Current-voltage relations of the apical and basolateral membranes of the frog skin

We determined the current-voltage (I-V) relations of the apical and basolateral barriers of frog skins by impaling the cells with an intracellular microelectrode and assuming that the current across the cellular pathway was equal to the amiloride-inhibitable current. We found that: (a) The responses in transepithelial current and intracellular potential to square pulses of transepithelial potential (VT) varied markedly with time. (b) As a consequence of these transient responses, the basolateral I-V relation was markedly dependent on the time of sampling after the beginning of each pulse. The apical I-V plot was much less sensitive to the time of sampling within the pulse. (c) The I-V data for the apical barrier approximated the I-V relations calculated from the Goldman constant field equation over a relatively wide range of membrane potentials (+/- 100 mV). (d) A sudden reduction in apical bath [Na+] resulted in an increase in apical permeability and a shift in the apical barrier zero-current potential (Ea) toward less positive values. The shift in Ea was equivalent to a change of 45 mV for a 10-fold change in apical [Na+]. (e) The transient responses of the skin to square VT pulses were described by the sum of two exponentials with time constants of 114 and 1,563 ms, which are compatible with the time constants that would be produced by an RC circuit with capacitances of 65 and 1,718 microF. The larger capacitance is too large to identify it comfortably with a true dielectric membrane capacitance.     

Differences between resting and insulin-stimulated amino acid transport in frog skeletal muscle

Summary We have compared some features of the resting and the insulin-stimulated uptake of -aminoisobutyrate (AIB) in frog skeletal muscle. We found a substantial difference between the two processes, namely, that resting AIB uptake is Na-independent while the insulin-stimulated fraction of the AIB uptake is Na-dependent.Since the amino acid transport systems in frog skeletal muscle are poorly characterized, we have also surveyed some of their properties. One of the most interesting findings of this survey is that both the uptake and efflux of AIB are inhibited by low concentrations of PCMBS (parachloro-mercury-benzene sulfonic acid 5×10^–5 m). In contrast, the carrier mediated transport of basic amino acids is neither inhibited by this mercurial agent nor accelerated by insulin.The action of PCMBS strongly suggests the presence of a critical sulfhydryl group in the amino acid carrier system utilized by AIB. This group is exposed to the outside solution since PCMBS penetrates cell membranes poorly, and in addition its inhibitory actions were reverted by agents that do not penetrate the cell membrane like albumin or glutathione.     

Exocytotic events unrelated to regulation of water permeability in amphibian tight epithelia: effects of oxytocin, PMA and insulin on membrane capacitance, water and Na+ transport

We measured the effects of oxytocin on capacitance and hydroosmotic water flow in the urinary bladder of the toad Bufo marinus and the skins of Rana pipiens and Rana temporaria. Oxytocin increased capacitance in all these tissues but stimulated hydroosmotic water flow only in the urinary bladder. We also measured the effects of oxytocin and PMA on the capacitance and hydroosmotic water flow of the toad urinary bladder. Both agents produced increases in membrane capacitance that were additive, however, PMA produced a stimulation of water flow that was only a fraction of that caused by oxytocin. Comparison of the effects of PMA and insulin in toad urinary bladder showed that in contrast with PMA, insulin did not increase membrane capacitance in this tissue. Moreover, insulin stimulated Isc in the urinary bladder while PMA produced an inhibition of variable magnitude. These results suggest that: (1) oxytocin can promote the fusion with the apical membrane of cytoplasmic membranes with or without water channels; (2) oxytocin and PMA stimulate the fusion with the apical membrane of cytoplasmic membranes originating in different pools; membranes in each pool have different water permeabilities and their insertion is controlled by different signals; (3) PMA and insulin act through different mechanisms in the toad urinary bladder.     

