Water and sodium balance in the estuarine diamondback terrapin (Malaclemys)

Summary Total body water decreased significantly in terrapins exposed to sea water (SW). Although the intracellular fluid decreased somewhat upon SW exposure, the decline in extracellular fluid was almost twice as great. Under conditions of voluntary drinking after salt loading, terrapins substantially increased the volume of the extracellular fluid while maintaining the intracellular fluid near the freshwater (FW) control levels. FW terrapins were consistently heavier than animals of the same plastron length exposed to SW. Thus expression of body fluid volumes as ml/cm plastron length rather than as % body weight is necessary to correct for the loss of total body water with progressive dehydration. Fasted terrapins in SW lost weight at 0.32% weight/day, whereas the rate in FW was 0.21%/day. Water influx and efflux in SW were 0.17 and 0.16 ml/100 g·h respectively. When the efflux was increased by the calculated value for unmeasured respiratory loss, it exceeded the influex by 0.01 ml/100 g·h. Consequently the net water loss determined with radiotracers (equivalent to 0.24% weight/day) was similar to the difference between the weight losses in SW and FW (0.11%/day). Partitioning studies indicated that the majority of water exchange between the terrapin and SW occurs through the integument. Terrapins in SW underwent a concentration of the body fluids, most of which can be attributed to water loss, not electrolyte gain. The rates of Na influx and efflux were quite low (usually ranging from 6–10 moles/100 g·h). In two terrapins the injection of NaCl loads resulted in eight- to 19-fold increases in Na efflux. The uptake of Na from SW occurred orally. The skin was virtually impermeable to Na. The salt gland and possibly the cloaca were the major routes of Na efflux. The injection of NaCl loads resulted in an increase in cephalic Na excretion from a mean of 3.2 moles/100 g·h to 32.5 moles/100 g·h. Terrapins in SW exhibited a significant increase in bladder urine [K] over the FW controls. There was a direct relationship between plasma [Na], urine [K], and lachrymal salt gland Na–K ATPase content. In comparing SW terrapins with FW painted turtles (Chrysemys) exposed to SW radiotracer studies demonstrated a similarity in Na influx, but there was at least a four-fold increase in water exchange in the painted turtle. It seems likely that the skins of many aquatic reptiles (marine, estuarine and FW) are impermeable to Na but differ markedly in water permeability.     

Sodium balance in the green turtle,Chelonia mydas, in seawater and freshwater

Summary Sodium balance in the green turtle,Chelonia mydas, has been investigated in both seawater and freshwater. In seawater the unidirectional Na efflux is 131 M · 100 g^–1 · h^–1, over 90% of which is via the head region and less than 5% each is via the cloaca and the integument. After 17 days in freshwater the efflux of Na has declined by 97% and the majority is via the cloaca. The integumental efflux in freshwater is less than that in seawater indicating that a change in skin permeability, trans-skin electrical potential or pattern of blood flow has taken place. Although there are indications that Na is actively extracted from freshwater by the green turtle, this species faces a net loss of Na of the medium and the blood Na concentration falls significantly. When transferred from seawater to freshwater the turtle's orbital salt gland is turned off within 25 h after transfer. The salt gland does not become functional until 400 h after transfer from freshwater to seawater.     

Structure and function of skin in the pelagic sea snake,Hydrophis platurus

We describe and interpret the functional morphology of skin of the Yellow-bellied sea snake, Hydrophis platurus. This is the only pelagic sea snake, and its integument differs from what is known for other species of snakes. In gross appearance, the scales of H. platurus consist of non-overlapping, polygonal knobs with flattened outer surfaces bearing presumptive filamentous sensillae. The deep recesses between scales (‘hinge’) entrap and wick water over the body surface, with mean retention of 5.1 g/cm of skin surface, similar to that determined previously for the roughened, spiny skin of marine file snakes, Acrochordus granulatus. This feature possibly serves to maintain the skin wet when the dorsal body protrudes above water while floating on calm oceanic slicks where they forage. In contrast with other snakes, including three species of amphibious, semi-marine sea kraits (Laticauda spp.), the outer corneous β-protein layer consists of a syncytium that is thinner than seen in most other species. The subjacent α-layer is also thin, and lipid droplets and lamellar bodies are seen among the immature, cornifying α-cells. A characteristic mesos layer, comprising the water permeability barrier, is either absent or very thin. These features are possibly related to (1) permeability requirements for cutaneous gas exchange, (2) reduced gradient for water efflux compared with terrestrial environments, (3) less need for physical protection in water compared with terrestrial ground environments, and (4) increased frequency of ecdysis thought to be an anti-fouling mechanism. The lipogenic features of the α-layer possibly compensate for the reduced or absent mesos layer, or produce layers of cells that comprise what functionally might be termed a mesos layer, but where the organization of barrier lipids nonetheless appears less robust than what is characteristically seen in squamates.     

