Salt‐induced changes in sodium transport across the skin of the euryhaline toad, Bufo viridis.

Katz, Uri

doi:10.1113/jphysiol.1975.sp010946

Cited by 24 publications

(8 citation statements)

References 17 publications

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“…In yet another species, Bufo viridis, it has been reported that adaptation of these animals to high salinities results in a reduction of amiloride sensitive sodium transport and a reduction of mucosal sodium influx (Katz, 1975). The author concludes that the effect of saline adaptation is to 'reduce the number of Na selective sites at the outer barrier', a conclusion which is in accord with our direct measurements of site density.…”

Section: Discussionsupporting

confidence: 78%

“…A sodium transporting epithelium was deprived of sodium for a period of 1 week and at the end of this time the level of transport and the density of sodium entry sites in the epithelium were measured. It had already been established that adaptation of amphibian epithelia to high or low salinities influenced the subsequent level of sodium transport by a negative feed-back reaction, that is deprived tissues had elevated transport capability and vice versa (Bentley, 1973;Katz, 1975). In these experiments it was found that sodium deprivation increased both the level of sodium transport and the numbers of membrane macromolecules controlling sodium entry into the epithelium.…”

Section: Introductionmentioning

confidence: 98%

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Induction of transporting sites in a sodium transporting epithelium.

Cuthbert¹,

Shum²

1976

The Journal of Physiology

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1. Frogs (Rana temporaria) were bathed for 1 week in solutions containing 1-1 mM sodium chloride and either one or both of amiloride (10(-4)M) and spironolactone (10(-5r both of amiloride (10(-4) M) and spironolactone (10(-5) M). This procedure was designed to deplete the sodium transporting compartment of the skin epithelium of sodium, while at the same time antagonizing the effects of endogenous aldosterone. 2. After 1 week the skins were used in vitro to measure the level of sodium transport (short-circuit current) and the density of sodium entry sites in the mucosal surface of the epithelium ([14C]amiloride binding). 3. Sodium deprivation for 1 week caused approximately a doubling of both sodium transport and the density of sodium entry sites in the mucosal surface of the epithelium compared to control skins. 4. When the results for sodium deprived and control skins were pooled there was a highly significant correlation between the density of sodium entry sites and sodium transport. 5. Mechanisms by which sodium deprivation leads to an increase in the density of sodium entry sites are discussed.

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Section: Discussionsupporting

confidence: 78%

Section: Introductionmentioning

confidence: 98%

Induction of transporting sites in a sodium transporting epithelium.

Cuthbert¹,

Shum²

1976

The Journal of Physiology

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“…However, judged from the change in net sodium transport the factor of adaptation appears to be above 100, and it can even be argued that adaptation to a high-sodium diet leads to a complete suppression of the rheogenic sodium transport. Even the lowest of these estimates of the ability ofthe chicken coprodeum to adapt functionally to the dietary sodium load exceeds the degree of adaptation observed for other sodium-transporting epithelia like rat colon and rectum (Edmonds, 1967), toad urinary bladder (Fanestil, Herman, Fimognari & Edelman, 1968), the skin of an euryhaline toad (Katz, 1975), and the goldfish intestine (Ellory, Lahlou & Smith, 1972). In the toad colon, how-501 502 I. CHOSHNIAK, B. G. MUNCK AND E. SKADHAUGE ever, the adaptation, although smaller in range, proceeds to a reversal of the sodium transport from net absorption to net secretion (Ferreira & Smith, 1968).…”

Section: The Functional Adaptation To Sodium Intakementioning

confidence: 93%

Sodium chloride transport across the chicken coprodeum. Basic characteristics and dependence on sodium chloride intake

Choshniak¹,

Munck²,

Skadhauge³

1977

The Journal of Physiology

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SUMMARY1. The transport characteristics of the chicken coprodeum have been examined in vitro using the isolated mucosa. The short-circuit current (I,), the transepithelial electrical potential difference (p.d.), the unidirectional transmural fluxes (J., J.) of sodium and chloride measured in the short-circuited state, and the unidirectional influx of sodium and chloride across the brush border membrane measured under open-circuit conditions have been studied. The effect of the sodium chloride contents of the diet on these parameters have been investigated.2. The isolated mucosa depends functionally on the presence of glucose in the incubation media. This dependence reflects the need of glucose as a fuel. There is no indication of coupling between transport of -sugars and sodium across the brush border membrane. For preparations from chickens on a low sodium diet a very high and stable ISc can quantitatively be accounted for by the net transport of sodium. Influx of sodium across the brush border membrane is not significantly different from the net flux of sodium. By feeding the chickens a high sodium diet the I,, is reduced by more than 95 %, the net transport of sodium is abolished, and the transepithelial electrical conductance is reduced by more than 50 %.3. Both unidirectional transepithelial fluxes of chloride, and the serosa to mucosa flux of sodium appear to proceed through a paracellular shunt.4. Under the conditions of the low sodium diet the paracellular pathway appears to be anion selective. Whereas, under the conditions of the high sodium regimen the paracellular route appears to be cation selective. After adaptation to a high sodium diet the influx of sodium across the brush border membrane is only moderately reduced. Consequently the decisive event in the adaptation must be localized elsewhere.

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“…Although a sodium pump is necessary for the survival of amphibians in fresh water a decrease in its activity when animals are in highly saline environments would place less burden on the kidneys and bladder to excrete excess electrolytes. A decrease in sodium uptake has been shown in several species when acclimated to high salinities (Ferreira and Jesus, 1973;Katz, 1975).…”

Section: Discussionmentioning

confidence: 99%

Osmoregulation of the cane toad, Bufo marinus, in salt water

Liggins

Grigg

1985

Comparative Biochemistry and Physiology Part A: Physiology

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Abstract-1. Adult cane toads, B. marinus, survived in salinities up to 40% sea-water (SW).2. Pre-exposure to 30, then 40% SW, increased the survival time of toads in 50% SW. 3. Plasma from toads acclimated to salt water is hyperosmotic to the environment -a result of increased plasma sodium, chloride and urea concentrations.4. When toads were placed in tap-water and 20% SW, all significant changes to plasma sodium, chloride, urea and osmotic pressure occurred within the first 2 days of exposure.5. When toads were placed in 30 and 40% SW environments, the increases in plasma sodium and chloride concentrations occurred within the first 2 days of exposure while urea and total osmotic pressure continued to rise until some time between 2 and 7 days exposure.

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Salt‐induced changes in sodium transport across the skin of the euryhaline toad, Bufo viridis.

Cited by 24 publications

References 17 publications

Induction of transporting sites in a sodium transporting epithelium.

Induction of transporting sites in a sodium transporting epithelium.

Sodium chloride transport across the chicken coprodeum. Basic characteristics and dependence on sodium chloride intake

Osmoregulation of the cane toad, Bufo marinus, in salt water

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