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.     

Cytochemical localization of adenylate cyclase in the sodium-transporting epithelium isolated from frog skin

Summary A modified cytochemical technique with 5-adenylylimidodiphosphate as substrate, was used to examine the distribution of adenylate cyclase in cells comprising the transepithelial Na⁺ transport pathway in isolated frog skin epithelium. Particular attention was paid to the effects of fixation on the activity and localization of adenylate cyclase. Fixation in glutaraldehyde alone or in combination with paraformaldehyde reduced the amount of reaction product, while better results were obtained using unfixed tissues. Optimum results were obtained following stimulation of adenylate cyclase with forskolin and in the presence of specific metabolic inhibitors. Adenylate cyclase was localized in the basolateral membranes of the principal cells which constitute a functional syncytium for Na⁺ transport and was absent from the apical membranes of the outermost granulosum cells. This distribution is consistent with the transepithelial Na⁺ transport model and defines the functional morphology of the cells involved in Na⁺ transport across frog skin. The results are compatible with the process of Na⁺ re-absorption across other epithelial cells, verifying that frog skin is a convenient model-tissue to study Na⁺ transport mechanisms. Adenylate cyclase was also found in membranes of the mitochondria-rich cells, a minor and parallel Na⁺ transporting pathway.     

Sodium transport across isolated epithelial structures in vitro--Ledakrin in the liposomes as a moderator of the bioelectric activity of frog skin

The effect of Ledakrin (an acridine derivative with antineoplastic action), free or liposome-bound, on the bioelectric activity of frog skin was studied by the method of Ussing and it was shown that this activity (being a function of sodium transport) depended on the chemical composition of the liposomes as well as on the calcium content of the experimental medium. Two conclusions have been drawn: 1) the first phase of the response triggered by Ledakrin is due to its action on the cell membrane, 2) the second phase depends on an intracellular mechanism due, probably, to Ledakrin effect on the cytoskeleton.     

Oxygen consumption of animals and tissues as a function of temperature

The generally accepted view that rates of oxygen consumption of tissues and poikilotherms increase regularly with rising temperature was subjected to careful examination using brain slices and skin of rats and nine different species of aquatic and terrestrial animals. It was found that, although there are statements in the literature to the contrary, the influence of temperature is a regular one and respiration increases with rising temperature so that when rates of oxygen consumption are plotted against temperature the resulting curve is regular without dips or peaks except the maximum expected at the optimum temperature.     

Cell sodium activity and sodium pump function in frog skin

Summary Cell Na activity,a _Na ^c , was measured in the short-circuited frog skin by simulaneous cell punctures from the apical surface with open-tip and Na-selective microelectrodes. Skins were bathed on the serosal surface with NaCl Ringer and, to reduce paracellular conductance, with NaNO₃ Ringer on the apical surface. Under control conditionsa _Na ^c averaged 8±2mm (n=9,sd). Apical addition of amiloride (20 m) or Na replacement reduceda _Na ^c to 3mm in 6–15 min. Sequential decreases in apical [Na] induced parallel reductions ina _Na ^c and cell current,I _c . On restoring Na after several minutes of exposure to apical Na-free solutionI _c rose rapidly to a stable value whilea _Na ^c increased exponentially, with a time constant of 1.8±0.7 min (n=8). Analysis of the time course ofa _Na ^c indicates that the pump Na flux is linearly related toa _Na ^c in the range 2–12mm. These results indicate thata _Na ^c plays an important role in relating apical Na entry to basolateral active Na flux.     

Effects of metabolic inhibitors and drugs on ion transport and oxygen consumption in isolated frog skin

Active ion (NaCl) transport across isolated frog skin is discussed in relation to sodium and potassium composition and to O(2) consumption of skin. A distinction is made between processes in skin related to "unidirectional active ion transport" and processes related to "maintenance electrolyte equilibrium;" i.e., ionic composition of skin. Several metabolic inhibitors were found that could be used in separating maintenance electrolyte equilibrium from unidirectional active ion transport. Fluoroacetate (up to 1 x 10(-2)M/liter) did not affect maintenance electrolyte equilibrium, but severely diminished the rate of active ion transport. This could also be accomplished with azide and diethyl malonate when 1 x 10(-3) molar concentrations were used. When applied in higher concentrations, these two inhibitors, and several others, diminished active ion transport, but this was associated with changes in maintenance electrolyte equilibrium (gain of Na(+) by and loss of K(+) from skin). Similar observations were made when skins were subjected to K(+)-deficient media. Mersalyl and theophylline, in low concentrations, stimulated active ion transport without leading to changes in maintenance electrolyte equilibrium. Inhibition of active ion transport was found accompanied by decrease, increase, and unaltered over-all O(2) consumption, depending on the kind of chemical agent used. A provisional scheme of the mechanism of unidirectional active ion transport is proposed. It is conceived as a process of metabolically supported ion exchange adsorption, involving a carrier, forming complexes with K(+) and Na(+), a trigger, K(+) ions, and two spatially separated metabolic pathways.     

