Inhibition of Amino Acid Transport in Rabbit Intestine by p-Chloromercuriphenyl Sulfonic Acid

Influx of phenylalanine across the brush border of rabbit intestine is markedly reduced by treatment with 5 mM p-chloromercuriphenyl sulfonate (PCMBS). The effect is rapidly and completely reversed by dithiothreitol. Phenylalanine influx into PCMBS-treated tissue can be competitively inhibited by other neutral amino acids and follows saturation kinetics. PCMBS causes an increase in the apparent Michaelis constant from the value observed in control tissue but does not alter the maximal influx significantly. Treatment of the tissue with PCMBS leads to a significant reduction in the Na-sensitivity of the transport, and a number of results indicate that the major effect of the reagent is to cause a marked reduction in the affinity of the transport system for Na. The transport system can be partially protected against reaction with PCMBS by phenylalanine and tryptophan but not by methionine or norleucine. The results suggest that PCMBS reacts with a sulfhydryl group in the region of the transport site and may alter conformational changes associated with the binding of substrates.     

Voltage dependence of Na channel blockage by amiloride: Relaxation effects in admittance spectra

Summary Amiloride, present in the mucosal solution, causes the appearance of a distinct additional dispersion in the admittance spectrum of the apical membrane of toad urinary bladder. The parameters of this dispersion (characteristic frequency. amplitude) change with amiloride concentration and with membrane voltage. They allow the calculation of the overall rate constants for Na channel blockage by the positively charged form of amiloride. and the voltage dependence of these rate constants. The on-rate of blockage increases and the off-rate decreases when the membrane surface to which cationic amiloride has access, is made more positive. This result is suggestive of a blocking model where the cationic amidino group of amiloride, depending on its charge, senses 10 to 13% of the membrane voltage while invading the channel entrance by a single-step process, and rests at an electrical distance corresponding to 24 to 30% of membrane voltage while occupying the blocking position.     

Na+-H+ exchange and Na+ entry across the apical membrane of Necturus gallbladder

The role of Na+-H+ exchange in Na+ transport across the apical membrane was evaluated in Necturus gallbladder epithelium by means of intracellular Na+ activity (aNai) and 22Na+ uptake measurements. Under control conditions, complete replacement of Na+ in the mucosal solution with tetramethylammonium reduced aNai from 14.0 to 6.9 mM in 2 min (P less than 0.001). Mucosal addition of the Na+-H+ exchange inhibitor amiloride (10(-3) M) reduced aNai from 15.0 to 13.3 mM (P less than 0.001), whereas bumetanide (10(-5) and 10(-4) M) had no effect. Na+ influx across the apical membrane was studied by treating the tissues with ouabain, bathing them in Na-free solutions, and suddenly replacing the mucosal solution with an Na-containing solution. When the mucosal solution was replaced with Na-Ringer's, aNai increased at approximately 11 mM/min. This increase was inhibited by 54% by amiloride (10(-3) M, P less than 0.001) and was unaffected by bumetanide (10(-5) M). Amiloride-inhibitable Na+ fluxes across the apical membrane were also induced by the imposition of pH gradients. Na+ influx was also examined in tissues that had not been treated with ouabain. Under control conditions, 22Na+ influx from the mucosal solution into the epithelium was linear over the first 60 s and was inhibited by 40% by amiloride (10(-3) M, P less than 0.001) and by 19% by bumetanide (10(-5) M, P less than 0.025). We conclude that Na+-H+ exchange is a major pathway for Na+ entry in Necturus gallbladder, which accounts for at least half of apical Na+ influx both under transporting conditions and during exposure to ouabain. Bumetanide-inhibitable Na+ entry mechanisms may account for only a smaller fraction of Na+ influx under transporting conditions, and cannot explain influx in ouabain-treated tissues. These results support the hypothesis that NaCl entry results primarily from the operation of parallel Na+-H+ and Cl--HCO-3 exchangers, and not from a bumetanide-inhibitable NaCl cotransporter.     

