Vascular aspects of water uptake mechanisms in the toad skin: perfusion, diffusion, confusion

Blood cell flow (BCF) in the water absorbing "seat patch" region of toad skin was measured with laser Doppler flow cytometry. BCF of dehydrated toads increased by a factor of 6-8 when water contact was made and declined gradually as toads rehydrated. Water absorption was initially stimulated and declined in parallel with BCF. Water absorption measured during the initial rehydration period did not correlate with BCF and hydrated toads injected with AVT increased water absorption without an increase in BCF indicating the lack of an obligate relation between blood flow and water absorption. Aquaporins 1-3 were characterized by RT-PCR analysis of seat patch skin. AQP 1 was localized in the endothelium of subepidermal capillaries and serves as a pathway for water absorption in series with the apical and basolateral membranes of the epithelium. Dehydrated toads rehydrated more rapidly from dilute NaCl solutions than from deionized water despite the reduced osmotic gradient. BCF of toads rehydrating on 50 mM NaCl was not different than on deionized water and blocking Na+ transport with 100 microM amiloride did not reduce water absorption from 50 mM NaCl. Thus, neither circulation nor solute coupling explains the greater absorption from dilute salt solutions. Rehydration from 10 mM CaCl2 was stimulated above that of DI water by a similar degree as with 50 mM NaCl suggesting the anion might control water permeability of the skin.     

The effect of salt acclimation of the water uptake and osmotic permeability of the skin of the toad (Bufo viridis, L.)

1. Water uptake in vivo, and water fluxes across the isolated skin were studied in salt (NaCl) acclimated toads. 2. Water uptake of acclimated toads maintained in the solution of acclimation, decreased with the environmental salinity. 3. The osmotic water permeability (Pos) of the skin increased upon salt (NaCl) acclimation, both in vivo and in vitro. 4. Pos of the skin of toads acclimated to non-permeant solutes such as sucrose (230 mmol/l) or mannitol (400 nmol/l), was greatly reduced. 5. Oxytocin (syntocinon) increased the Pos both in tap water and salt acclimated toads. In high salt (greater than 200 mmol/l NaCl) acclimated toads however, the increased Pos and water flux at larger osmotic gradients, could not be stimulated further by the hormone. 6. The adaptive nature of the selective changes in the permeability properties of the skin under salt acclimation conditions is discussed.     

Comparison of dehydration and angiotensin II-stimulated cutaneous drinking in toads, Bufo punctatus

Toads (Bufo punctatus) use a sequence of two postures to place the ventral skin on a moist surface and absorb water osmotically. First, the skin contacts the surface (seat patch down, SPD), and then the hindlimbs are abducted to maximize skin contact area (water absorption response, WR). Toads modulated behavior in response to hydration status and osmotic content of the hydration source. Dehydrated toads placed on water displayed both SPD and WR. Hydrated toads injected with angiotensin II (AII) displayed SPD longer than Ringer-injected controls but did not initiate WR and absorbed less water than dehydrated toads. These results suggest that dehydration has a more robust dipsogenic effect than AII. Dehydrated toads placed on 250 mM NaCl briefly initiated SPD but not WR. The addition of amiloride to the hyperosmotic salt solution resulted in brief display of WR but no water loss. Hydrated toads placed on 250 mM NaCl showed shorter periods of SPD behavior. The combination of AII injection and amiloride addition to the salt solution increased SPD initiation but SPD duration was short and water loss was prevented. Neither AII nor dehydration overrides chemosensory mechanisms in the skin that suppress cutaneous drinking from hypertonic solutions.     

Chemosensory function of salt and water transport by the amphibian skin

Solute and water transport mechanisms of anuran skin mediate chemosensory functions that permit evaluation of ionic and osmotic properties of hydration sources in a manner similar to taste receptors in the mammalian tongue. Histochemical observations demonstrated apparent connections between spinal nerve endings and epithelial cells of the skin and we used neural and behavioral responses as measures of coupling between transport and chemosensation. The inhibition of transcellular Na+ transport by amiloride partially reduced the neural response and the avoidance of hyperosmotic NaCl but not KCl solutions. Cetylpyridinium chloride (CPC) reduced the neural response to hyperosmotic salt solutions, suggesting a chemosensory role for vanilloid receptors in the skin. Avoidance of hyperosmotic salt solutions was reduced by impermeant anions suggesting paracellular conductance is important for chemosensation. The effects of blocking the transcellular and paracellular pathways was additive but did not eliminate the avoidance of osmotically unfavorable solutions by dehydrated toads. The timing of the neural response to deionized water was similar to the onset of water absorption behavior and increased blood flow to the pelvic skin. Water absorption from 50 mM NaCl was greater than from deionized water when toads were fully immersed, but not when contact was limited to the ventral surface.     

