Pulmonary epithelial sieving of small solutes in rat lungs

Transport and consumption of glucose from the air spaces of isolated, fluid-filled lungs can result in significantly lower glucose concentrations in the air spaces than in the perfusate compartment (11). This concentration difference could promote the osmotic movement of water from the air spaces to the perfusate, but the rate of fluid extraction from the air spaces would then be limited by the rates of electrolyte transport through the epithelium. In the present study, measurements were made of solute and water losses from the air spaces of fluid-filled rat lungs and the transport of these solutes and water into the vasculature after addition of hypertonic glucose or sucrose to the perfusate. Increases in the concentrations of Na+, Cl-, K+, and labeled mannitol in the air space were initially comparable to those of albumin labeled with Evans blue. Similarly, decreases in electrolyte concentrations in the perfusate were comparable to those of labeled albumin, indicating that very little solute accompanied the movement of water out of the lungs. Nor was evidence found that exposure of the vasculature to hypertonic glucose resulted in an increase in the rate at which fluid was reabsorbed from the air spaces over a 1-h interval, aside from an initial, abrupt loss of solute-free water from the lungs. These observations suggest that perfusion of fluid-filled lungs with hypertonic solutions of small solutes results in the extraction of water from the air spaces and pulmonary parenchyma across membranes that resist the movement of electrolytes and other lipophobic solutes.     

The effect of osmotically induced water flows on the permeability and ultrastructure of the rabbit gallbladder

Summary The purpose of these experiments was to determine the effect of osmotic gradients on the permeability of the rabbit gallbladder. Increasing the tonicity of the mucosal solution reduced the permeability of the gallbladder to both ions and nonelectrolytes, whereas there was no significant effect when the serosal solution was made hypertonic. These results cannot be explained by solvent/solute interactions in either the epithelial membranes or the unstirred layers. Associated with the changes in permeability was the appearance of the transport number effect and current induced resistance changes. Morphological studies of the gallbladder under these conditions showed that the extracellular spaces of the epithelium and the rest of the wall dilate in the presence of osmotic flow to the serosa, but that the spaces collapse when the flow is in the opposite direction. Reconstruction of the permeability changes from the dimensions of the tissue show that all the physiological phenomena are accounted for by the changes in morphology, the dominant effect being in the lateral intercellular spaces. These results suggest that the lateral spaces are a common pathway shared by all solutes crossing the epithelium, and that diffusion along these spaces becomes rate limiting as the spaces collapse.     

Ultrastructural modifications of frog urinary bladder epithelium under the influence of hypertonic media

Summary The frog urinary bladder undergoes a marked increase in its water permeability when incubated in hypertonic media. Many similarities are found between this effect and the hydrosmotic action of antidiuretic hormone. The ultrastructural modifications of the epithelium observed under the influence of serosal hypertonicity (the intercellular spaces are dilated while the tight junctions remain closed) lead us to assume that the pathways of water movement across the epithelium could be the same in this case and in hydrosmotic response to the hormone. In contrast, when the mucosal medium is made hypertonic, the ultrastructure is differently altered: the intercellular spaces are closed, the tight junctions show small vesicles and numerous large vacuoles appearing in the cytoplasm.     

Functional consequences of ultrastructural geometry in "backwards" fluid-transporting epithelia

Many fluid-transporting epithelia possess dead-end, long, and narrow channels opening in the direction to which fluid is being transported (basal infoldings, lateral intercellular spaces, etc.). These channels have been thought to possess geometrical significance as standing-gradient flow systems, in which active solute transport into the channel makes the channel contents hypertonic and permits water-to-solute coupling. However, some secretory epithelia (choroid plexus, Malpighian tubule, rectal gland, etc.) have "backwards" channels opening in the direction from which fluid is being transported. It is shown that these backwards channels can function as standing-gradient flow systems in which solute transport out of the channel makes the channel contents hypotonic and results in coupled water flow into the channel mouth. The dependence of the transported osmolarity (isotonic or hypertonic) on channel radius, length, and other parameters is calculated for backwards channels for values of these parameters in the physiological range. In addition to backwards channels' being hypotonic rather than hypertonic, they are predicted to differ from "forwards" channels in that some restrictions are imposed by the problem of solute exhaustion, and in the presence of a sweeping-in effect on other solutes which limits the solutes that may be transported.     