Effect of mercurial compounds on net water transport and intramembrane particle aggregates in ADH-treated frog urinary bladder

Summary It has been suggested that during the oxytocin-induced hydrosmotic response, water crosses the luminal membrane of urinary bladder epithelium cells through membranespanning proteins. Although specific inhibitors of osmotic water transport have not been found, certain sulfhydryl reagents such as mercurial compounds may help to identify the proteins involved in this permeation process. We tested the effects ofp-chloromercuribenzene sulfonate (PCMBS) and of fluoresceinmercuric acetate (FMA) on the net water flux, the microtubule and microfilament structures of the frog urinary bladder, and the distribution of intramembrane particle aggregates in the luminal membrane.We observed that: (i) 5mm PCMBS at pH 5 and 0.5mm FMA at pH 8 added to the mucosal bath at the maximum of the response to oxytocin partially inhibited the net water flux. Inhibition then increased progressively when the preparation was repeatedly or continuously stimulated, until it reached a maximal inhibition at 120 min. This inhibition was not reversed even when cystein was added in the mucosal bath. PCMBS and FMA effects were also observed when cyclic AMP (3,5 cyclic adenosine monophosphate) was used to increase water permeability. (ii) PCMBS mucosal pretreatment did not modify the basal water flux but potentiated the inhibitory effect of PCMBS or FMA on the hydrosmotic response to oxytocin. (iii) Microtubule and microfilament network, visualized in target cells by immunofluorescence, was not affected by PCMBS. (iv) The maximal PCMBS or FMA inhibition was not associated with a reduction of aggregate surface area in the apical membrane.The persistence of the intramembrane particle aggregates associated with the oxytocin-induced hydrosmotic response during the net water flux inhibition by PCMBS, suggests that the PCMBS effect occurs possibly at the level of sulfhydryl groups of the water channel itself.     

Mercurial perturbation of brush border membrane permeability in rabbit ileum

The sulfhydryl reagents Hg++ and p-chloromercuribenzene sulfonate (PCMBS) at millimolar concentrations reduced the mucosal entry of sugars and amino acids to 80-90% of control levels within several minutes. Based on 50% levels of inhibition, Hg++ proved to be 20 and 10 times as potent as PCMBS in blocking sugar and amino acid transport, respectively; both systems were equally sensitive to Hg++. Concomitant measurements of 203Hg-PCMBS demonstrated a progressive tissue uptake, which, unlike inhibition, did not saturate with increasing times of exposure, thus suggesting appreciable epithelial entry with prolonged exposures (less than 30 min at 1 mM). At similar dose levels, no significant change in mucosal Na+ entry was detected. Inhibition was not reversed by 30-min washes in cholinesalt solutions; however, 10-min exposures to dithiothreitol [10 mM] reversed Hg++ and PCMBS inhibition by 40 and 100%, respectively. Alanine and galactose influx kinetics measured at concentrations of 0-100 mM exhibited a linear or diffusional entry component in addition to the usual saturable component for both control and Hg++-treated ileum. The presence of a diffusional term in the flux equation resulted in two sets of parameters giving nearly equal fits to these measurements. It was shown that this ambiguity could be resolved by determining the change in diffusional entry with Hg++ treatment. A 20-min exposure to 0.5 mM Hg++ caused an increase from 0.050 and 0.045 to 0.064 and 0.070 cm/hr in the coefficient of diffusional entry for alanine and galactose, respectively. On the basis of this increase, it is argued that Hg++ causes a decrease in Jmax and little change in Km for both transport mechanisms. This analysis has a general bearing on kinetic measurements of transport in which passive fluxes are comparable to those mediated by specific pathways. The alanine results are consistent with bimolecular reactions between mercurial and two membrane inhibitory sites, each producing approximately 40% reduction in membrane translocation rate. The estimated reaction rate constants were 5.0 and 0.4 mM min.     

Cyclic AMP inhibits Cl-/HCO3- exchange at the apical membrane of Necturus gallbladder epithelium