Antidiuretic responses to osmotic, ionic or volume stimulation of the brain in the unanesthetized toad, Bufo arenarum Hensel

Single injections of 15 microliter of 1 M NaCl or 2M sucrose into the carotid system of normal unanesthetized toads induced a rapid and significant decrease of urine production. This appears to be the first report on the existence of a Verney-like phenomena in a non-mammalian vertebrate. This antidiuresis was blocked out in the hypophysectomized diencephalic lesioned animal. Concurrently, small volumes (4 microliters) of 1 M NaCl but not 2 M sucrose also induced antidiuresis when injected into the midbrain tegmentum of normal but not of hypophysectomized diencephalic lesioned toads. Larger volumes (6 microliters) of 2 M sucrose were needed to induce a similar antidiuresis in normals. Furthermore, even larger volumes (more than 8 microliters) of any of both solutions were able to induce oliguria in normal as well as in hypophysectomized toads. On the basis of these results, the following conclusion would be drawn: the brain of the toad is able to detect ionic and osmotic stimuli, these stimuli apparently affect different receptors in the brain, the antidiuresis initiated by these mechanisms is dependent on diencephalic integrity.     

Lymph osmolality and rehydration from NaCl solutions by toads, Bufo marinus

Toads, Bufo marinus, allowed to maintain an ad libitum state of hydration were dehydrated by 10 15% of their standard weight and allowed to rehydrate from either deionized water or from 10 or 50 mmol l(-1) NaCl solutions. Toads rehydrating from the dilute salt solutions recovered a larger fraction of their standard weight than did toads rehydrating from deionized water despite there being a reduced osmotic gradient. Amiloride did not reduce water gain from these solutions. Water uptake from 100 mmol l(-1) sucrose and 50 mmol l(-1) Na gluconate was reduced relative to deionized water by a fraction predicted from the osmotic gradient. Thus, the presence of both Na+ and Cl- are required for the augmentation of water gain from dilute salt solutions. Toads allowed to rehydrate from 120 mmol l(-1) NaCl for 180 min recovered nearly as much water as toads rehydrating from deionized water for 120 min and the lymph osmolality was not reduced relative to the dehydrated condition. The recovery of water from the salt solution was greater than that predicted from the reduced osmotic gradient and amiloride partially inhibited the rehydration from 120 mmol l(-1) NaCl. Solute coupled water transport can therefore be demonstrated in living animals but only from a NaCl solution that is nearly isoosmotic with the lymph. The mechanism for enhanced water gain from dilute salt solutions remains unresolved.     

Antidiuretic responses to osmotic cutaneous stimulation in the toad,Bufo arenarum

Summary Osmotic stimulation of the skin of the toadBufo arenarum with isotonic (115 mM) or hypertonic (400 mM) NaCl solutions produced a marked and reversible antidiuresis within 5 min. No changes in plasma osmolarity were detected in the course of this response.Hypophysectomized animals exhibited a lower and delayed antidiuresis when exposed to a hypertonic environment (400 mM NaCl). This antidiuretic response was drastically reduced in normal toads after ten consecutive days of administration of the sympatoplexic guanethidine.The existence of a feed-forward control of urine production initiated by cutaneous osmotic sensors and involving an adrenergic component is proposed.     

Effects of anion substitution on hydration behavior and water uptake of the red-spotted toad, Bufo punctatus: is there an anion paradox in amphibian skin?

Amphibians absorb water osmotically across their skins and rely on chemosensory information from the skin to assess the suitability of hydration sources. The time spent with skin in contact with a moist surface provides a quantitative measure of their ability to perceive the ionic and osmotic properties of aqueous solutions. Dehydrated toads given hyperosmotic (250 mM) solutions of NaCl or Na-gluconate showed significantly longer periods of hydration behavior on the gluconate solution, but they lost water osmotically when immersed in either solution. Similarly, dehydrated toads given 250 mM solutions of NaCl, Na-acetate, Na-phosphate or Na-gluconate showed a progressively greater length of hydration time on solutions with the larger mol. wt anions. These results are consistent with the chemosensory phenomenon previously described in mammalian tongue as 'anion paradox'. On dilute (50 mM) solutions of NaCl or Na-gluconate, the hydration time was not different between anions, despite toads gaining water more rapidly when immersed in dilute NaCl than in Na-gluconate solutions. The differing behavioral results with hyperosmotic and hypoosmotic salt solutions suggest that chemosensory transduction through toad skin involves both transcellular and paracellular pathways.     