Correlation of structural changes at different levels of the jejunal villus with positive net water transport in vivo and in vitro.

Experiments were done for indentification and localization of certain structural changes at different levels of jejunal villus of the hamster during positive and negative water transport across the intestine in vivo and in vitro. Positive transport occurred when the mucosal surface of the intestine was bathed (in vitro experiments) or perfused (in vivo experiments) with isotonic Krebs-Ringer bicarbonate solution containing 10 mM glucose, and negative water transport was achieved by rendering this solution hypertonic with 150 mM mannitol. Results indicate that during positive net water transport the intestine in vivo transported more fluid and exhibited a more conspicuous dilatation of the lateral intercellular spaces (L.I.S.) than did the in vitro preparation. Dilatation of the L.I.S. in both preparations was present only in the apical part of the villus, suggesting that this is the principal site of water absorption. When the mucosal solution was made hypertonic with mannitol, the L.I.S. in the in vivo intestine totally collapsed, whereas in the in vitro intestine these spaces remained open very slightly. These morphological changes correspond well with our finding that in the presence of the hypertonic mucosal solution there was a greater net negative water transport in vivo than in vitro. Incubation of the intestine in the isotonic mucosal solution produced subnuclear swelling of the mid-villus epithelial cells, and this morphological change was associated with an increase in the water content of the tissue. Perfusion of the in vivo intestine with the isotonic solution produced neither the swellings nor the increase in water content of the tissue. In the presence of hypertonic mucosal solution there was a water loss from the tissue both in vivo and in vitro, and these swellings were not observed. These results are discussed in relation to intestinal sugar transport and to the maturity of the epithelial cells, and it is concluded that transport studies on in vitro preparations may provide valid information on a qualitative basis, if not on a strictly quantitative basis.     

Passive Intercellular Pathway in Amphibian Epithelia

PHYSIOLOGIC studies of transporting epithelia generally indicate that passive shunts (or “leak” pathways for water and ions) exist in parallel with transport systems. Most notably, Ussing^1–3 defines this pathway as an extracellular channel in amphibian skin and has shown that a hypertonic external bath decreases the transepithelial electrical resistance, whereas a hypertonic internal bath has the opposite effect. Similar results have been obtained with toad urinary bladder⁴, but in virtually all of the epithelia studied by electron microscopy, tight junctions⁵ have been found at the luminal end of intercellular spaces. Apparent fusion of adjacent plasma membranes and the inability of electron-dense tracer molecules to pass through such regions^5–8 suggest that they may be tight seals, preventing extracellular transepithelial flow. It is shown that these junctions are reproducibly altered when electrical resistance is changed by hypertonic solutions.     

Role of the mesothelium of the parietal peritoneum in the process of absorption of true solutions and india ink suspension from the abdominal cavity]

The method of electron microscopy was applied to the study of absorption from the abdominal cavity of hypotoanic, physiological, hypertonic solutions and of the Indi-ink suspension on physiological saline. Quantitative assessment of pynocytosis was conducted on electron microphotographs. Passage through the mesothelium of true solutions was realized by way of diffusion through the cytoplasm of its cells and by the intercellular spaces; as to the India ink suspension, it passed only by way of the open intercellular spaces. Pynocytosis in the mesothelial cells coursed from their basal portion to the apical one and was directed to the balancing of the concentration of the protein and salt composition in the serous fluid.     

Down-regulation of insulin receptors is related to insulin internalization

In the present study, we have tested the influence of inhibition of endocytosis by hypertonic medium on the regulation of cell surface insulin receptors. We show that active internalization of 125I-insulin is markedly inhibited by hypertonic media and that, in parallel, cell surface invaginations are significantly diminished. These two events are accompanied by a marked inhibition of cell surface insulin receptor down-regulation. These data provide further strong evidence that receptor-mediated endocytosis is the major mechanism by which insulin receptors are regulated at the surface of target cells.     

