Effects of Evans Blue and amiloride on anti-diuretic hormone (ADH)-induced sodium transport across frog (Rana hexadactyla) skin.

The epithelial sodium channel (ENaC) has four subunits, namely α (alpha), ß (beta), γ (gamma) and δ (delta). The functional ENaC is formed by the combination of either αßγ or δßγ subunits. The aim of the present study is to determine the combination of ENaC subunits predominant on the apical side of the frog skin, and the effect of ADH on sodium transport though these two ENaCs subunit combinations. The ventral abdominal skin of the frog, Rana hexadactyla was mounted in an Ussing-type chamber. The voltage-clamp method was performed to measure the ionic transport across the frog skin with normal Ringer solution (NR) on both sides. Evans blue (300 µM) and amiloride (100 µM) were added to the NR on the apical side and ADH (40 nM) was added on the serosal side. Statistical significance was analyzed by Student's paired t-test and repeated-measures ANOVA, P < 0.05 was considered significant. This study suggests that the ENaC of the frog skin consist of both αßγ and δßγ subunit combinations on the apical side. Though both types of subunit combination are present, the αßγ type was found to be more common than δßγ. ADH increases the sodium transport across the frog skin. The effect of ADH on sodium transport is achieved through the combination of δ-subunits, not through the combination of a-subunits in the skin of Pana hexadactyla.

Requirement of potassium for the action of anti-diuretic hormone (ADH) on frog skin.

The aim of the present study is to study whether the presence of K(+) in bathing media is required for the action of ADH to the ionic transport across the skin in the frog species Rana hexadactyla. lonic transport was measured as transepithelial potential difference (TEPD) and short circuit current (SCC) by using an indigenously developed computer based voltage-clamp technique. Addition of ADH (40 nM) on the serosal side significantly increased the TEPD and SCC with Normal Ringer (NR) on both sides. ADH had no effect subsequent to amiloride (100 µM) pre-treatment, which confirmed the ADH-induced Na(+) transport. Chloride also has a significant role in the development of TEPD. To determine the role of K(+), Potassium-free Ringer (KFR) was placed on both sides; addition of ADH had no effect consequently. Further experiments were carried out to find out which side of K(+) was required for the action of ADH. There was a lack of ADH effect with apical NR and serosal KFR, demonstrating that serosal K(+) is essential to activate Na(+), K(+)- ATPase. Similarly, the ADH effect was lacking with apical KFR and serosal NR that was the novel finding of this study. Due to the concentration gradient, the K(+) was secreted from serosal side to apical side through barium (1 mM) blockable K(+) channel. This study provides evidence that serosal as well as apical K(+) are necessary for the action of ADH.

Actions of antidiuretic hormone analogues on intact and nystatin-permeabilized frog skins.

The roles of two antidiuretic hormone analogues, namely arginine vasotocin (AVT) and lysine vasopressin (LVP), in solute transport across the ventral abdominal skin of frogs (Rana hexadactyla) were studied using voltage-clamp methods on intact and nystatin-permeabilized preparations. Arginine vasotocin (40 nm), the amphibian analogue of antidiuretic hormone, did not have any effect on the skin of Rana hexadactyla. However, LVP, the porcine antidiuretic hormone, increased the transepithelial potential difference (TEPD) and short-circuit current (SCC) significantly, without affecting the slope conductance. Lysine vasopressin had no action subsequent to addition of amiloride (100 microm) on the apical side or ouabain (10 microm) on the basolateral side. Lysine vasopressin increased slope conductance in the nystatin-permeablized skin while decreasing TEPD. Such a change was not seen in chloride-free solutions. To elucidate the mechanism of action of LVP on intact skin, experiments were done with forskolin and a V(2) receptor blocker. The effects of forskolin (10 microm) were different from those of LVP in that forskolin significantly increased SCC and conductance of the intact skin, while decreasing TEPD. The forskolin-induced increase in conductance was not abolished by amiloride. Use of the V(2) receptor blocker inhibited the effects of LVP. We conclude that AVT does not have an action on the skin of Rana hexadactyla. Lysine vasopressin enhances transepithelial sodium transport by increasing sodium-potassium pump activity, while not affecting the epithelial sodium channel conductance. Lysine vasopressin also enhances an inward-directed conductance on the basolateral membrane, probably a chloride conductance. The action of LVP on the intact frog skin is through the V(2) receptors; however, downstream signalling does not seem to be mediated by cAMP. Analysis of the electrophysiological model of frog skin with LVP allows us additionally to conclude that modulation of channel activity and not carrier-mediated transport affects slope conductance.