Speculations on the evolution of ion transport mechanisms.

Primate cells evolved a plasma membrane to restrict the loss of important molecules. The osmotic problems that then arose were solved in one of several ways. Of major importance was the evolution of specific ion pumps, to actively extrude those salts whose inward diffusion would have led to swelling and lysis. In addition, these pumps allowed the cell to store energy in the form of ion gradients across the membrane. Thus, even in the earliest stages, the evolution of ion transport systems coincided with the development of mechanisms which catalyzes the energy transformations. It is postulated that an "ATP"-driven proton pump was one of the first ion transport systems. Such a proton pump would extrude hydrogen ions from the cell, establishing both a transmembrane pH gradient (alkaline inside) and a membrane potential (negative inside). This difference in electrochemical potential for protons (the proton-motive force) could then drive a variety of essential membrane functions, such as the active transport of ions and nutrients. A second major advance was the evolution of an ion transport system that converted light energy into a form which could be used by the cell. The modern model for this is the "purple membrane" of Halobacterium halobium, which catalyzes the extrusion of protons after the capture of light. The protonmotive force generated by such a light-driven proton pump could then power net synthesis of ATP by a reversal of the ATP-driven proton pump. A third important evolutionary step associated with ion transport was the development of a system to harness energy released by biological oxidations. Again, the solution of this problem was to conserve energy as a protonmotive force by coupling the activity of a respiratory chain to the extrusion of protons. Finally, with the development of animal cells a more careful regulation of internal and external pH was required. Thus, an ATP-driven Na+-K+ pump replaced the proton-translocating ATPase as the major ion pump found in plasma membranes.     

On the mechanisms of sodium ion transport by the irrigated gills of rainbow trout (Salmo gairdneri)

Sodium uptake by rainbow trout gills has been investigated with a small-volume system enabling rapid, successive flux measurements in different solutions. Sodium influx obeys a Michaelis-Menten type relation, with a K_m of 0.46 mM, and uptake proceeds unimpaired in the absence of penetrating counter-ions. This suggests a coupled cation exchange. Ammonia output is about the same as the Na⁺ influx when external [Na⁺] is 1 mM, but at higher or lower Na⁺ influxes, the correlation does not hold. A progressive downward shift in the pH of the irrigating medium as Na⁺ influx increases indicates that the exchanging cation is hydrogen. In support of this, acetazolamide, which inhibits Na⁺ uptake, also prevents the downward pH shift. The potential across the gill is about 10 mv, body fluids positive, in NaCl solutions up to 10 mM, and is little affected by changes in Na⁺ concentration below that. Finally, evidence for locating the rate-limiting step at the outer membrane of the epithelium is presented.     

Barium inhibition of sodium ion transport in toad bladder

The effect of Ba²⁺ on Na⁺ transport and electrical characteristics of toad bladder was determined from change produced in short circuit current (I_sc, epithelial, apical and basal-lateral potentials (ψ_t, ψ_a, ψ_b), epithelial and membrane resistances (R_t, R_a, R_b) and shunt resistance (R_s). Mucosal Ba²⁺ had no effect. Serosal Ba²⁺ reduced I_sc, ψ_t, ψ_a, and ψ_b, but had no effect on R_t, R_a, R_b and R_s. Minimal effective Ba²⁺ concentration was 5 · 10^?5 M. The phenomenon was reversed by Ba²⁺ removal, but not by 86 mM serosal K⁺. Ba²⁺ inhibition of I_sc did not impair the response to vasopressin which was quantitatively the same as controls. ψ_a with Ba²⁺ equalled ψ_b. After Ba²⁺ inhibition, ouabain produced no further decrease in ψ_t and I_sc. Ba²⁺ exposure after ouabain did not decrease ψ_t and I_sc. The results suggest that Ba²⁺ inhibits the basal-lateral electrogenic Na⁺ pump.     

cAMP and sodium transport in the freshwater crayfish, Cherax destructor.

Crayfish in which sodium absorption was maximally stimulated had elevated levels of both cAMP and Na(+)-K(+)-ATPase activity in gill tissue. The concentration of cAMP and activity of Na(+)-K(+)-ATPase in gill tissue were monitored following transfer of crayfish from water containing 125 mmol x l(-1) Na to Na-free media. Both parameters were significantly elevated within 10 min of transfer to Na-free media and [cAMP] peaked between 1 and 2 h before falling transiently to the control level at 3 h. A second peak of [cAMP] and a further rise in Na(+)-K(+)-ATPase activity were evident 6 h after transfer and elevated levels were then maintained. The pattern observed was consistent with the existence of two separate mechanisms for the control of sodium absorption both of which stimulated the activity of Na(+)-K(+)-ATPase via elevation of the intracellular concentration of cAMP. The initial response was very rapid (<10 min) but of brief duration (1-2 h) and this mechanism appeared to be sensitive to changes in external ion levels. The second mechanism exhibited a much longer response time (3-6 h) and duration and was likely to be sensitive to changes in internal ion concentrations.     