Role of an apical cation-selective channel in function of tight epithelia

Some features of oxytocin stimulation of a cation-selective channel of the apical membrane of amphibian tight epithelia were examined in an attempt to understand the channel's role in the regulation of epithelial transport. We first examined the ability of the channel to pass alkaline-earth cations. We found that oxytocin can stimulate the movement of alkaline-earth ions through the channel. This stimulation became greatly enhanced by treatment with Ag+. The stimulation of alkaline-earth movements is discussed together with recently reported experiments which suggest that the channel may be involved in K+ secretion. In addition we carried out comparative studies of the effects of oxytocin on the channel in a variety of epithelia obtained from different amphibians to examine whether the stimulation of ionic currents through the channel and the enhancement of hydrosmotic permeability caused by the hormone are linked. The results of our experiments showed that oxytocin activates the channel in the urinary bladders of Bufo marinus, and Rana catesbeiana as well as in the skin of B. marinus. It is well known that in all these tissues the hormone increases water permeability of the apical membrane. On the other hand, in skins of Rana catesbeiana, Rana pipiens, and Rana temporaria, where oxytocin does not have a hydrosmotic effect, the hormone did not increase the currents through the cation-selective channel.     

Permeable junctional complexes. The movement of lanthanum across rabbit gallbladder and intestine

Ionic lanthanum has been used to study transepithelial ion permeation in in vitro rabbit gallbladder and intestine (ileum) by adding 1 mM La³⁺ to only the mucosal bathing solution. Transepithelial fluid transport electrical potential differences (p.d.), and resistances were measured. During La³⁺ treatment the gallbladder''s rate of active solute-coupled fluid transport remained constant, the resistance increased, and the 2:1 NaCl diffusion p.d. decreased. Mucosa-to-serosa fluxes of ¹⁴⁰La³⁺ were measured and indicate a finite permeability of the gallbladder to La³⁺. La³⁺ also increased the transepithelial resistance and p d. of ileum. Electron microscopic examination of La³⁺-treated gallbladder showed: (a) good preservation of the fine structure, (b) electron-opaque lanthanum precipitates in almost every lateral intercellular space, most frequently near the apical end of the lateral spaces close to or within the junctional complex, (c) lanthanum among the subjacent muscle and connective tissue layers, and (d) lanthanum filling almost the entire length of so-called "tight" junctions. No observations were made which unequivocally showed the penetration of lanthanum into the gallbladder cells. Electron micrographs of similar La³⁺-treated ilea showed lanthanum deposits penetrating the junctional complexes. These results coupled with other physiological studies indicate that the low resistance pathway for transepithelial ion permeation in gallbladder and ileum is through the tight junctions A division of salt-transporting epithelia into two main groups, those with "leaky" junctional complexes and those with tight junctional complexes, has been proposed.     

LOCALIZATION OF PERMEABILITY BARRIERS IN THE FROG SKIN EPITHELIUM

Ruthenium red and colloidal lanthanum were used to determine the site of the structural barriers to diffusion within the intercellular spaces of frog skin epithelium. Electron micrographs show that occluding zonules located at the outer border of the stratum corneum and at the outer layer of the stratum granulosum are true tight junctions since they are impermeable to these tracers. Measurement of ¹⁴⁰La uptake by the living skin shows that lanthanum moves across the external surface of the skin readily, into and out of a compartment that has a limited capacity and is bounded on its internal side by a barrier impermeable to lanthanum. Examination of these skins with the electron microscope suggests that the compartment is localized between the external membrane of the cells at the outer layer of the s. granulosum and at the outermost surface of the skin. These observations and other findings described in the literature indicate that the site of the external high resistance barrier of the frog skin is localized at the outer border of the s. granulosum.     

Action of insulin and cell calcium: effect of ionophore A23187.

We have measured the effects of the carboxylic Ca++ ionophore A23187 on muscle tension, resting potential and 3-O-methylglucose efflux. The ionophore produces an increase in tension that is dependent on external Ca++ concentration since (a) the contracture was blocked by removing external Ca++ and (b) its size was increased by raising outside Ca++. Neither resting potential nor resting and insulin-stimulated sugar efflux were modified by the ionophore. These data imply that the action of insulin is not mediated by increasing cytoplasmic [Ca++]. Additional support for this conclusion was obtained by testing the effects of caffeine on sugar efflux. This agent, which releases Ca++ from the reticulum, did not increase resting sugar efflux and inhibited the insulin-stimulated efflux. Incubation in solutions containing butyrated derivatives of cyclic AMP or cyclic GMP plus theophylline did not modify the effects of insulin on sugar efflux. Evidence suggesting that our experimental conditions increased the cytoplasmic cyclic AMP activity was obtained.