The Ultrastructural Route of Fluid Transport in Rabbit Gall Bladder

The route of fluid transport across the wall of the rabbit gall bladder has been examined by combined physiological and morphological techniques. Fluid transport was either made maximal or was inhibited by one of six physiological methods (metabolic inhibition with cyanide-iodoacetate, addition of ouabain, application of adverse osmotic gradients, low temperature, replacement of Cl by SO₄, or replacement of NaCl by sucrose). Then the organ was rapidly fixed and subsequently embedded, sectioned, and examined by light and electron microscopy. The structure of the gall bladder is presented with the aid of electron micrographs, and changes in structure are described and quantitated. The most significant morphological feature seems to be long, narrow, complex channels between adjacent epithelial cells; these spaces are closed by tight junctions at the luminal surface of the epithelium but are open at the basal surface. They are dilated when maximal fluid transport occurs, but are collapsed under all the conditions which inhibit transport. Additional observations and experiments make it possible to conclude that this dilation is the result of fluid transport through the spaces. Evidently NaCl is constantly pumped from the epithelial cells into the spaces, making them hypertonic, so that water follows osmotically. It is suggested that these spaces may represent a "standing-gradient flow system," in which osmotic equilibration takes place progressively along the length of a long channel.     

Effects of cooling rate on thermal shock hemolysis

The increase in thermal shock hemolysis in hypertonic sodium chloride with increasing cooling rate was confirmed. Thermal shock damage was also induced by hypertonic solutions of sucrose but it decreased with increasing cooling rate. The effect of cooling rate on thermal shock hemolysis appears to be due to the time that the cells are in the hypertonic solutions. The extent of the stress of the temperature reduction was independent of the cooling rate. In hypertonic sodium chloride susceptibility to thermal shock damage increased with increasing time of exposure at +25 °C (0–5 min) before decreasing with time (5–50 min). In contrast, with hypertonic sucrose, thermal shock damage increased gradually with time of exposure. The protective effects of sucrose on thermal shock hemolysis at a given osmolality can be explained by the different solution properties (e.g., ionic strength) of hypertonic sodium chloride and sucrose. These results suggest that the role of thermal shock damage during slow freezing should be reexamined.     

Determinants of plasma membrane wounding by deforming stress

Once excess liquid gains access to air spaces of an injured lung, the act of breathing creates and destroys foam and thereby contributes to the wounding of epithelial cells by interfacial stress. Since cells are not elastic continua, but rather complex network structures composed of solid as well as liquid elements, we hypothesize that plasma membrane (PM) wounding is preceded by a phase separation, which results in blebbing. We postulate that interventions such as a hypertonic treatment increase adhesive PM-cytoskeletal (CSK) interactions, thereby preventing blebbing as well as PM wounds. We formed PM tethers in alveolar epithelial cells and fibroblasts and measured their retractive force as readout of PM-CSK adhesive interactions using optical tweezers. A 50-mOsm increase in media osmolarity consistently increased the tether retractive force in epithelial cells but lowered it in fibroblasts. The osmo-response was abolished by pretreatment with latrunculin, cytochalasin D, and calcium chelation. Epithelial cells and fibroblasts were exposed to interfacial stress in a microchannel, and the fraction of wounded cells were measured. Interventions that increased PM-CSK adhesive interactions prevented blebbing and were cytoprotective regardless of cell type. Finally, we exposed ex vivo perfused rat lungs to injurious mechanical ventilation and showed that hypertonic conditioning reduced the number of wounded subpleural alveolus resident cells to baseline levels. Our observations support the hypothesis that PM-CSK adhesive interactions are important determinants of the cellular response to deforming stress and pave the way for preclinical efficacy trials of hypertonic treatment in experimental models of acute lung injury.     