The effects of alterations in the external sodium concentration on human leucocyte sodium and potassium transport in vitro

Human leucocytes incubated in tissue culture fluid of low-sodium concentration (2 mM; iso-osmolarity maintained with choline chloride) reached a new equlibrium within 1 hour and lost approximately 25% of intracellular potassium and 70% of intracellular sodium. The rate constant for ouabainsensitive sodium efflux fell by more than 50% and the ouabain-insensitive rate constant increased nearly threefold in the low-sodium medium. Total sodium efflux fell in proportion to internal sodium whereas ouabain-insensitive sodium efflux remained unchanged. A reduction in external sodium from 140 to 2 mM was associated with a 75% fall in sodium influx. In the low-sodium medium ouabainsensitive potassium influx exceeded ouabain-sensitive sodium efflux and no ouabain-sensitive potassium efflux could be demonstrated. Ouabain-insensitive potassium influx and that portion of potassium efflux which is dependent on external potassium fell in parallel in low-sodium cells, suggesting reduced activity of a ouabain-insensitive K:K exchange system.     

Benzodiazepines stimulate sodium ion transport in frog skin epithelium

Benzodiazepine binding sites are present in a variety of non-neuronal tissues including the kidney where they are localized to distal nephron segments. It is postulated that renal binding sites are involved in modulating ion transport. This study examined the effects of two benzodiazepines on sodium transport in frog skin epithelium, a model system for sodium transport in renal collecting duct. Treatment of short-circuited frog skin with diazepam (a non-selective benzodiazepine agonist) stimulated amiloride-sensitive short-circuit current, reflecting stimulation of active sodium transport. The diazepam response was equally effective with either serosal or mucosal application of the drug. Maximal stimulation of the current (42 +/- 8%) was achieved with 10 microM diazepam (serosal). Short-circuit current was similarly augmented by serosal or mucosal addition of Ro5-4864, a benzodiazepine agonist with selective activity at peripheral (non-neuronal) receptors. The natriferic response to diazepam was additive to that of vasopressin or cyclic AMP suggesting that the mode of action of benzodiazepines is probably distinct from the cyclic AMP pathway. Thus, frog skin appears to be a useful model to examine the epithelial effects of benzodiazepines. Whether stimulation of sodium transport, however, involves peripheral-type benzodiazepine receptors in this tissue requires further studies.     

Light-driven primary sodium ion transport in halobacterium halobium membranes

Light-induced sodium extrusion from H halobium cell envelope vesicles proceeds largely through an uncoupler-sensitive pathway involving bacteriorhodopsin and a proton/sodium antiporter. Vesicles from bacteriorhodopsin-negative strains also extrude sodium ions during illumination, but this transport is not sensitive to uncouplers and has been proposed to involve a light-energized primary sodium pump. Proton uptake in such vesicles is passive, and under steady-state illumination the large electrical potential (negative inside) is just balanced by a pH difference (acid inside), so that the protonmotive force is near zero. Action spectra indicated that this effect of illumination is attributable to a pigment absorbing near 585 nm (of 568 for bacteriorhodopsin). Bleaching of the vesicles by prolonged illumination with hydroxylamine results in inactivation of the transport; retinal addition causes partial return of the activity. Retinal addition also causes the appearance of an absorption peak at 588 nm, while the absorption of free retinal decreases. The 588 nm pigment is present in very small quantities (0.13 nmole/mg protein), and behaves differently from bacteriorhodopsin in a number of respects. Vesicles can be prepared from bacteriorhodopsin-containing H halobium strains in which primary transport for both protons and sodium can be observed. Both pumps appear to cause the outward transport of the cations. The observations indicate the existence of a second retinal protein, in addition to bacteriorhodopsin, in H halobium, which is associated with primary sodium translocation. The initial proton uptake normally observed during illumination of whole H halobium cells may therefore be a passive flux in response to the primary sodium extrusion.     

Effect of hibernation on sodium and chloride ion transport in isolated frog skin

The aim of the study was to evaluate the effect of hibernation on electrophysiological parameters of isolated frog skin under control incubation (Ringer solution) and after inhibition of Na+ and CI- transepithelial transport by application of amiloride and bumetanide. The transepithelial electrical potential difference (PD in mV) was measured before and after mechanical stimulation of isolated frog skin. The tissues were mounted in a modified Ussing chamber. The results revealed a reduced PD of frog skin during hibernation. In February, as compared with November, PD of frog skin incubated in Ringer solution decreased by about 50%. Hibernation also affected hyperpolarization (dPD) of frog skin after mechanical stimulation. In November and December, dPD was about 50% and 30% lower, respectively, compared with the subsequent two months of the experiment. The incubation of frog skin with amiloride, a sodium ion channel blocker, resulted in reduced values of all measured electrophysiological parameters irrespective of the phase of hibernation. After application of chloride ion transport inhibitor (bumetanide), the PD in November and December decreased compared with the control incubation by about 80% and 75%, while in January and February by about 40% and 25%, respectively. In January and February dPD increased by four times and three times as compared with November and December. Hibernation reduces net ion flow in isolated frog skin. During the initial period of hibernation the sensitivity of the skin to mechanical stimulation also decreases. Towards the end of hibernation, on the other hand, excitation of mechanosensitive ion channels takes place.     