Transcellular and paracellular elements of salt chemosensation in toad skin

Dehydrated toads absorb water by pressing a specialized (seat patch) area of the skin to moist surfaces. This behavior, the water absorption response (WR), is preceded by periods of more limited skin contact (seat patch down, SPD) in which the suitability of the rehydration source is evaluated. WR and SPD behaviors were suppressed on 250 mM NaCl and 200 mM KCl solutions. Ten micromolar amiloride partially restored SPD and WR on NaCl solutions. The addition of 5 mM La(3+) also partially restored the initiation of WR and this effect was additive to the effect of amiloride, suggesting transcellular and paracellular pathways exist in parallel. Similarly, 5 mM La(3+) partially restored the initiation of WR on KCl solutions, to levels comparable to those with K(+)gluconate, suggesting a paracellular pathway for detection of K(+). Hyperosmotic (250 mM) NaCl solutions bathing the mucosal surface rapidly and reversibly increased the paracellular conductance of isolated skin and this increase was partially inhibited by 5 mM La(3+). These results suggest that the regulation of tight junctions has a chemosensory role in toad skin.     

Water potential receptors in the skin regulate blood perfusion in the ventral pelvic patch of toads

Blood cell flux (BCF) in ventral pelvic skin capillaries was measured in conscious unrestrained Bufo bufo, using a laser Doppler flowcytometer. Hydrated toads responded to water contact with a small but significant increase in BCF. Dehydration alone did not change the BCF in seat patch skin before water contact. However, water contact by dehydrated toads elicited a rapid 600% increase in BCF. The BCF and water uptake of dehydrated toads rehydrating in water declined over 2 h but remained significantly above the low, constant values measured in hydrated toads. Arginine vasotocin injection in hydrated toads did not change skin BCF, but water uptake increased, and urine production decreased. Injection of the beta -adrenergic agonist isoproterenol increased BCF in hydrated toads by 900% and also increased the rate of water uptake. These increases corresponded in magnitude and duration to the response to water contact observed in dehydrated toads. Injection of dehydrated toads with the beta -adrenergic antagonist propranolol significantly reduced both BCF and water uptake. These results are consistent with an autonomic reflex mediated by skin water potential receptors that regulate blood perfusion of ventral pelvic skin.     

Cutaneous blood flow and water absorption by dehydrated toads

Blood cell flux (BCF) in ventral pelvic skin capillaries was measured in toads, Bufo woodhouseii and Bufo punctatus, using a chamber that allowed hydration behavior and water absorption to be observed concurrently in unrestrained animals. Dehydrated B. woodhouseii and B. punctatus placed on a rehydration solution significantly increased BCF relative to that on a dry surface in less than 2 min. Skin contact with a rehydration solution rather than dehydration alone is the primary stimulus for increased seat patch blood flow. In B. woodhouseii, the water absorption response was initiated after the increase in BCF had started but before maximum BCF was reached. BCF and water uptake across the ventral skin of both species placed on deionized water were not different from those of toads placed on 50 mM NaCl. Similarly, no significant correlation between BCF and rate of water uptake could be observed in dehydrated toads of either species. Angiotensin II (AII) injection in hydrated B. punctatus had no effect on BCF, suggesting that factors other than AII are responsible for the increase in blood flow upon water contact in dehydrated toads.     