Hypertonic stress induces rapid and widespread protein damage in C. elegans

Proteostasis is defined as the homeostatic mechanisms that maintain the function of all cytoplasmic proteins. We recently demonstrated that the capacity of the proteostasis network is a critical factor that defines the limits of cellular and organismal survival in hypertonic environments. The current studies were performed to determine the extent of protein damage induced by cellular water loss. Using worm strains expressing fluorescently tagged foreign and endogenous proteins and proteins with temperature-sensitive point mutations, we demonstrate that hypertonic stress causes aggregation and misfolding of diverse proteins in multiple cell types. Protein damage is rapid. Aggregation of a polyglutamine yellow fluorescent protein reporter is observable with <1 h of hypertonic stress, and aggregate volume doubles approximately every 10 min. Aggregate formation is irreversible and occurs after as little as 10 min of exposure to hypertonic conditions. To determine whether endogenous proteins are aggregated by hypertonic stress, we quantified the relative amount of total cellular protein present in detergent-insoluble extracts. Exposure for 4 h to 400 mM or 500 mM NaCl induced a 55-120% increase in endogenous protein aggregation. Inhibition of insulin signaling or acclimation to mild hypertonic stress increased survival under extreme hypertonic conditions and prevented aggregation of endogenous proteins. Our results demonstrate that hypertonic stress causes widespread and dramatic protein damage and that cells have a significant capacity to remodel the network of proteins that function to maintain proteostasis. These findings have important implications for understanding how cells cope with hypertonic stress and other protein-damaging stressors.     

Potassium depletion and hypertonic medium reduce "non-coated" and clathrin-coated pit formation, as well as endocytosis through these two gates

Intracellular potassium depletion inhibits receptor-mediated endocytotic processes occurring through clathrin-coated pits. Besides the clathrin-coated pit route, flask-shaped invaginations that do not bear a typical clathrin coat have been recently implicated in receptor-mediated endocytosis of cholera toxin. These invaginations are called "non-coated" to distinguish them from the typical clathrin-coated pits. In the present study, we have investigated whether "non-coated" invaginations are sensitive, as are clathrin-coated pits, to potassium depletion and whether hypertonic medium, which inhibits receptor-mediated endocytosis, also affects "non-coated" invaginations. We found that 1) both potassium depletion and hypertonic medium reduce "non-coated" invaginations on the cell surface; 2) similar to potassium depletion, hypertonic medium markedly decreases the number of clathrin-coated pits; 3) these changes are accompanied by an inhibition of the internalization (measured morphologically) of cholera toxin-gold through "non-coated" invaginations, as well as of alpha 2-macroglobulin-gold taken up by clathrin-coated pits; and 4) in addition, both the hypertonic medium and potassium depletion inhibit the uptake of horseradish peroxidase, a marker of fluid-phase endocytosis.     

Alterations in the Morphology of Bacillus subtilis After Exposure to β-Lysin and Ultraviolet Light

Viable counts, turbidities, and electron micrographs of Bacillus subtilis exposed to beta-lysin and ultraviolet light (UV), singly or in combination, were compared in an attempt to relate death with changes in morphology. The decreases in survival of both the beta-lysin- and UV-treated cells were rapid and preceded decreases in turbidity, as well as the changes in morphology. No significant differences were observed in turbidity reduction or morphological alterations of control cells from those of cells exposed to UV light. These cells developed prominent subcell wall spaces during incubation in the hypertonic stabilizing medium. No observable damage in either the cell wall or the cell membrane had taken place during 4 hr, but by 20 hr extensive damage of these two structures was apparent. The control and UV-treated cells exposed to beta-lysin did not develop prominent subcell wall spaces. Within 2 hr, lesions were observable in their cell walls, and the cytoplasmic membranes were permeable to phosphotungstic acid. The damage to these structures became more extensive with time. Although the visible changes of control and UV-treated cells were evident much later than those induced by beta-lysin, the morphological alterations in all cells were similar. It appeared that beta-lysin caused an accelerated release of an autolytic enzyme which digested the cell walls.     