The permeability to water of the eggs of certain marine teleosts

Summary Measurements have been made of the rate of turnover of tritiated water in the eggs of the plaice,Pleuronectes platessa and of the permeability of the vitelline membrane. The rate constant of water exchange in body cavity eggs is 1.0 h^–1, corresponding to a permeability of 0.086 ³/²/sec. When shed into sea water the rate constant of exchange declines to 0.2 h^–1 after 1 hour and to 0.02 h^–1 after one day corresponding to a permeability of 0.0017 [³/²/sec. As the embryo develops the rate of turnover increases again. The buoyancy of the egg is dependent on its low salt content which counteracts the weight of the protein. During development the water loss by osmosis reduces the egg almost to neutral buoyancy.     

Gill potentials and sodium fluxes in the flounderPlatichthys flesus

Summary A simple method is described of measuring the potentialin vivo between the blood plasma and external medium of a fish. The potential in the euryhaline flounderPlatichthys flesus averages +19 mV in sea water and –78 mV immediately after transfer to fresh water. The potential is largely dependent on the external concentration of sodium and behaves as a diffusion potential. The relative permeabilities of the gill of the sea water adapted flounder to Na, K. and Cl ions are in the ratio 12.50.03. The permeability to the divalent ions, Ca, Mg and SO₄ is very low. The changes of potential account for the apparent sodium exchange diffusion effect observed in the sodium fluxes following changes in the external medium and the slight dependence of sodium efflux on the external concentration of potassium in sea water.This work was supported by N.E.RC. Grant No.: GR/3/1515. We are grateful to the Joint Western Sea Fisheries Committee for the supply of flounders.     

The effect of food consumption on sodium and water balance in the predaceous diving beetle,Dytiscus verticalis

Summary Sodium and water balance ofDytiscus verticalis in fresh water were investigated under three feeding regimes: unfed, and fed a diet either low or high in sodium chloride. Unfed sodium influx was 0.13 and sodium efflux was 0.74 moles/100 gwm·h. These values are low in comparison with most freshwater animals. The electrical potential difference across the integument in artificial soft water (ASW) was about 150 mV smaller than the potential necessary to maintain sodium balance in the absence of active transport. However, sodium influx did not show saturation kinetics over an external concentration range of 91 to 1725 M. Unfed beetles failed to arrest net sodium loss to baths that were initially distilled water or ASW, even when bath sodium concentrations reached 75–298 M. The long-term rate of net sodium loss ranged from 0.61 to 4.4 moles/100 gwm·h for four sets of animals. Beetles decreased sodium efflux during a period of fasting. During subsequent feeding, beetles fed a high sodium diet (HSD) increased sodium efflux while beetles fed a low sodium diet (LSD) maintained low rates of sodium efflux. HSD fed beetles increased body sodium and hemolymph sodium concentration, and expanded extracellular fluid, relative to LSD fed beetles. Thus beetles cannot achieve sodium balance in fresh water without dietary sodium input, although they are able to regulate sodium loss.Abbreviations gwm grams wet mass - ASW artificial soft water - DW distilled water - HSD high sodium diet - LSD low sodium diet - ECF extracellular fluid volume     