Gallbladder epithelial cell hydraulic water permeability and volume regulation

The hydraulic water permeability (Lp) of the cell membranes of Necturus gallbladder epithelial cells was estimated from the rate of change of cell volume after a change in the osmolality of the bathing solution. Cell volume was calculated from computer reconstruction of light microscopic images of epithelial cells obtained by the "optical slice" technique. The tissue was mounted in a miniature Ussing chamber designed to achieve optimal optical properties, rapid bath exchange, and negligible unstirred layer thickness. The control solution contained only 80% of the normal NaCl concentration, the remainder of the osmolality was made up by mannitol, a condition that did not significantly decrease the fluid absorption rate in gallbladder sac preparations. The osmotic gradient ranged from 11.5 to 41 mosmol and was achieved by the addition or removal of mannitol from the perfusion solutions. The Lp of the apical membrane of the cell was 1.0 X 10(-3) cm/s . osmol (Posm = 0.055 cm/s) and that of the basolateral membrane was 2.2 X 10(-3) cm/s . osmol (Posm = 0.12 cm/s). These values were sufficiently high so that normal fluid absorption by Necturus gallbladder could be accomplished by a 2.4-mosmol solute gradient across the apical membrane and a 1.1-mosmol gradient across the basolateral membrane. After the initial cell shrinkage or swelling resulting from the anisotonic mucosal or serosal medium, cell volume returned rapidly toward the control value despite the fact that one bathing solution remained anisotonic. This volume regulatory response was not influenced by serosal ouabain or reduction of bath NaCl concentration to 10 mM. Complete removal of mucosal perfusate NaCl abolished volume regulation after cell shrinkage. Estimates were also made of the reflection coefficient for NaCl and urea at the apical cell membrane and of the velocity of water flow across the cytoplasm.     

Urea production and accumulation in the green toad, Bufo viridis

The toad, Bufo viridis , can live for several months without access to free water, absorbing soil-bound water down a water-potential gradient created, mainly, by accumulating urea in its body fluids. We investigated if the retention of urine was sufficient to account for the rate of accumulation or if an increased rate of urea production was needed in order to do so. The basal rate of urea production in unfed animals in the absence of osmotic stress was estimated by two methods; first, analysis of the bathing medium and, secondly, collection and analysis of urine at two-hourly intervals. This was then repeated with animals fed a weight-maintaining diet. Generally similar results were obtained by either method in both fed and unfed animals, although higher urea production rates were found in the former. Although it had been planned to apply the short interval method to toads with free access to water, the control condition for toads transferred to soil, it proved to be impracticable. Some animals did not bathe for almost a day, during which time minute quantities of urine were obtained. Larger volumes were only produced during or after bathing. Consequently, animals which were partially immersed in water were substituted as controls. Total urea content was determined in these and in toads after a week on soil. The calculated increase was compared to that which could be expected from urine retention. It was found that urea accumulated at more than twice the predicted rate. When rates of accumulation were calculated over longer periods, urine retention alone was sufficient to account for them within three weeks on soil, the usual period required for acclimation. We concluded that B. viridis increased its rate of urea production only for a short period, until a favourable water potential gradient was achieved.     

Rapid Water Inflow and Outflow in Plants with Roots Treated with Salt Solutions of Various Concentrations

A new highly sensitive and rapidly responding gravimetric method was used for the investigation of rapid responses manifesting in water inflow and outflow from roots in the intact seedlings of tomato Lycopersicon esculentumMill. and sunflower Helianthus annuusL. The effects of K⁺, Na⁺, and Ca²⁺chlorides were studied in solutions with concentrations of 0.3–500 mM. Any sudden increase in the osmotic pressure of an external solution brought about a typical gravimetric response in the roots of seedlings that started practically without a lag period and comprised rapid and slow phases of water loss. The total amplitude of the response depended on the osmotic gradient produced by the changes of solutions. Responses were reversible and well reproduced upon the repeated treatment of the same plant if the treatment was noninvasive. The notable characteristics of water inflow and outflow included a very short lag period, a gradual pattern, and a low selectivity to different salts. This was especially true for the initial (rapid) phase of response. However, mono- and bivalent cations showed some specificity of action. Some data suggest the osmotic nature of rapid responses of water uptake and loss by roots. One may assume that a dynamic osmotic equilibrium exists between the root and the outer solution so that any change in the osmotic pressure of the medium would induce an instant and then a more gradual change in the water content. When plotted in logarithmic coordinates, two straight lines with different slopes described the relationship between the gravimetric response and the salt concentration. The point where these lines intersected corresponded to about 50 mM NaCl. Lower and higher salt concentrations seem to induce rapid water inflow and outflow in plant roots by means of different mechanisms.     