Evaluation of the rate of basal oxygen consumption in the isolated frog skin and toad bladder

In the study of active transport it is important to distinguish between oxygen consumption sustaining transepithelial transport and that responsible for other tissue functions (basal metabolism). Since amiloride blocks transepithelial active sodium transport and the associated oxygen consumption in the frog skin and toad bladder, we and others have employed this agent to evaluate the rate of basal metabolism. This technique has recently been criticized in a report that amiloride (and ouabain) increased oxygen consumption when no sodium was available for transport. We have been unable to corroborate these observations.With magnesium-Ringer as external bathing solutions, amiloride and ouabain failed to stimulate oxygen consumption. With sodium-Ringer as external bathing solution amiloride reduced oxygen consumption about 30%, to a level indistinguishable from that found on external substitution of magnesium-Ringer for sodium-Ringer. We conclude that the use of amiloride permits evaluation of the rate of basal metabolism with acceptable accuracy; a possible slight depressant effect of ouabain on basal metabolism remains to be investigated.     

Energetics of sodium transport in frog skin. I. Oxygen consumption in the short-circuited state

Sodium transport and oxygen consumption were studied simultaneously in the short-circuited frog skin. Sodium transport was evaluated from I _o /F, where I _o is the short-circuit current measured with standard Ringer''s solution bathing each surface and F is the Faraday constant. Oxygen tension was measured polarographically. Under a variety of circumstances the rate of oxygen consumption from the outer solution exceeded that from the inner solution, the ratio being constant (0.57 ± 0.09 SD). Both I _o and the associated rate of oxygen consumption J _ro declined nonlinearly with time, but the relationship between them was linear, suggesting that the basal oxygen consumption was constant. For each skin numerous experimental points were fitted by the best straight line. The intercept (J _ro)_Io=0 then gave the basal oxygen consumption, and the slope dNa/dO₂ gave an apparent stoichiometric ratio for a given skin. The basal oxygen consumption was about one-half the total oxygen consumption in a representative untreated short-circuited skin. Values of dNa/dO₂ in 10 skins varied significantly, ranging from 7.1 to 30.9 (as compared with Zerahn''s and Leaf and Renshaw''s values of about 18). KCN abolished both I _o and J _ro. 2,4-dinitrophenol (DNP) depressed I _o while increasing J _ro four- to fivefold. Anti-diuretic hormone stimulated and ouabain depressed both I _o and J _ro; in both cases apparent stoichiometric ratios were preserved.     

Evaluation of the rate of basal oxygen consumption in the isolated frog skin and toad bladder.

In the study of active transport it is important to distinguish between oxygen consumption sustaining transepithelial transport and that responsible for other tissue functions (basal metabolism). Since amiloride blocks transepithelial active sodium transport and the associated oxygen consumption in the frog skin and toad bladder, we and others have employed this agent to evaluate the rate of basal metabolism. This technique has recently been criticized in a report that amiloride (and ouabain) increased oxygen consumption when no sodium was available for transport. We have been unable to corroborate these observations. With magnesium-Ringer as external bathing solutions, amiloride and ouabain failed to stimulate oxygen consumption. With sodium-Ringer as external bathing solution amiloride reduced oxygen consumption about 30%, to a level indistinguishable from that found on external substitution of magnesium-Ringer for sodium-Ringer. We conclude that the use of amiloride permits evaluation of the rate of basal metabolism with acceptable accuracy; a possible slight depressant effect of ouabain on basal metabolism remains to be investigated.     

Ionic fluxes in isolated epithelial cells of the abdominal skin of the frog Leptodactylus ocellatus.

Unidirectional ion fluxes are measured in cells isolated by a trypsination-dissection method from the epithelium of the frog Leptodactylus ocellatus. Potassium seems to be contained in a single cellular compartment. The influx of potassium is 0.0068 mumole min-1 mg-1 of dry weight and is carried by a ouabain-sensitive pump. Sodium seems to be contained in two cellular compartments, one of which does not exchange its Na within the experimental period. The possibility that these compartments reflect the existence of different types of cells is not discarded. 49% of the rate constant for the Na efflux is ouabain-sensitive and 23% is ethacrynic-sensitive. Under control conditions the permeability to potassium (PK), sodium (PNa) and chloride (PC1) are 7.6 X 10(-5), 2.6 X 10(-5) and 2.8 X 10(-5) liters/min mg, respectively. The value of PNa is much higher than predicted by current electrical models of the epithelium. The discrepancy might offer some insight into the nature of the "inner facing barrier" of the skin.     

Oxygen consumption by isolated mitochondria: Software for planning and interpreting experiments

A computer program for teaching is described which stimulates oxygen consumption by isolated mitochondria. The effects of different compounds (substrates, inhibitors, uncouplers) may be tested. Results from evaluation with 166 undergraduate and 11 postgraduate students are presented.