) reduces taurine uptake, increases efflux of taurine and induces cell swelling. Studies of efflux in isotonic media with various cation and anion substitutions demonstrate that high-K+ markedly enhances taurine efflux irrespective of cell volume changes (i.e. membrane stretching is not involved). Moreover, iso-osmotic cell swelling induced in media containing propionate is not associated with enhanced efflux of taurine from the cells. It is suggested that external K+ exerts a specific effect on the cytoplasmic membrane to increase its permeability to taurine.

Glucose transport and metabolism in rat renal proximal tubules: multicomponent effects of insulin.

Glucose transport and metabolism, and the effect of insulin thereon, was studied using suspensions of rat renal tubules enriched in the proximal component. [U-14C]Glucose oxidation is a saturable process (Km 3.1 +/- 0.2 mM; Vmax 14 +/- 0.2 mumole 14CO2 formed/g tissue protein per h). Glucose oxidation and [14C]lactate formation from glucose are inhibited in part by phlorizin and phloretin: the data suggest that the rate-limiting entry of glucose into the cell metabolic pool occurs by both the Na-glucose cotransport system (at the brush border) and the equilibrating, phloretin-sensitive system (at the basal-lateral membrane). Raising external glucose from 5 to 30 mM markedly increases aerobic and anaerobic lactate formation. Gluconeogenesis from lactate is not affected by variations of glucose concentrations. 24 h after streptozotocin administration, aerobic lactate formation is enhanced, as is the uptake of methyl alpha-D-glucoside by the tubules, while anaerobic glycolysis is depressed. Streptozotocin treatment (ST) increases both the Km and Vmax of glucose oxidation; gluconeogenesis and lactate oxidation are not affected. The effect of streptozotocin treatment on lactate formation are abolished by 1 mU/ml insulin. Streptozotocin treatment increases tissue hexokinase activity, decreases glucose-6-phosphatase, but has no significant effect on fructose-1,6-diphosphatase; phosphoenolpyruvate carboxykinase and pyruvate dehydrogenase. The data demonstrate fast streptozotocin-induced changes in cellular enzymes of carbohydrate metabolism. The enhancing effect of streptozotocin on methyl alpha-glucoside uptake is transient: 8 days after administration of the agent, no significant difference from controls is found. It is concluded that under the given experimental conditions insulin enhances the equilibrating glucose entry by the phloretin-sensitive pathway at the basal-lateral membrane, and transiently inhibits the Na-glucose cotransport system.

Basal-lateral transport and transcellular flux of methyl alpha-D-glucoside across LLC-PK1 renal epithelial cells.

The characteristics of methyl alpha-D-glucoside transport by the LLC-PK1 cell line are extended by a study of the interaction of this glucose analog with the basal-lateral membrane of these cells: 1 mM methyl alpha-D-glucoside enters LLC-PK1 cells across the basal-lateral membrane 10-times more slowly than when entering across the apical membrane; neither 10 mM glucose nor 10 mM methyl alpha-D-glucoside affect the rate of methyl glucoside uptake at the basal lateral membrane; 0.1 mM phlorizin in the apical hemichamber significantly decreases the rate at which methyl glucoside enter the cell when methyl glucoside is present in the basal-lateral hemichamber; the methyl glucoside transcellular flux ratio, Ja/Jb (apical to basal vs. basal to apical) is 15, whereas Ja/Jb for D-mannitol equals 1; and basal-lateral to apical fluxes (Jb) of mannitol consistently exceed those of methyl glucoside. These results demonstrate that methyl glucoside, unlike glucose, is accumulated within these cells to a high degree because of the limited ability of methyl glucoside to exit the cells by a carrier-mediated pathway. They also raise the important caveat for any studies with glucose (and other low-molecular-weight substrates) by showing that a monosaccharide presented to one surface of these cells will traverse the cell sheet (in part) by the intercellular route and will enter the cell at the unintended cell surface. The ability of the tight junctions of this intercellular route to discriminate between open-chain molecules, such as mannitol, vs. closed ring structures, like methyl glucoside, is also described.

Trimethylamine oxide and the maintenance of volume of dogfish shark rectal gland cells.

Determinants of the steady-state vol of the dogfish shark (Squalus acanthias) rectal gland cells were studied. The cellular levels of trimethylamine oxide (TMAO) in fresh tissue and slices incubated aerobically 60 min in standard (TMAO-free) elasmobranch saline were close to those in the plasma (71 +/- 5 mM S.E.M.); therefore, under these conditions, the cell membrane appears to be impermeable to this solute. However, depolarization of the cells in high-K+ media produced a rapid loss of TMAO. Thus, TMAO is a major, effectively impermeant solute in the rectal gland cells. The osmolarity of cell solutes in tissue water (fresh and incubated slices) did not differ significantly from values in the plasma or incubation medium, demonstrating the absence of an osmotic pressure gradient across the cell membrane. An analysis of a simple model of cell solutes under steady-state conditions shows that the presence of an (effectively) impermeant osmolyte decreases the cellular concentration of bulk cations. The analysis is consistent with available observations on the distribution of cell Na+ and K+ in tissues containing high concentrations of (nitrogeneous) osmolytes. One simplifying assumption of the model, i.e., identity (or closeness) of the respective reflection coefficients sigma for Na+ and K+ passage through the cell membranes could not be verified. Compared to available data on the steady-state cellular fluxes of 42K+ in slices of the rectal gland, the uptake of 22Na+ by the tissue was slow (the derived rate constant k' = 0.017 min-1, i.e., about one tenth of that for K+).(ABSTRACT TRUNCATED AT 250 WORDS)

Glucose transport in intestinal epithelia of winter flounder.

D-Glucose (Glc) transport was studied in stripped intestinal epithelial sheets of the winter flounder Pseudopleuronectes americanus. At 1 mM Glc and 15 degrees C, Glc uptake did not occur against a concentration gradient (free cell Glc 0.78 +/- 0.06 mM) but was inhibited by 0.5 mM phlorizin or ouabain. [U-14C]-Glc oxidation to 14CO2 was also depressed by these agents or the absence of Na+ and was saturable (Km 3.3 +/- 1.2 mM Glc; maximal velocity at saturating substrate concentration (Vmax) 4.0 +/- 2.0 mumol X g wet wt-1 X h-1]. No electrical transcellular manifestations of the Na-Glc cotransport system were seen in regular media. In the absence of Cl-, Glc and nonmetabolizable Glc analogs (alpha-methyl-D-glucopyranoside or 3-O-methyl-D-glucose) added mucosally elicited an increase in a serosally directed short-circuit current that was inhibitable by 0.5 mM mucosal phlorizin or 0.1 mM serosal ouabain and dependent on the external sugar concentration [Km 2.3 +/- 1.8 mM (range 0.6 to 6.1); Vmax 2.4 +/- 1.1 microA X cm-2 (range 0.8-4.2)]. Vmax for L-leucine transport was fivefold greater [13.4 +/- 7.3 microA X cm-2 (range 4.6-20.7)]. These results indicate the presence of a mucosal Na+-linked Glc absorptive system and reflect the paucity of transport sites for Glc relative to leucine.