Phosphate Absorption, Fluxes, and Symplasmic Transport in Osmotically-Shocked Zea mays Roots

Osmotic shock with sequential 30 min treatments in ice-coldsaline solutions and distilled water inhibited both the subsequentuptake of orthophosphate (Pi) and its transport into the xylemof excised corn (Zea mays L.) roots. Measurements of Pi fluxeswith ³²P indicated that the decrease in net Pi uptake over a24 h period caused by osmotic shock was due primarily to delayedrecovery of Pi influx rather than to increasing efflux. Despitecomplete recovery of Pi absorption within 2–6 h aftershocking with 150–200 mM NaCl, transport to the xylemduring the subsequent 24 h only partially recovered. Leucineuptake and incorporation into protein was also markedly inhibitedby osmotic shock but both almost completely resumed controlrates within 24 h after shocking with up to 150 mM NaCl. Tetracyclineinhibited recovery of Pi uptake after NaCl treatment whereaspuromycin did not. These results with corn roots are consistentwith the hypothesis that recovery of Pi uptake activity aftermoderate osmotic shock requires de novo synthesis of membraneproteins. Incomplete recovery of Pi transport to the xylem suggeststhat osmotic shock may damage plasmodesmata. Key words: Corn, Ion uptake, Leucine uptake, NaCl, Puromycin, Tetracycline     

Effect of amiloride on cell volume regulation in renal straight proximal tubules

Amiloride has been shown to impair cell volume regulatory decrease in amphiuma red cells. The present study has been performed to test for the influence of amiloride on volume regulatory decrease and electrical properties in isolated perfused mouse straight proximal tubules. Replacement of 40 mmol/l NaCl with 80 mmol/l mannitol in bath perfusate does not appreciably affect the cell volume or the potential difference across the basolateral cell membrane. Reduction of osmolarity by omission of mannitol leads to cell swelling by 16.7 +/- 0.7% (n = 7), followed by volume regulatory decrease to 107.2 +/- 1.2% (n = 7) of original cell volume within 2 min. 1 mmol/l amiloride (but not 0.1 mmol/l amiloride) in the bath depolarizes the basolateral cell membrane from -63 +/- 1 mV (n = 24) by +16 +/- 1 mV (n = 16), decreases the apparent potassium transference number from 0.69 +/- 0.02 (n = 5) to 0.36 +/- 0.05 (n = 5), and significantly impairs volume regulatory decrease without appreciably modifying cell volume in isotonic solutions. 1 mmol/l amiloride in the luminal perfusate leads to a slight hyperpolarization of the basolateral cell membrane but does not interfere with volume regulatory decrease. Reduction of bath osmolarity depolarizes the basolateral cell membrane within 30 s by +7.8 +/- 0.8 mV (n = 18) in the absence and by +18 +/- 2 mV (n = 8) in the presence of amiloride. In the presence of reduced bath osmolarity and amiloride the potassium transference number amounts to 0.36 +/- 0.04 (n = 8). The hyperpolarization following luminal application of amiloride is most likely due to inhibition of luminal sodium channels, whereas bath amiloride depolarizes the basolateral cell membrane by reduction of basolateral potassium selectivity. As in amphiuma red cells amiloride impairs volume regulatory decrease in proximal straight renal tubules.     

Elevated plasma osmotic concentration stimulates water absorption response in a toad.

The water-seeking behavior (WR) of toads (Bufo viridis) was investigated. Fully hydrated toads that are allowed free choice of wet or dry filter paper voluntarily and spontaneously select to sit on water-soaked paper at a regular frequency during trials. Dehydration of bladder-emptied toads by 14% elicits WR in all animals. Injection of aldosterone or angiotensin-I reduced the dehydration threshold to 7% weight loss. WR frequency increased when plasma osmolality was elevated by injection of NaCl or other solutes (both ionic and non-ionic). Only urea, to which cell membranes are highly permeable, was the exception that did not produce this response. The increase in WR frequency induced by elevated plasma osmolality was augmented by injection of aldosterone or angiotensin-I. In vivo water uptake, measured in a water bath, was increased by an NaCl or oxytocin injection, but not by aldosterone. It is concluded that elevated plasma osmolality induces an increase in WR frequency that is separate and prior to the water uptake process. Different hormones are involved in each step.     