Sodium and potassium fluxes across the dialyzed giant axon ofMyxicola

Summary Resting and stimulated fluxes of sodium and potassium across the giant axon of the marine annelid,Myxicola infundibulum, have been characterized using the technique of internal dialysis. In most respects the ion movements were found to be similar to those in squid axons. Sodium efflux and potassium influx were found to be active, cardiac glycoside-sensitive fluxes, with a variable coupling ratio. However, when [ATP]_i was lowered to less than 20 M by treatment with cyanide and continuous dialysis, or to less than 2 m by dialysis with glucose following injection of hexokinase, Na efflux and K influx were unaltered. The maintained fluxes were not accounted for by an increased passive permeability of the axolemma, although 30–60% of the Na efflux appeared to be due to Na–Na exchange. An altered form of Na pump operation at low [ATP]_i is a more likely explanation than an alternate energy source, or an ATP source proximate to the axolemma. The transient response of²²Na efflux to a change in [²²Na]_i was found to be much slower than in squid, =360 sec. The efflux delay could only be accounted for by an extra-axonal diffusion barrier, which is probably the basement membrane surrounding the ventral nerve cord.     

The sodium balance of the euryhaline marine loggerhead turtle,Caretta caretta

Summary The efflux of sodium ions from the loggerhead turtle,Caretta caretta, was investigated when animals were acclimated to seawater, freshwater, and during the acclimation period after transfer from seawater to freshwater. The rate of sodium loss in animals acclimated to seawater was found to be 3 M Na · g^–1 · hr^–1. Cannulation of the cloaca showed that only 5% of the gross efflux of sodium was via the cloaca and it was calculated that 60% of the gross efflux was via nasal gland secretion and 35 % via integumentary diffusional loss. Cannulation experiments indicated that a significant amount of sodium may enter the body via the cloaca. Transfer of animals from seawater to freshwater resulted in a decline of sodium efflux by 90–99 % within 6 hr, and a further decline to only approximately 0 01 M Na · g^–1· hr^–1 after 1–2 days in freshwater. Cannulation experiments of individuals acclimated to freshwater indicated that the role of the cloaca in sodium loss in freshwater was minimal. It was calculated that sodium loss in freshwater is so small that survival in freshwater for at least 20 days is possible without active extraction of sodium from the medium. No evidence could be found for active uptake of sodium ions from freshwater baths byCaretta.This research was supported by NSF grant GB 16839.     

Effect of metabolic depletion on the furosemide-sensitive Na and K fluxes in human red cells

Summary We report in this paper the effect of metabolic depletion on several modes of furosemide-sensitive (FS) Na and K transport in human red blood cells. The reduction of ATP content below 100 mol/liter cells produced a marked decrease in the maximal activation (V _max) of the outward. FS transport of Na and K into choline medium in the presence of ouabain (0.1 mM) and 1 mM MgCl₂. TheK _0.5 for internal Na to activate the FS Na efflux was not altered by metabolic depletion. However, metabolic depletion markedly decreased the K _i for external K (K _o ) to inhibit the FS Na efflux into choline medium (from 25 to 11 mM). Repletion of ATP content by incubation of cells in a substraterich medium recovered control levels ofV _max of the FS Na and K fluxes and of K _i for external K to inhibit FS Na efflux. TheV _max of FS Na and K influxes was also markedly decreased when the ATP content dropped below 100 mol/liter cells. This was mainly due to a decrease in the inward-coupled transport of K and Na (Na _o -stimulated K influx and the K _o -stimulated Na influx). The FS K _i /K _o exchange pathway of the Na–K cotransport, estimated from the FS K influx from choline-20 mM K _o medium into cells containing 22 mmol Na/liter cells, was also reduced by starvation. Starvation did not inhibit the FS Na _i /Na _o exchange pathway, estimated as FS Na influx from a medium containing 130 mM NaCl into cells containing 22 mmol Na/liter cells. The unidirectional FS²²Na efflux and influx were also measured in control and starved cells containing 22 mmol Na/liter cells, incubated in a Na medium (130 mM) at varying external K (0 to 20 mM). In substrate-fed cells, incubated in the absence of external K, FS Na efflux was larger than Na influx. This FS net Na extrusion (400 to 500 mol/liter cells·hr) decreased when external K was increased, approaching zero around 15 mM K _o . In starved cells the net Na extrusion was markedly decreased and it approached zero at lower K _o than in substrate-fed cells. Our results indicate that the FS Na and K fluxes, and their major component, the gradient driven Na–K–Cl cotransport system, are dependent on the metabolic integrity of the cells.     