Intracellular microelectrode techniques were employed to study the effect of cyclic AMP on apical membrane Cl-/HCO3- exchange and electrodiffusive HCO3- transport in Necturus gallbladder epithelium. Intracellular cAMP levels were raised by addition of either the phosphodiesterase inhibitor theophylline (3 X 10(-3) M) or the adenylate cyclase activator forskolin (10(-5) M) to the serosal bathing solution. Measurements of pH in a poorly buffered control mucosal solution upon stopping superfusion show acidification, owing to secretion of both H+ and HCO3-. When the same experiment is performed after addition of amiloride or removal of Na+ from the mucosal bathing medium, alkalinization is observed since H+ transport is either inhibited or reversed, whereas HCO3- secretion persists. The changes in pH in both amiloride or Na-free medium were significantly decreased in theophylline-treated tissues. Theophylline had no effect on the initial rates of fall of intracellular Cl- activity (aCli) upon reducing mucosal solution [Cl-] to either 10 or 0 mM, although membrane voltage and resistance measurements were consistent with stimulation of apical membrane electrodiffusive Cl- permeability. Estimates of the conductive flux, obtained by either reducing simultaneously mucosal [Cl-] and [HCO3-] or lowering [Cl-] alone in the presence of a blocker of anion exchange (diphenylamine-2-carboxylate), indicate that elevation of intracellular cAMP inhibited the anion exchanger by approximately 50%. Measurements of net Cl- uptake upon increasing mucosal Cl- from nominally zero to levels ranging from 2.5 to 100 mM suggest that the mechanism of inhibition is a decrease in Vmax. Consistent with these results, the rate of intracellular alkalinization upon reducing external Cl- was also inhibited significantly by theophylline. Reducing mucosal solution [HCO3-] from 10 to 1 mM under control conditions caused intracellular acidification and an increase in aCli. Theophylline inhibited both changes, by 62 and 32%, respectively. These data indicate that elevation of intracellular cAMP inhibits apical membrane anion (Cl-/HCO3-) exchange. Studies of the effects of rapid changes in mucosal [HCO3-] on membrane voltages and the apparent ratio of membrane resistances, both in the presence and in the absence of theophylline, with or without Cl- in the mucosal solution, do not support the hypothesis that cAMP produces a sizable increase in apical membrane electrodiffusive HCO3- permeability.     

Effects of SNP, ouabain, and amiloride on electrical potential profile of isolated sheep pleura.

The fluid and solute transport properties of pleural tissue were studied by using specimens of intact visceral and parietal pleura from adult sheep lungs. The samples were transferred to the laboratory in a Krebs-Ringer solution at 4 degrees C within 1 h from the death of the animal. The pleura was then mounted as a planar sheet in a Ussing-type chamber. The results that are presented in this study are the means of six different experiments. The spontaneous potential difference and the inhibitory effects of sodium nitroprusside (SNP), ouabain, and amiloride on transepithelial electrical resistance (R(TE)) were measured. The spontaneous potential difference across parietal pleura was 0.5 +/- 0.1 mV, whereas that across visceral pleura was 0.4 +/- 0.1 mV. R(TE) of both pleura was very low: 22.02 +/- 4.1 Omega. cm2 for visceral pleura and 22.02 +/- 3.5 Omega. cm2 for parietal pleura. There was an increase in the R(TE) when SNP was added to the serosal bathing solution of parietal pleura and to the serosal or mucosal bathing solution in visceral pleura. The same was observed when ouabain was added to the mucosal surface of visceral pleura and to either the mucosal or serosal surface of parietal pleura. Furthermore, there was an increase in R(TE) when amiloride was added to the serosal bathing solution of parietal pleura. Consequently, the sheep pleura appears to play a role in the fluid and solute transport between the pleural capillaries and the pleural space. There results suggest that there is a Na+ and K+ transport across both the visceral and parietal pleura.     

Independence of apical membrane Na+ and Cl- entry in Necturus gallbladder epithelium