A peptide-gated ion channel from the freshwater polyp Hydra

Chemical transmitters are either low molecular weight molecules or neuropeptides. As a general rule, neuropeptides activate only slow metabotropic receptors. To date, only one exception to this rule is known, the FMRFamide-activated Na(+) channel (FaNaC) from snails. Until now FaNaC has been regarded as a curiosity, and it was not known whether peptide-gated ionotropic receptors are also present in other animal groups. Nervous systems first evolved in cnidarians, which extensively use neuropeptides. Here we report cloning from the freshwater cnidarian Hydra of a novel ion channel (Hydra sodium channel, HyNaC) that is directly gated by the neuropeptides Hydra-RFamides I and II and is related to FaNaC. The cells expressing HyNaC localize to the base of the tentacles, adjacent to the neurons producing the Hydra-RFamides, suggesting that the peptides are the natural ligands for this channel. Our results suggest that neuropeptides were already used for fast transmission in ancient nervous systems.     

Effects of external saccharides on cell wall properties and ion transport inHydrodictyon reticulatum

Various saccharides, when present at osmotically insignificant concentrations in growth media, were tested as to their effects on the cell walls of the green algaHydrodictyon reticulatum, manifesting themselves in differences in cell water and ion contents. Bothd-xylose andd-mannose reduce the cell water content andd-galactose does occasionally the same but onlyd-xylose reduces significantly the intracellular sodium concentration, presumably by forming steric hindrances at the outlets of the sodium pumps at the outer surface of the cell membrane. No significant effects of eitherl-arabinose ord-arabinose on the cell water and ion contents were found.     

Effect of oleamide on water and sodium ion transport in osmoregulatory organs of vertebrates

In the frog Rana temporaria L., oleamide solution (10 μmole/L) applied to the isolated basal surface of the skin augmented the short-circuit current (SCC) from 59.8 ± 2.5 to 78.2 ± 1.4 μA/cm². When applied to the serous membrane of the urinary bladder, oleamide (1 μmole/L) induced more than a 30-fold increase in osmotic water permeability. The addition of argininevasotocin against the background of oleamide further increased SCC across the skin and osmotic water permeability in the bladder. In Wistar rats, intraperitoneal injection of oleamide (0.1 μmole/L per 100 g of body weight) to non-anesthetized animals after water load reduced diuresis by 22% and increased solute-free water reabsorption and urinary sodium excretion by 31% and 55%, respectively, but did not affect urinary potassium excretion. These findings provide evidence of the similarity between the effects of oleamide and nonapeptide neurohypophyseal hormones on water and ion transport in epithelial cells of osmoregulatory organs in vertebrates.     

Molecular mechanisms of ANP inhibition of renal sodium transport.

ANP, a hormone secreted by the atria of mammalian hearts in response to volume expansion, increases urinary sodium excretion in part by inhibiting sodium reabsorption across the inner medullary collecting duct. A number of nephron segments may contribute to the ANP-induced natriuresis; however, this review will focus on the cellular mechanisms of ANP inhibition of electrogenic sodium reabsorption by the inner medullary collecting duct. Patch-clamp studies conducted on rat inner medullary collecting duct cells in primary culture revealed that ANP, via its second messenger cGMP, inhibits electrogenic sodium reabsorption by reducing the open probability of a cation channel located in the apical membrane. Cyclic GMP inhibits the cation channel and thereby sodium reabsorption by two mechanisms. First, cGMP inhibits the channel by a phosphorylation-independent mechanism, by binding either to an allosteric modifier site on the channel or to a regulatory subunit. Second, cGMP inhibits the channel by activating cGMP-dependent protein kinase, which by a sequential pathway involving the GTP-binding protein, Gi, inhibits the channel. These cGMP-dependent mechanisms inhibiting sodium reabsorption across the inner medullary collecting duct account for a substantial component of the natriuresis following a rise in ANP levels.     

Diphenylamine-2-carboxylate stimulates sodium ion transport in frog skin epithelium

1. Diphenylamine-2-carboxylate (DPC), added to the mucosal side of the frog skin, increased reversibly the short-circuit current (I0), even in SO2-(4) Ringer. Amiloride blocked this effect. 2. The maximal stimulation was 140% of the control value and the EC50 was 0.26 mM DPC. 3. The stimulatory effect of DPC was additive to that of oxytocin. 4. The dose-response curves for amiloride determined in the absence and in the presence of 1 mM DPC showed an IC50 of 1.0 microM and 0.8 microM amiloride, respectively. 5. Thus DPC, a blocker of Cl- channels in various Cl-transporting epithelia, exerts a stimulatory effect on the amiloride-sensitive Na+ transport in frog skin.