Gill area, permeability and Na+ ,K+ -ATPase activity as a function of size and salinity in the blue crab, Callinectes sapidus

Juvenile blue crabs, Callinectes sapidus, extensively utilize oligohaline and freshwater regions of the estuary. With a presumptively larger surface-area-to-body weight ratio, juvenile crabs could experience osmo- and ionoregulatory costs well in excess of that of adults. To test this hypothesis, crabs ranging over three orders of magnitude in body weight were acclimated to either sea water (1,000 mOsm) or dilute sea water (150 mOsm), and gill surface area, water and sodium permeabilities (calculated from the passive efflux of 3H2O and 22Na+), gill Na+, K+ -ATPase activity and expression were measured. Juveniles had a relatively larger gill surface area; weight-specific gill surface area decreased with body weight. Weight-specific water and sodium fluxes also decreased with weight, but not to the same extent as gill surface area; thus juveniles were able to decrease gill permeability slightly more than adults upon acclimation to dilute media. Crabs < 5 g in body weight had markedly higher activities of gill Na+ ,K+ -ATPase than crabs > 5 g in both posterior and anterior gills. Acclimation to dilute medium induced increased expression of Na+, K+ -ATPase and enzyme activity, but the increase was not as great in juveniles as in larger crabs.The increased weight-specific surface area for water gain and salt loss for small crabs in dilute media presents a challenge that is incompletely compensated by reduced permeability and increased affinity of gill Na+, K+ -ATPase for Na+. Juveniles maintain osmotic and ionic homeostasis by the expression and utilization of extremely high levels of gill Na+, K+ -ATPase, in posterior, as well as in anterior, gills.     

Pelagic sea snakes dehydrate at sea

Secondarily marine vertebrates are thought to live independently of fresh water. Here, we demonstrate a paradigm shift for the widely distributed pelagic sea snake, Hydrophis (Pelamis) platurus, which dehydrates at sea and spends a significant part of its life in a dehydrated state corresponding to seasonal drought. Snakes that are captured following prolonged periods without rainfall have lower body water content, lower body condition and increased tendencies to drink fresh water than do snakes that are captured following seasonal periods of high rainfall. These animals do not drink seawater and must rehydrate by drinking from a freshwater lens that forms on the ocean surface during heavy precipitation. The new data based on field studies indicate unequivocally that this marine vertebrate dehydrates at sea where individuals may live in a dehydrated state for possibly six to seven months at a time. This information provides new insights for understanding water requirements of sea snakes, reasons for recent declines and extinctions of sea snakes and more accurate prediction for how changing patterns of precipitation might affect these and other secondarily marine vertebrates living in tropical oceans.     

Sodium extrusion by the sea-water-acclimated fiddler crab Uca pugilator: comparison with other marine crustacea and marine teleost fish.

1. Measurements of the blood Na concentration and transepithelial electrical potential (T.E.P.) across Uca pugilator acclimated to sea water indicate that Na is maintained out of electrochemical equilibrium with sea water. The resulting net Na influx as well as the sodium gain due to ingestion of the medium must be balanced by extrarenal Na extrusion. 2. The small T.E.P. (-0.7 mV) and the 'transport numbers' of Na and Cl indicate that the permeability to these ions is equivalent. 3. Removal of external K results in a significant stimulation of unidirectional Na efflux that is dependent upon external Na but is not inhibited by ouabain. 4. Transfer of Uca to K and Na-free sea water results in a 54% decline in unidirectional efflux, which is not due to T.E.P. changes. Readdition of 25mM-K stimulates Na efflux much more than can be accounted for by changes in the T.E.P. Readdition of 25mM-Na to potassium-free sea water does not change the Na efflux. 5. The results indicate that Na extrusion by Uca is via a Na/K exchange mechanism which partially inhibits Na/Na exchange. Cessation of Na/K exchange (in K-free sea water) removes this inhibition and allows rapid Na/Na exchange. It is not known whether Na/K and Na/Na exchange are via the same or parallel carrier systems.     