Transepithelial fluid transport (Jv) and intracellular Na+ and Cl- activities (aNai, aCli) were measured in isolated Necturus gallbladders to establish the contribution of different proposed apical membrane entry mechanisms to transepithelial salt transport. In 10 mM HCO3- Ringer's, Jv was 13.5 +/- 1.1 microliter X cm-2 X h-1, and was significantly reduced by a low bicarbonate medium and by addition of amiloride (10(-3)M) or SITS (0.5 X 10(-3)M) to the mucosal bathing solution. Bumetanide (10(-5)M) was ineffective. Bilateral Na+ removal abolished Jv. The hypothesis of NaCl cotransport was rejected on the basis of the following results, all obtained during mucosal bathing solution changes: during Na+ removal, aNai fell 4.3 times faster than aCli; during Cl- removal, aCli fell 7.5 times faster than aNai; amiloride (10(-3) M) reduced aNai at a rate of 2.4 +/- 0.3 mM/min, whereas aCli was not changed; bumetanide (10(-5) M) had no significant effects on Jv or aCli. The hypothesis of Na-K-Cl cotransport was rejected for the same reasons; in addition, K+ removal from the mucosal bathing solution (with concomitant Ba2+ addition) did not alter aNai or aCli. The average rate of NaCl entry under normal transporting conditions, estimated from Jv, assuming that the transported fluid is an isosmotic NaCl solution, was 22.5 nmol X cm-2 X min-1. Upon sudden cessation of NaCl entry, assuming no cell volume changes, aNai and aCli should fall at an average rate of 4.8 mM/min. To compare this rate with the rates of Na+ and Cl- entry by ion exchange, the Na+ or Cl- concentration in the mucosal bathing solution was reduced rapidly to levels such that electroneutral cation or anion exchange, respectively, should cease. The rate of Na+ or Cl- entry before this maneuver was estimated from the initial rate of fall of the respective intracellular ionic activity upon the mucosal solution substitution. aNai and aCli decreased at initial rates of 3.7 +/- 0.4 and 5.9 +/- 0.8 mM/min, respectively. The rate of fall of aNai upon reduction of external [Na] was not affected by amiloride (10(-3) M), and the rate of fall of aCli upon reduction of external [Cl] was unchanged by SITS (0.5 X 10(-3) M), which indicates that net cation or anion exchange was, in fact, abolished by the changes in Na+ and Cl- gradients, respectively. I conclude that double exchange (Na+/H+ and Cl-/HCO-3) is the predominant or sole mechanism of apical membrane NaCl entry in this epithelium.     

Norepinephrine stimulation of sodium transport in Necturus urinary bladder

Norepinephrine alters the transepithelial electrical properties of an open-circuited urinary bladder from the mud puppy, Necturus maculosus. When 10(-5) M norepinephrine is superfused over the serosa of the epithelium, the transepithelial voltage (Vt) and short-circuit current (Isc) increase as the resistance (Rt) decreases. The norepinephrine-mediated changes are reversed by the addition of amiloride (5.10(-5) M) to the mucosal Ringer's solution. The serosal adrenoceptors mediating the Na+ transport are more sensitive to norepinephrine (EC50 = 1.2.10(-6) M) than to epinephrine or isoproterenol. Since the Isc is blocked selectively by the antagonist, phenoxybenzamine, stimulation of active transepithelial Na(+)-flux by catecholamines is mediated by an alpha-adrenoceptor. The apical cell membrane voltage (Va) and fractional resistance (fRa) were recorded using conventional KCl-filled microelectrodes. Untreated tissues have Va close to 0 mV while the basolateral membrane voltage (Vb) is between -85 and -95 mV. About 90% of Rt is apical cell membrane resistance (fRa). When amiloride inhibits sodium transport, Va becomes negative, Vb hyperpolarizes slightly and fRa increases to 97%. On the other hand, if the bladders are treated with norepinephrine, fRa decreases to 79% as Va becomes positive and Vb depolarizes. When Rt changes, the resistance of the paracellular pathway (Rp) is unaltered. Changes in the electrical properties of the tissue appear to be mediated primarily by alterations in Ra. Since the Necturus bladder does not respond to antidiuretic hormone, this study implies that biogenic amines regulate Na+ transport in the epithelium.     

Effects of diphenylamine-2-carboxylate on sodium and chloride transport across bovine tracheal epithelium: studies in monolayers and in the native tissue

1. The short-circuit current (I0) across monolayers of bovine tracheal epithelial cells is the sum of Na+ absorption and Cl- secretion. 2. Diphenylamine-2-carboxylate (DPC), added to the mucosal side of the native tissue or monolayers induced a rapid, dose-dependent and fully reversible reduction in I0, which reached zero with 3 mM DPC. 3. The blocking effect of DPC was examined during incubation (1) in standard, (2) in Cl(-)-free and (3) in Na+-free solution. Dose response curves revealed that the IC50 was not altered following ion substitution: it was approximately 0.7 mM DPC. 4. Thus, in bovine tracheal epithelium, DPC was an effective blocking agent of both Na+ and Cl- transport.     

