A comparative study of the effects of norepinephrine and vasopressin on Na transport and O2 consumption in frog skin

Oxygen consumption and active sodium and chloride transport in bovine tracheal epithelium

The O2 consumption (Jr) and the short-circuit current (Ji) were measured simultaneously in bovine tracheal epithelium in vitro. In this tissue, Ji is the sum of two active transport processes, Cl- secretion and Na+ absorption. Jr was determined from the decrease of PO2 in the incubation solution, at 37 +/- 0.05 degrees C and at a PO2 around 600 torr. Microbial contamination and leaks of dissolved O2 from the solution never exceeded 4% of the rate of PO2 decrease due to the O2 consumption of the tissue. Ji and Jr were stable over 5 h of incubation under standard conditions. Ji was 106 +/- 4 nequiv min-1 cm-2 and Jr was 39.8 +/- 1.1 nmol O2 min-1 cm-2 (mean +/- S.E., n = 46). Ji was varied with several agents known to affect ion transport across the tracheal epithelium. Na+ absorption was inhibited partly with amiloride or completely following Na+ substitution with choline. Cl- secretion was selectively suppressed by furosemide. Ji was also reduced to a very low level, using ouabain or K+ suppression to inhibit the Na+-K+-ATPase. All these manoeuvres resulted in significant reductions of both Ji and Jr. Basal Jr was not affected when Ji was modified. A plot of the relative change in suprabasal Jr versus the relative change of Ji gave a straight line (r = 0.98, n = 60). A plot using absolute values yielded a stoichiometric ratio of 13.9 ions per O2 molecule, for Na+ as well as for Cl-. The stoichiometric ratio was also calculated for each experiment. Its mean value was 14.9 ions per O2 molecule. The population of the ratios was widely dispersed, but this was explained as a predictable statistical phenomenon.

Time course of active Na transport and oxidative metabolism following transepithelial potential perturbation in toad urinary bladder

The use of an Ussing chamber with well-defined mixing characteristics coupled to a mass spectrometer permits the concurrent evaluation of transepithelial current and oxidative metabolism with improved temporal resolution. The time-course of the amiloride-sensitive current Ia and the rate of suprabasal CO2 production JsbCO2 were observed in 10 toad urinary bladders at short-circuit and after clamping delta psi at 100 mV, serosa positive. Following perturbation of delta psi (0 leads to 100 mV), Ia declined sharply within 1/2 min, remaining near constant approximately 15 min, and then increased slightly. JsbCO2 declined more gradually, remained near constant at approximately 4-7 min, and then declined further. Detailed analysis revealed an early quasi-steady state with near constancy of JsbCO2 starting at 2.9 +/- 1.1 (SD) min and lasting 4.7 +/- 1.8 (SD) min, followed by relaxation to a later steady state at about 15 min. During the early quasi-steady state, Ia was also nearly constant. Considering that in steady states Ia/F approximately or equal to JaNa, the rate of transepithelial active Na transport, during the early quasi-steady state mean values +/- SE of JaNa, JsbCO2 and (JaNa/JsbCO2) were, respectively, 29.9 +/- 1.7%, 59.4 +/- 3.2%, and 56.4 +/- 5.7% of values at short-circuit. Corresponding values during the late steady state were 41.4 +/- 6.0%, 38.2 +/- 6.1%, and 111.3 +/- 8.6%. Thus the flow ratio JaNa/JsbCO2 was depressed significantly during the early quasi-steady state, but returned later to the original value. The results of measurements of Ia and JsbO2 in three hemibladders were qualitatively similar. In terms of a phenomenological "black-box" treatment the findings are consistent with earlier studies indicating incomplete coupling between transport and metabolism. Further studies will be required to clarify the molecular basis for these observations.

Oxygen consumption by frog skin and its isolated epithelial layers as a function of their sodium-transporting activity

The metabolic cost (in terms of oxygen consumption) of transcellular sodium transport was assessed on ventral frog skin and its isolated epithelial layers, by measuring the decrease in oxygen consumption by the tissue upon transient withdrawal of sodium from the outside solution. The same number of sodium ions was transported per molecule oxygen consumed whole skin (17.4 +/- 2.3) and its isolated epithelium (17.3 +/- 2.4). The metabolic cost of sodium transport could not be estimated properly when this process was blocked by amiloride or ouabain, as these drugs were found to bring about an increase in oxygen consumpton by the tissue when no sodium was available for transport.

A comparative study of the effects of norepinephrine and vasopressin on Na transport and O2 consumption in frog skin

Experiments were designed to compare the effects of two hormones-vasopressin and norepinephrine-on the energetics of Na transport in frog skin. Simultaneous measurements of O2 consumption and net Na flux were performed in the same skins by means of O2 cathodes and the short circuit current technique. The results showed that both hormones induced similar increments in Na transport. In contrast, there was a conspicuous difference in O2 consumption values, norepinephrine having a very small stimulatory effect compared to the one induced by vasopressin. Thus, despite the fact that both hormones increase Na permeability of frog skin by similar mechanisms and to a similar extent, they appear to exert very different effects on cell metabolism.