Osmotic Water Permeability of Vacuolar and Plasma Membranes Isolated from Maize Roots

The method of stopped flow was used to follow the changes in light scattering by the vesicles of plasmalemma and tonoplast isolated from maize (Zea maysL.) roots and treated by osmotic pressure. In both membrane preparations, the rate of the process depended on the osmotic gradient and was described with the simple exponential function. The rate constants derived from these functions were the following: the coefficient of water permeability in the tonoplast (P= 165 ± 7 m/s) exceeded by an order of magnitude the corresponding index for plasmalemma (11 ± 2 m/s). The presence of HgCl₂(1.6 nmol/g membrane protein) decreased the tonoplast water permeability by 80%. Microviscosity studies of the hydrocarbon zone in the isolated membranes by using a fluorescent diphenylhexatriene probe demonstrated that the two membranes do not differ in the phase state of their lipid bilayer. The authors conclude that the observed difference in water permeability does not depend on the state of the lipid phase and probably reflects the dissimilar functional activity of plasmalemma and tonoplast aquaporins.     

Barriers to sodium movement across frog skin

Summary The aim of this paper is to obtain information on the number, nature and location of the barriers to Na movement across the frog skin, and on the size and location of the Na-pool that might be contained between these barriers. On the basis that Na penetrates passively across an outer barrier, and is actively extruded across an inner barrier which is impermeable to passive movements of Na, we expected to detect at least the Na-pool of a single cell layer containing some 10^–8 moles per cm² of epithelium (i.e., in a cell layer 5 thick and with 21mm Na). Yet no Na-pool with these characteristics was found. The method employed could have detected a Na-pool at least an order of magnitude smaller than the one expected. It is concluded that either a Na-pool does not exist (except for the Na bound to the mechanisms operating the translocation), or else that the Na-pool is contained between barriers with different characteristics than the ones assumed above. In the first case, Na transportacross the epithelium would consist of a translocation across a single asymmetrical functional barrier. In the second case, the experimental results would require that ouabain either directly (by inhibiting an active step) or indirectly (through a mediated decrease of the Na permeability of the outer barrier) prevents Na penetration at the outer border.     

The influence of salinity on the kinetics of NH inf4 sup+ uptake in Spartina alterniflora

Summary The effects of short- and long-term exposure to a range in concentration of sea salts on the kinetics of NH _inf4 ^sup+ uptake by Spartina alterniflora were examined in a laboratory culture experiment. Long-term exposure to increasing salinity up to 50 g/L resulted in a progressive increase in the apparent K_m but did not significantly affect V_max (mean V_max=4.23±1.97 mole·g^–1·h^–1). The apparent K_m increased in a nonlinear fashion from a mean of 2.66±1.10 mole/L at a salinity of 5 g/L to a mean of 17.56±4.10 mole/L at a salinity of 50 g/L. These results suggest that the long-term effect of exposure to total salt concentrations within the range 5–50 g/L was a competitive inhibition of NH _inf4 ^sup+ uptake in S. alterniflora. No significant NH _inf4 ^sup+ uptake was observed in S. alterniflora exposed to 65 g/L sea salts. Short-term exposure to rapid changes in salinity significantly affected both V_max and K_m. Reduction of solution salinity from 35 to 5 g/L did not change V_max but reduced K_m by 71%. However, exposing plants grown at 5 g/L salinity to 35 resulted in an decrease in V_max of approximately 50%. Exposure of plants grown at 35 g/L to a total sea salt concentration of 50 g/L for 48h completely inhibited uptake of NH _inf4 ^sup+ . For both experiments, increasing salinity led to an increase in the apparent K_m similar to that found in response to long-term exposure. Our data are consistent with a conceptual model of changes in the productivity of S. alterniflora in the salt marsh as a function of environmental modification of NH _inf4 ^sup+ uptake kinetics.     

Tobacco protoplasts differentiate into elongate cells without net microtubule depolymerization