Mode of action of amiloride in toad urinary bladder

Summary The effect of amiloride on the sensitivity to Na of the mucosal border of toad urinary bladder was investigated by recording Na concentration-dependent transepithelial potential difference (V _t ) and the intracellular potential. When mucosal Na concentration was normal, amiloride added to the mucosal solution at 10^–4 m markedly reduced the mucosal membrane potential (V _m ) and altered the potential profile from a two-step type to a well type. Similar changes were observed when Na was totally eliminated from the mucosal medium. The serosal membrane potential was insensitive to amiloride and elimination of mucosal Na. In the absence of amiloride, theV _t could be described by the Goldman-Hodgkin-Katz equation in the range of mucosal Na concentration from 0 to 16mm, and amiloride extended this concentration range. By using the Goldman-Hodgkin-Katz equation, Na permeability was calculated from the data ofV _t 's obtained in the allowed ranges of Na concentration and compared before and after the addition of amiloride. The results show that Na permeability decreases to 1/600 of control when the maximum dose of amiloride (10^–4 m) is applied. The relationship between Na permeability and amiloride concentration is well explained on the basis of assumptions that amiloride binds to the Na site of the mucosal border in one-to-one fashion and in a competitive manner with Na and that Na permeability reduces in proportion to increase in number of the sites bound with amiloride.     

Localization of Erythrocyte Membrane Sulfhydryl Groups Essential for Glucose Transport

The reactions of three organic mercurial compounds, chlormerodrin, parachloromercuribenzoate (PCMB), and parachloromercuribenzenesulfonate (PCMBS) with intact red blood cells, hemolyzed red cells, hemoglobin solutions, and hemoglobin-free ghosts have been characterized. Both PCMB and PCMBS react with only 2 to 3 sulfhydryl groups per mole of hemoglobin in solution, whereas chlormerodrin reacts with 6 to 7. In hemoglobin-free ghosts, however, all three reagents react with a similar number of sulfhydryl groups, approximately 4 x 10^-17 moles per cell, or about 25 per cent of the total stromal sulfhydryl groups, which react with inorganic mercuric chloride. In the intact cell the membrane imposes a diffusion barrier; chlormerodrin and PCMB penetrate slowly, whereas PCMBS does not. Kinetic studies of chlormerodrin binding to intact cells reveal that the majority of stromal sulfhydryl groups is located inside the diffusion barrier, with only 1 to 1.5 per cent (or 1 to 1,400,000 sites per cell) located outside of this barrier. Reaction of PCMBS with intact cells is limited to this small fraction on the outer membrane surface. All three reagents are capable of inhibiting glucose transport in the red cell. With chlormerodrin and PCMBS it was demonstrated that the inhibition results from interactions with the sulfhydryl groups located on the outer surface of the membrane.     

Chemical Modification of Membranes : 1. Effects of sulfhydryl and amino reactive reagents on anion and cation permeability of the human red blood cell

Four different amino-reactive reagents, 4-acetamido-4'-isothiocyano-stilbene-2,2'-disulfonic acid (SITS),¹ 1-fluoro-2,4-dinitrobenzene (FDNB), 2,4,6-trinitrobenzene sulfonic acid (TNBS), and 2-methoxy-5-nitrotropone (MNT) decrease the anion permeability of the human red blood cell, as measured by sulfate fluxes, whereas the sulfhydryl agent, parachloromercuriphenyl sulfonic acid (PCMBS), does not. In contrast, PCMBS increases the cation permeability as measured by K⁺ leakage, whereas SITS does not. Of the other agents, FDNB increases the cation permeability to the same extent as PCMBS but MNT and TNBS produce smaller increases. PCMBS does not protect against FDNB as it does against other sulfhydryl agents (X-irradiation) and the FDNB effect on cations is attributed to amino groups. Studies of the binding of SITS indicate that it does not penetrate into the membrane and its failure to influence cation permeability is attributed to its inability to reach an internal population of amino groups. It is concluded that two ion permeability barriers, both involving proteins, are present in the red blood cell. The more superficial barrier contains amino groups and controls anion flow; the more internal barrier contains sulfhydryl and amino groups and controls cation flow. The amino groups contribute to the control of permeability by virtue of their positive charges, but the role of sulfhydryl groups is not clear. Only a small fraction of the membrane protein amino and sulfhydryl is involved in the barriers.     