Ultrastructure changes associated with osmoregulation in the hindgut cells of a saltwater insect, Ephydrella sp. (Ephydridae: Diptera)

Ephydrella larvae strictly regulate their blood osmotic pressure and Na⁺ content over a wide range of environmental salinities (7 mM to 3000 mM NaCl). They can survive in distilled water and 6000 mM NaCl for several days. In the hindgut the ileum is concerned with the regulation of urine composition whilst the rectum has a purely mechanical function. In the ileum there are large cells which have long basal channels and short apical microvilli, and small cells which have long apical leaflets and short basal channels. It is suggested that the large cells reabsorb water and that the small cells either reabsorb or secrete ions. The configurations of the channels, and the spacing of leaflets and microvilli change with alterations in environmental salinity. Fixation experiments using fixatives of different osmotic pressures show that the configuration of extracellular space in the cells has a marked dependence on both the osmotic pressure of the fixative and upon the environmental salinity. It is suggested that the osmotic response of the cells to fixatives indicates that the osmotic pressure of the cells increases with increasing environmental salinity. It is suggested, in general, that correlation of changes in the volume of extracellular space with changes in ion and water transport must be regarded with caution.     

Regulation of MI transport in retinal pigment epithelium by sugars, amiloride, and pH gradients: potential impairment of pump-leak balance in diabetic maculopathy

Impairment of transport and metabolism of retinal pigment epithelium (RPE) has been recognized to play a role in the development of diabetic macular edema. To understand the mechanism(s) of action of high glucose levels in alteration of RPE metabolism, primary cultures of RPE cells were used as an in vitro model of diabetic retinopathy/maculopathy. RPE cells were grown with 5 mM (control) or 40 mM glucose (a monosaccharide that enters the cells), or 40 mM sucrose (a disaccharide that does not enter the cells), and the extent of Na(+)-dependent active transport of an osmolyte ([3H]-myo-inositol, MI, 10 microM) into cells was determined. While 40 mM glucose down-regulated 3H-MI transport, 40 mM sucrose stimulated it, compared to 5 mM glucose feeding. Addition of 1 mM amiloride, an inhibitor of Na+/H+ exchanger, in the incubation media, significantly inhibited MI transport. Cells treated with high sucrose or high glucose were more sensitive toward amiloride inhibition, compared to controls. Inhibition of either pump or leak pathway alone was not sufficient to completely inhibit MI transport, but simultaneous inhibition of both pathways, by amiloride and ouabain (1 mM each), strongly inhibited osmolyte accumulation. The strongest inhibition of uptake occurred when 150 mM NaCl in the incubation media was replaced by 150 mM choline-Cl, and the percent inhibition of uptake, with choline-Cl, was highest with sucrose-fed cells, compared to normal or high glucose-fed cells. Imposition of a pH gradient [pHi (6.1) less than pH0 (8.0)] across the cell membrane, a condition that stimulates Na+/H+ exchange activity, also reduced MI accumulation. Cellular water content, measured by the extent of [3H]-3-O-methyl glucose uptake, in the presence of balanced salt solution (BSS), BSS containing half the ionic strength (hypotonic solution), or BSS containing 20 mM K+, for induction of cell swelling, varied when cells were fed with various sugars. Cells fed with high glucose were less sensitive toward media tonicity compared to normal. These results suggested that in cultured RPE cells, changes in Na+/H+ exchanger activity (intracellularly or extracellularly), through its inhibition by amiloride, its activation via intracellular acidification, or perhaps by chronic feeding with high sucrose or high glucose, affected the Na(+)-dependent active accumulation of MI. A metabolic factor involved in the development of diabetic macular edema is perhaps associated with glucose-induced alterations in Na+ fluxes (e.g., changes in Na+/H+ exchanger activity), which can secondarily influence osmolyte accumulation, impairment of pump-leak balance, and/or intracellular pH.(ABSTRACT TRUNCATED AT 400 WORDS)     

Water retention and plasma and urine composition in toads (Bufo viridis Laur.) under burrowing conditions

Summary Osmoregulation in the terrestrial toad,Bufo viridis, was studied under burrowing conditions in the laboratory. The toads can live for over 3 months burrowed in soil containing 9–10% moisture, maintaining constant body volume due to a large increase in the plasma osmolality, contributed mainly by urea. Water content of the tissues remains constant. Relatively large volumes of urine are stored in the urinary bladder during water restriction. The osmolality of the urine does not exceed that of the plasma. Urea uptake across the skin was measured in vitro and was greatly elevated in skins from the burrowed toads. The increase in plasma osmolality enables greater water absorption from the soil under water restricted conditions while the water content of the tissues is maintained constant since cell membranes are highly permeable to urea. It is concluded that the urea accumulating ability and urea tolerance form the basis for both the terrestriality and salt adaptability of this and other amphibian species.