Actions of carbaryl on the ionic transport across the isolated skin of Rana esculenta

1. Carbaryl, a carbamate used as a pesticide, increases the short-circuit current (SCC) across the isolated frog skin in a dose-dependent manner. 2. This effect is due to the stimulation of sodium absorption and chloride secretion. 3. Carbaryl action on short-circuit current is unrelated to its inhibitory power on cholinesterase; this statement is supported by two experimental results: (a) carbaryl is equally active on both sides of the skin, (b) atropine pretreatment does not inhibit the carbaryl action on SCC.     

Active transport of chloride across skin isolated from Rana esculenta]

The effect of SITS, ouabain and acetazolamide on potential difference (E) and short-circuit current (ccc) across isolated frog skin after Amiloride treatment have been investigated. It has been found that Amiloride (3.5 . 10(-5)M) reverses the E and ccc values. After Amiloride treatment, with the use of SITS (6 . 10(-4)M) positive values of E and ccc have been measured while Ouabain (10(-4)M) only slightly reduces the reversed E and ccc values. On the other hand the effect of Acetazolamide (6 . 10(-4)M) is additional to the effect of SITS. It is suggested that the frog skin possesses an active transport for Cl-, as demonstrated by the use of Amiloride, and that it is carried out by two distinct mechanism: the first SITS and Acetazolamide sensible, the second one sensible to Strofantine.     

Transepithelial transport of sodium and chloride ions in isolated skin of the frog,Rana esculenta L

Isolated frog skin, mounted in a Ussing apparatus, was investigated electrophysiologically. Application of amiloride, an inhibitor of sodium ion transport, and bumetanide, known to block the transport of chloride ions, revealed the effect of these ions on PD, both under control conditions and following mechanical stimulation. Under control conditions, mechanical stimulation of the skin caused hyperpolarization, i.e. a transient increase in the electrical potential difference. Preincubation in the presence of amiloride, or amiloride plus bumetanide, brought about both a decrease in electrical potential and an inhibition of the reaction upon stimulation. On the other hand, incubation with bumetanide resulted in a decrease in electrical potential, but did not affect the skin reaction after mechanical stimulation. The above results indicate that hyperpolarization of the frog skin following mechanical stimulation is caused by enhanced transepithelial transport of sodium ions which, in turn, is induced by stimulation of sensory receptors.     

Seasonal variations of Rana esculenta L. skin tyrosinase

Various enzymes are known to be involved in melanin biosynthesis, but the key role appertains to tyrosinase. In amphibians this enzyme displays peculiar characteristics: i) it requires an activation process; ii) its level of enzymatic activity in the animal skin changes depending on the season. In this work, by using chymotrypsin, subtilisin and SDS as putative activators, we studied the activation process of the skin pro-tyrosinase of Rana esculenta L. in different seasons over a period of two years. We found that chymotrypsin and subtilisin were able to yield an active enzyme, but not SDS. The maximum levels of tyrosinase activity were recorded in winter and the minimum in summer. We detected tyrosinase activity in the melanosomal fraction, where the enzyme form was least sensitive to proteolytic activation, probably corresponding to a "mature" tyrosinase. The enzyme forms found in the microsomal and soluble fractions were more sensitive to proteolytic activation, probably corresponding to "immature" tyrosinase. On SDS-PAGE, the tyrosinase activity assays showed a dopa-positive band at 200 kDa and a second aggregated band with a still higher molecular mass. The significance of these results in frog melanogenesis regulation is discussed.     

Electrophysiological effect of ruthenium red and pH on the skin of the edible frog, Rana esculenta L

Amphibian skin is a sensitive interface between the organism and the environment. Metal ions from the external environment, some of them being trace elements, act on the amphibian skin. It had been shown that stimulation of tactile receptors affected Na+ transport in the frog skin and changed the potential difference, therefore the aim of this project was to study the effect of ruthenium complex, known as ruthenium red (RR), on the ion transport in this organ in vitro under control conditions, after mechanical stimulation and also in the presence of the Na+ transport inhibitor-amiloride. Three different concentrations of RR (0.12, 1.2, and 12.0 mM) in two different pH values (6.4 and 7.4) were studied in vitro in the Ussing apparatus. The measured electrophysiological parameters were the transepithelial electrical potential difference (PD) and the changes in PD after mechanical stimulation (dPD). The gentle mechanical stimulus was a jet of bath fluid from a peristaltic pump directed on the mucosal surface of isolated frog skin. After mechanical stimulation, transient hyperpolarization invariably occurred (dPD = 1.5 +/- 0.2 mV). In the presence of RR the hyperpolarization was smaller and this diminution was concentration dependent: 0.5 +/- 0.1 mV for 1.2 mM of RR and 0.1 +/- 0.1 mV for 1.2 mM of RR. At pH 6.4 the reactions of the skins on the mechanical and chemical stimuli were smaller, in the presence of amiloride disappearing completely, but after the washing away of amiloride from the experimental organ in pH 6.4 the action of RR was stimulatory. The natural defensive reactions of frog skin related to the ion transport and electrical potential difference are affected or disappear in the presence of ruthenium complex.     

Studies on Rana tigerina skin collagen

The current paper pertains to the study of frog skin, more specifically Rana tigerina skin collagen, which is a major extracellular matrix protein known to play an important role in the wound-healing process. This study revealed interesting differences in the frog skin collagen when compared to the hitherto known vertebrate collagens. This could probably be attributed to the position of the amphibians in the vertebrate hierarchy. Therefore, detailed investigations on the various physico-chemical properties, such as reconstitution, redissolution, viscosity and denaturation were carried out. The study confirms the structural relationship of collagen to habitat and function.     

Effect of aminoglycoside antibiotics on sodium transport across the Rana esculenta urinary bladder

The aminoglycoside antibiotics inhibit the short circuit current (s.c.c.) in the urinary bladder of Rana esculenta. This effect is due to a direct inhibition on the sodium pump; ADH or db-AMPc are not able to reverse the inhibition of the sodium current, but are effective in stimulating the urea fluxes in the presence of antibiotics. In correlation with the number of the NH+2 groups in the antibiotic molecule there is a different pattern of inhibitory effect, i.e. neomycin greater than gentamycin greater than dihydrostreptomycin greater than kanamycin greater than spectinomycin.