Summary Microtubules (MTs) are important for plant cell morphogenesis because they influence the deposition of cell plate and wall components. It has been observed that tobacco protoplasts contain a disordered MT array in the cortex. Following several days in culture, these protoplasts become elongate cells with an orderly cortical MT array. The transformation of the MT array may occur by net depolymerization of the disordered MTs and repolymerization of MTs into an ordered array, or by movement of the array as an integral unit. To experimentally distinguish between these two possibilities, the drug taxol was used to stabilize MTs. Protoplasts derived from suspension cultured tobacco,Nicotiana tabacum, were grown in a medium containing the two plant hormones -naphthaleneacetic acid and benzyladenine, in the presence or absence of 10M taxol. Changes in cell size and shape were quantified using a video image analysis system. Cell elongation had begun within 48h of protoplast conversion, in both treatments, and continued for 7 days. Immunolocalization of tubulin showed that, in the majority of cells, MTs were disorganized immediately following protoplast conversion. After elongation, the MT arrays were observed to have reoriented to an ordered state. Taxol-treated protoplasts were found to elongate faster and to a greater extent than the non-treated controls. Additionally, the cortical array of taxol-treated protoplasts reorganized more quickly. These data indicate that the net depolymerization of disordered cortical MTs is not necessarily required for the differentiation of a protoplast into an elongate cell.Abbreviations APM amiprophosmethyl - BSA bovine serum albumin - DIC differential interference contrast - DTT dithiothreitol - EGTA ethylenegrycol-bis-(-aminoethyl ether)N,N,N,N-tetra-acetic acid - ELISA enzyme-linked immunosorbent assay - FMS Fukuda, Murashige, and Skoog - MS Murashige and Skoog - MT(s) microtubule(s) - PBS phosphate buffered saline - PIPES piperazine-N,N-bis (2-ethanesulfonic acid, 1.5 sodium) - PM plasma membrane - Tris Tris(hydroxymethyl)amino-methane     

Sodium efflux at 0°C in single barnacle muscle fibers

Summary A study has been made of the efflux of radiosodium in single barnacle muscle fibers cooled to 0°C. Cooling from 24 to 0°C results in a rapid fall in the Na efflux, the magnitude of which averages 81%. Rewarming leads to almost complete restoration of the Na efflux. The Arrhenius plot shows no breaks and gives anE _a value of 14.2 kcal/mol. External application of 10^–4 m-ouabain following cooling to 0°C causes a fall in the residual efflux (8%). Rewarming results in partial restoration of the Na efflux. Lowering external pH (pH _e ) results in a rise in Na efflux at 0°C, which peaks and declines rather slowly. The magnitude of the stimulatory response to acidification is a function of pH _e over the pH _e 7.00–5.8 range, the theoretical threshold being pH _e 7.1. The magnitude of the response to acidification of cooled, ouabain-poisoned fibers suspended in Li-ASW is the same as that of fibers suspended in Na-ASW. Injection of pure protein kinase inhibitor into fibers maintained at 0°C fails to reduce the size of the response to acidification. Benzolamide but not acetazolamide, ethoxzolamide or Cl 13,580 abolishes the response to acidification. It also reverses the response to acidification. SITS is also able to abolish the response to acidification. An additional new observation is that the Na efflux at 0°C is stimulated following the injection of CaCl₂ in a concentration-dependent manner. A similar response is not seen with MgCl₂. Acidification (pH _e 5.8) following peak stimulation by injection of CaCl₂ is without effect. These results add up to a refutation of the concept that the Na efflux at 0°C is wholly passive and that the response to acidification involves Na:Na or Na:Ca exchange. The results also weaken the argument that stimulation of the efflux by acidification is the result of activation of carbonic anhydrase.     

Stimulation by high external potassium of the sodium efflux in barnacle muscle fibers

Summary Single barnacle muscle fibers fromBalanus nubilus were used to study the effect of elevated external potassium concentration, [K] _o , on Na efflux, membrane potential, and cyclic nucleotide levels. Elevation of [K] _o causes a prompt, transient stimulation of the ouabain-insensitive Na efflux. The minimal effective concentrations is 20mm. The membrane potential of ouabain-treated fibers bathed in 10mm Ca²⁺ artificial seawater (ASW) or in Ca²⁺-free ASW decreases approximately linearly with increasing logarithm of [K] _o . The slope of the plot is slightly steeper for fibers bathed in Ca²⁺-free ASW. The magnitude of the stimulatory response of the ouabain-insensitive Na efflux to 100mmK _o depends on the external Na⁺ and Ca²⁺ concentrations, as well as on external pH, but is independent of external Mg²⁺ concentration. External application of 10^–4 m verapamil virtually abolishes the response of the Na efflux to subsequent K-depolarization. Stabilization of myoplasmic-free Ca²⁺ by injection of 250mm EGTA before exposure of the fiber to 100mm K _o leads to 60% reduction in the magnitude of the stimulation. Pre-injection of a pure inhibitor of cyclic AMP-dependent protein kinase reduces the response of the Na efflux to 100mm K _o by 50%. Increasing intracellular ATP, by injection of 0.5m ATP-Na₂ before elevation of [K] _o , fails to prolong the duration of the stimulation of the Na efflux. Exposure of ouabain-treated, cannulated fibers to 100mm K _o for time periods ranging from 30 sec to 10 min causes a small (60%), but significant, increase in the intracellular content of cyclic AMP with little change in the cyclic GMP level. These results are compatible with the view that the stimulatory response of the ouabain-insensitive Na efflux to high K _o is largely due to a fall in myoplasmicpCa resulting from activation of voltage-dependent Ca²⁺ channels and that an accompanying rise in internal cAMP accounts for a portion of this response.     