Anthracene-9-carboxylic acid inhibits an apical membrane,chloride conductance in canine tracheal epithelium

Summary Canine tracheal epithelium secretes Cl from the submucosal to the mucosal surface via an electrogenic transport process that appears to apply to a wide variety of secretory epithelia. Cl exit across the apical membrane is thought to be a passive, electrically conductive process. To examine the cellular mechanism of Cl secretion we studied the effect of anthracene-9-carboxylic acid (9-AC), an agent known to inhibit the Cl conductance of muscle membrane. When added to the mucosal solution, 9-AC rapidly and reversibly decreases short-circuit current and transepithelial conductance, reflecting a reduction in electrogenic Cl secretion. The inhibition is concentration-dependent and 9-AC does not appear to compete with Cl for the transport process. The decrease in current and conductance results from a decrease in the net and both unidirectional transepithelial Cl fluxes without substantial alterations of Na fluxes. Furthermore, 9-AC specifically inhibits a Cl conductance: tissues bathed in Cl-free solutions showed no response to 9-AC. Likewise, when the rate of secretion and Cl conductance were minimized with indomethacin, addition of 9-AC did not alter transepithelial conductance. In contrast, neither removal of Na from the media nor blockade of the apical Na conductance with amiloride prevented a 9-AC-induced decrease in transepithelial conductance. We also found that the effect of 9-AC is independent of transepithelial transport: 9-AC decreases transepithelial conductance despite inhibition of Cl secretion with ouabain or furosemide. Intracellular electrophysiologic techniques were used to localize the effect of 9-AC to a reduction of the electrical conductance of the apical cell membrane: 9-AC hyperpolarizes the electrical potential difference across the apical membrane and decreases its relative conductance. 9-AC also prevents the characteristic changes in the cellular electrical potential profile, transepithelial conductance, and the ratio of membrane conductances produced by a reduction in mucosal bathing solution Cl concentration. These results indicate that 9-AC inhibits Cl secretion in tracheal epithelium by blocking an electrically conductive Cl exit step in the apical cell membrane. Thus, they support a cellular model of Cl secretion in which Cl leaves the cell across a Cl permeable apical membrane driven by its electrochemical gradient.     

Na+-H+ exchange at the apical membrane of Necturus gallbladder. Extracellular and intracellular pH studies

The mechanism of luminal solution acidification was studied in Necturus gallbladder by measurement of mucosal solution and intracellular pH with glass electrodes. When the gallbladder was bathed by a Na-Ringer's solution it acidified the luminal side by a Na+-dependent, amiloride- inhibitable process. In the presence of ouabain, acidification was reduced but could be stimulated to a rate greater than that under control conditions by the imposition of an inwardly directed Na+ gradient. These results suggest that luminal acidification results from Na+-H+ exchange at the apical membrane and not by diffusion of metabolic CO2. Li+ can substitute for Na+ but K+, Rb+, Cs+, and tetramethylammonium (TMA+) cannot. The maximal rate of exchange was about five times greater for Na+ than for Li+. Intracellular pH (pHi) was measured with recessed-tip glass microelectrodes; with the tissue bathed in Na-Ringer's solution (pH 7.75), pHi was 7.51 +/- 0.04. After inhibition of Na+-H+ exchange by mucosal perfusion with amiloride (1 mM) or by complete Na+ replacement with TMA+, phi fell reversibly by 0.15 and 0.22 pH units, respectively. These results support the conclusion that Na+-H+ exchange at the apical membrane is the mechanism of luminal acidification and is involved in the maintenance of steady state pHi.     

Effect of diuretics on intestinal transport of electrolytes, glucose, and amino acid.

The jejunal mucosal membrane of albino mice was used to study the electrical properties and ion transport. The membrane was bathed in Krebs-Ringer solution with or without glucose.When ethacrynic acid (EA), furosemide, or amiloride was added to the bathing fluid of both sides, a transient increase followed by a decrease of both potential difference (PD) and short circuit current (Isc) were observed. In glucose-containing bathing medium, EA inhibited both net Na and Cl flux and residual flux; however, EA had little effect on both Na and Cl flux in glucose-free bathing medium. Studies using everted intestinal sac technique showed that EA inhibited both glucose and L-tyrosine across the mucosal membrane against concentration gradients. Furosemide and amiloride were less potent than EA in inhibiting the Na and Cl flux when the bathing solution contained glucose. But these two compounds had no effect on glucose and L-tyrosine transport across the intestinal mucosa. Furthermore, they did inhibit Cl flux even in the condition of glucose-free bathing medium. It is postulated that all three diuretics act on the brush-border membrane of the intestine. EA probably inhibits the Na-glucose cotransporting system; furosemide and amiloride inhibit the simple diffusion process of Na entry of Cl exit by decreasing the conductance of the membrane.     