Hypertonic conditions trigger transient plasmolysis, growth arrest and blockage of transporter endocytosis in Aspergillus nidulans and Saccharomyces cerevisiae

By using Aspergillus nidulans strains expressing functional GFP-tagged transporters under hypertonic conditions, we noticed the rapid appearance of cortical, relatively static, fluorescent patches (0.5-2.3 μm). These patches do not correspond to transporter microdomains as they co-localize with other plasma membrane-associated molecules, such as the pleckstrin homology (PH) domain and the SsoA t-Snare, or the lipophilic markers FM4-64 and filipin. In addition, they do not show characteristics of lipid rafts, MCCs or other membrane microdomains. Deconvoluted microscopic images showed that fluorescent patches correspond to plasma membrane invaginations. Transporters remain fully active during this phenomenon of localized plasmolysis. Plasmolysis was however associated with reduced growth rate and a dramatic blockage in transporter and FM4-64 endocytosis. These phenomena are transient and rapidly reversible upon wash-out of hypertonic media. Based on the observation that block in endocytosis by hypertonic treatment altered dramatically the cellular localization of tropomyosin (GFP-TpmA), although it did not affect the cortical appearance of upstream (SlaB-GFP) or downstream (AbpA-mRFP) endocytic components, we conclude that hypertonicity modifies actin dynamics and thus acts indirectly on endocytosis. This was further supported by the effect of latrunculin B, an actin depolymerization agent, on endocytosis. We show that the phenomena observed in A. nidulans also occur in Saccharomyces cerevisiae, suggesting that they constitute basic homeostatic responses of ascomycetes to hypertonic shock. Finally, our work shows that hypertonic treatments can be used as physiological tools to study the endocytic down-regulation of transporters in A. nidulans, as non-conditional genetic blocks affecting endocytic internalization are lethal or severely debilitating.     

Effect of AVT antisense oligodeoxynucleotides on AVT release induced by hypertonic stimulation in chicks

In birds, arginine vasotocin (AVT) and mesotocin (MT) are the neurohypophyseal hormones. AVT is known to be an avian antidiuretic hormone and is released from the neurohypophysis by dehydration or hyperosmotic stimulation. The purpose of this study was to determine whether the mechanism of AVT synthesis is related to the mechanism of hormone release from the neurohypophysis. Four-day-old chicks received an AVT antisense oligodeoxynucleotide (ODN) injection into the cerebral ventricle (icv). Following antisense administration, the chicks received hypertonic saline stimulation. Plasma levels of AVT and MT were measured by radioimmunoassays. In control birds, a hypertonic saline injection resulted in the increase of plasma AVT level. The administration of a high dose (50 microg) of antisense ODN inhibited the increase of plasma AVT level induced by the hypertonic saline stimulation. Plasma levels of MT did not change with the administration of hypertonic saline or antisense ODN. These results suggest that the mechanisms that regulate the secretion of AVT from the neurohypophysis may be coupled to the mechanisms that regulate the synthesis of AVT.     

Induction of random microtubule polymerization in cold and drug-treated PtK1 cells following hyperosmotic shock treatment

The effects of hypertonic sucrose on spindle and interphase microtubule (MT) arrays of PtK1 cells were investigated by incubating cells in complete culture medium at 4 degrees or 37 degrees C, with or without hypertonic sucrose, nocodazole or vinblastine (VLB). Results from anti-tubulin immunofluorescence showed that sucrose-induced alterations of spindle morphology seen at 37 degrees C did not occur at cold temperatures, but cold-induced MT loss was diminished. Application of warm hypertonic sucrose following depolymerization of MTs by nocodazole or cold resulted in the formation of a "feltwork" of randomly oriented, short MTs throughout the cytoplasm. These results, and those obtained substituting VLB for nocodazole, suggest that the effects of sucrose depend on the cytoplasmic concentration of soluble tubulin and support the hypothesis that osmotic factors are involved in effects of hypertonic sucrose on MT organization.     

Caffeine- and Potassium-Induced Contractures of Frog Striated Muscle Fibers in Hypertonic Solutions

The effect of hypertonic solutions on the caffeine- and KCl-induced contractures of isolated fibers of frog skeletal muscle was tested. Hypertonic solutions, twice the normal osmotic strength, prepared by adding NaCl or sucrose, potentiate the caffeine-induced contractures. The fibers may develop tensions of 3.6 kg/cm² of fiber transverse section. The same hypertonic medium reduced the peak tension of KCl-induced contractures. Thus the hypertonic condition does not affect the contractile mechanism itself. These findings give further support to the view that the differential effect of hypertonic solution is on the excitation-contraction coupling mechanism. Extracellular calcium is not essentially required for the first few of a series of caffeine-induced contractures either in hypertonic or in isotonic solutions.