Electrolytes control flows of water across the apical barrier in toad skin: The hydrosmotic salt effect

Summary The reversible dependence of skin osmotic water permeability (L _PD ) upon the ionic concentration of the outer bathing solution — which we have called hydrosmotic salt effect (HSE) — was studied in the isolated skin of the toadBufo marinus ictericus. The skin osmotic water flow (J _V ) was measured as a function of outer bathing solution osmolality (O _e ).L _PD , calculated as (J _v /) _P=0 (where and P are the osmotic and hydrostatic pressure differences across the skin, respectively) was constant whenO _e was altered with sucrose, a nonelectrolyte. In contrast,L _PD increased continuously in the hypotonic range asO _e was raised from zero (distilled water) with NaCl or KCl. The HSE could also be evoked in the condition of reversed osmotic volume flow, with the outer bathing medium made hypertonic with sucrose.Diffusional¹⁴C-sucrose permeability, measured in theJ _v =0 condition to prevent solvent drag of sucrose in the paracellular pathways, indicate that the hydrosmotic salt effect cannot be explained by assuming a paracellular permeability increase, due to tight junction opening, but might be interpreted as due to changes in the osmotic water permeability of the apical membranes of the most superficial cells of the epithelium.The hydrosmotic salt effect can be elicited in control skins and in vasopressin-stimulated skins, on top of the hormonal response.The time course of the hydrosmotic salt effect is substantially different from that of the hydrosmotic response to vasopressin. Its half-time is 4 to 5 times faster than that of vasopressin action, with individual values as short as 1.5 min.The time courses of the hydrosmotic salt-effect onset and reversibility are exponential, clearly contrasting with the typical sigmoidal shape of vasopressin onset and washout time courses.Based on time course data and on speed of response we postulate that the mechanism underlying the hydrosmotic salt effect is due to modifications of existing water pathways in the apical membrane, rather than to incorporation and removal of water permeability units in this structure.     

Forskolin increases osmotic water permeability of rabbit cortical collecting tubule

Summary Forskolin is a unique diterpene that may directly activate the catalytic subunit of adenylate cyclase. We therefore examined the effect of 50 m forskohn on osmotic water permeability in rabbit cortical collecting tubules perfusedin vitro. Forskolin increased net volume flux (J _v , from 0.30 to 1.22 nl/mm/min,P<0.02) in all tubules. The hydro-osmotic effect of forskolin was similar with respect to magnitude and time course to that produced by a maximal dose (250 U/ml) of arginine vasopressin. An additive effect onJ _v andL _p was not observed when maximal concentrations of forskolin and arginine vasopressin were given simultaneously. The compound d(CH₂)₅Tyr(Et) VAVP, which noncompetitively inhibits the vasopressin receptor, significantly reduced collecting tubular hydro-osmotic response to arginine vasopressin. In contrast, the hydro-osmotic response to forskolin was maintained in the presence of d(CH₂)₅ Tyr(Et)VAVP. However, the hydro-osmotic response to forskolin could be inhibited by 1.0 m guanine 5-(,-imido) triphosphate (GppNHp) and by the calmodulin inhibitor N-(6-amenohexyl)-5-chloro-1-naphthalenesulfonamide (W-7). These results demonstrate that forskolin exerts an hydro-osmotic effect in the mammalian nephron which occurs independent of the vasopressin receptor. Guanine nucleotide regulatory proteins may modulate the osmotic water permeability effect of forskolin. Finally, calmodulin is required for full expression of the effect of forskolin to increase osmotic water flux.