Cation selectivity of the apical membrane of the turtle colon: sodium entry in the presence of lithium

Exposure of the apical surface of the isolated turtle colon to Li produced a marked transient in short-circuit current (ISC) and total tissue conductance (GT) which was abolished by amiloride but was unaffected by ouabain or by removing Na or Cl from the mucosal bathing solution. Despite marked changes in Isc, Na uptake across the apical membrane was a linear function of time during exposure to Li-containing solutions, and except at very high Li concentrations, the initial rate of Na uptake, JiNa, was identical to its pre-Li value. In the presence of Li, however, JiNa was significantly less than the total Isc. The apparent "transference number" for Na in the apical membranes was a function of the Li:Na concentration ratio in the mucosal bathing solution. These results suggest that Li can carry substantial amounts of current through amiloride-sensitive channels in the apical membrane of the colon without having any effect on the rate coefficient for Na entry. This behavior is not consistent with "competition" of Na and Li for a membrane "carrier" but rather suggests that the Na entry mechanism may be a population of pores or channels through which Na and Li may pass with negligible interaction.     

The effects of amiloride on the labellar taste receptor cells of the fleshfly Boettcherisca peregrina

Amiloride is known to inhibit the taste response of vertebrates to salt by blocking the amiloride-sensitive sodium channel. In this study, we investigated electrophysiologically the effect of amiloride on the taste response of the fleshfly Boettcherisca peregrina. When 0.5 mM amiloride was included in taste solutions, the response of the salt receptor cell (salt response) to sodium chloride (NaCl) was not depressed but those of the sugar receptor cell (sugar responses) to sucrose, glucose, fructose, l-valine (l-Val) and l-phenylalanine (l-Phe) were strongly depressed. An inhibitory effect of amiloride on the concentration-response relationship for both sucrose and l-Phe was clearly revealed, but not at high concentrations of sucrose. After pretreatment of a chemosensory seta with 0.15 mM amiloride for 10 min, the salt response to NaCl was not affected. On the other hand, the sugar responses to sucrose, fructose, l-Val and l-Phe were depressed just after amiloride pretreatment. The sugar response to adenosine 5’-diphosphate (ADP) mixed with 0.5 mM amiloride was not depressed, but the response to ADP alone was depressed after amiloride pretreatment. It was therefore observed that amiloride depressed the responses to all stimulants that react with each of the receptor sites of the sugar receptor cell.     

Electrogenic ion transport in the intestine of the Australian common brushtail possum, <Emphasis Type="Italic">Trichosurus vulpecula</Emphasis>: indications of novel transport patterns in a marsupial

In this study, electrogenic ion transport in the intestine of the Australian common brushtail possum, Trichosurus vulpecula was investigated. In the ileum, a Na(+)-dependent, phloridzin- and amiloride-insensitive short-circuit current ( Isc) was present. Mucosal glucose stimulated a further phloridzin-sensitive, dose-dependent increase in Isc. A Na(+)-dependent, ouabain-sensitive Isc was also present in the caecum and colon. In the proximal and distal colon, amiloride (100 micro mol l(-1), mucosal) inhibited this Isc by 81+/-4% and 65+/-3%, respectively and the Ki for amiloride (approximately 1 micro mol l(-1)) was consistent with the inhibition of a classical epithelial Na(+) channel. In the caecum, 50% of the Isc was inhibited by amiloride (100 micro mol l(-1), mucosal). The amiloride-insensitive Isc in the colon was not due to electrogenic Cl(-) secretion, as serosal bumetanide (100 micro mol l(-1)) had no effect on the Isc. Furthermore, the secretagogues forskolin (10 micro mol l(-1)), carbachol (100 micro mol l(-1)) and dibutyryl-cAMP or dibutyryl-cGMP (100 micro mol l(-1)) did not stimulate electrogenic Cl(-) secretion by the colon. These results indicate that the transport properties of the hindgut of the possum differ significantly from those of eutherian mammals and may be associated with different functions of the hindgut of possums when compared to eutherian mammals.