An investigation of the ionic mechanism of intracellular pH regulation in mouse soleus muscle fibres.

1. Intracellular pH (pH(i)) of surface fibres of the mouse soleus muscle was measured in vitro by recessed-tip pH-sensitive micro-electrodes. pH(i) was displaced in an acid direction by removal of external (NH(4))(2)SO(4) after a short exposure, and the mechanism of recovery from this acidification was investigated.2. Removal of external K caused a very slow acidification (probably due to the decreasing Na gradient) but had no effect on the rate of pH(i) recovery following acidification. This indicates that K(+)-H(+) exchange is not involved in the pH(i) regulating system.3. Short applications of 10(-4)M ouabain had no obvious effect on pH(i) and did not alter the rate of pH(i) recovery following acidification. This suggests that there is no direct connexion between the regulation of pH(i) and the Na pump.4. Reduction of external Ca from 10 to 1 mM caused a transient fall in pH(i), but the rate of pH(i) recovery following acidification was unaffected. This suggests that Ca(2+)-H(+) exchange is not involved in the pH(i) regulating system.5. An 11% reduction in external Na caused a significant slowing of pH(i) recovery following acidification. 90% or complete removal of external Na almost stopped pH(i) recovery. This suggests that Na(+)-H(+) exchange is involved in pH(i) regulation.6. Amiloride (10(-4)M) reversibly reduced the rate of pH(i) recovery to much the same extent as removal of external Na. Its effect was not additive to that of removal of external Na.7. Internal Na ion concentration ([Na(+)](i)), measured using Na(+)-sensitive micro-electrodes, fell on application of (NH(4))(2)SO(4) and increased on its removal. The increase transiently raised [Na(+)](i) above the level recorded before (NH(4))(2)SO(4) application. This overshoot of [Na(+)](i) was almost completely inhibited by amiloride. This is consistent with the involvement of Na(+)-H(+) exchange in the pH(i) regulating system.8. Removal of external CO(2) or application of SITS (10(-4)M) caused some slowing of the rate of pH(i) recovery following acidification by removal of (NH(4))(2)SO(4). The effect of SITS was additive to that of Na-free Ringer or amiloride. These results suggest that Cl(-)-HCO(3) (-) exchange is also involved in the pH(i) regulating system and that it is a separate mechanism. Under the conditions used, Cl(-)-HCO(3) (-) exchange formed about 20% of the pH(i) regulating system.9. Decreasing the temperature from 37 to 28 degrees C not only caused an increase in pH(i), but also considerably slowed the rate of pH(i) recovery following acidification. We have calculated a Q(10) for Na(+)-H(+) exchange of 1.4 and for Cl(-)-HCO(3) (-) exchange, 6.9.10. We conclude that the pH(i) regulating system is comprised of two separate ionic exchange mechanisms. The major mechanism is Na(+)-H(+) exchange, which is probably driven by the transmembrane Na gradient. The other mechanism is Cl(-)-HCO(3) (-) exchange, which probably requires metabolic energy.     

Electrolyte transport in the mammalian colon: mechanisms and implications for disease.

The colonic epithelium has both absorptive and secretory functions. The transport is characterized by a net absorption of NaCl, short-chain fatty acids (SCFA), and water, allowing extrusion of a feces with very little water and salt content. In addition, the epithelium does secret mucus, bicarbonate, and KCl. Polarized distribution of transport proteins in both luminal and basolateral membranes enables efficient salt transport in both directions, probably even within an individual cell. Meanwhile, most of the participating transport proteins have been identified, and their function has been studied in detail. Absorption of NaCl is a rather steady process that is controlled by steroid hormones regulating the expression of epithelial Na(+) channels (ENaC), the Na(+)-K(+)-ATPase, and additional modulating factors such as the serum- and glucocorticoid-regulated kinase SGK. Acute regulation of absorption may occur by a Na(+) feedback mechanism and the cystic fibrosis transmembrane conductance regulator (CFTR). Cl(-) secretion in the adult colon relies on luminal CFTR, which is a cAMP-regulated Cl(-) channel and a regulator of other transport proteins. As a consequence, mutations in CFTR result in both impaired Cl(-) secretion and enhanced Na(+) absorption in the colon of cystic fibrosis (CF) patients. Ca(2+)- and cAMP-activated basolateral K(+) channels support both secretion and absorption of electrolytes and work in concert with additional regulatory proteins, which determine their functional and pharmacological profile. Knowledge of the mechanisms of electrolyte transport in the colon enables the development of new strategies for the treatment of CF and secretory diarrhea. It will also lead to a better understanding of the pathophysiological events during inflammatory bowel disease and development of colonic carcinoma.     

Transport activities involved in intracellular pH recovery following acid and alkali challenges in rat brain microvascular endothelial cells

Transport activities involved in intracellular pH (pH(i)) recovery after acid or alkali challenge were investigated in cultured rat brain microvascular endothelial cells by monitoring pH(i) using a pH-sensitive dye. Following relatively small acid loads with pH(i) approximately 6.5, [Formula: see text] influx accounted for most of the acid extrusion from the cell with both Cl(-)-independent and Cl(-)-dependent, Na(+)-dependent transporters involved. The Cl(-)-independent component has the same properties as the NBC-like transporter previously shown to account for most of the acid extrusion near the resting pH(i). Following large acid loads with pH(i) < 6.5, most of the acid extrusion was mediated by Na(+)/H(+) exchange, the rate of which was steeply dependent on pH(i). Concanamycin A, an inhibitor of V-type ATPase, had no effect on the rates of acid extrusion. Following an alkali challenge, the major component of the acid loading leading to recovery of pH(i) occurred by [Formula: see text] exchange. This exchange had the same properties as the AE-like transporter previously identified as a major acid loader near resting pH(i). These acid-loading and acid-extruding transport mechanisms together with the Na(+), K(+), ATPase may be sufficient to account not only for pH(i) regulation in brain endothelial cells but also for the net secretion of [Formula: see text] across the blood-brain barrier.     

The role of HCO3(-)-dependent mechanisms in pHi regulation during O2 deprivation

We have reported in our previous work that, in the absence of HCO(3)(-), Na(+)/H(+) exchanger is responsible for an anoxia-induced alkalinization in hippocampal CA1 neurons. HCO(3)(-)-dependent mechanisms have been reported to play a key role in pH(i) regulation in nerve cells, but how their function is affected by O(2) deprivation has not been well studied. In this work, pH(i) measurements (obtained from dissociated neurons loaded with carboxy-seminaphthorhodafluor-1 and using confocal microscopy) and whole-cell patch clamp recording techniques were used to investigate the role of HCO(3)(-)-dependent membrane exchangers on CA1 neurons during O(2) deprivation. Anoxia (5 min) induced a small acidification in neurons in the presence of HCO(3)(-) and this acidification was changed to a significant alkalinization when neurons were bathed with Hepes buffer or when 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid was applied in a HCO(3)(-) solution, indicating that HCO(3)(-)-dependent mechanisms were involved. A marked anoxia-induced acidification (0.33+/-0.11 pH unit) was seen when the Na(+)/H(+) exchange was blocked with 3-(methylsulfonyl-4-piperidino-benzoyl)-guanidine methanesulfonate in the presence of HCO(3)(-), but the same anoxia did not cause a significant pH(i) change in a Na(+) free, HCO(3)(-) solution, suggesting that the anoxia-induced acidification in the presence of 3-(methylsulfonyl-4-piperidino-benzoyl)-guanidine methanesulfonate is dependent on both Na(+) and HCO(3)(-). Furthermore, anoxia did not cause a significant pH(i) change when both 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid and 3-(methylsulfonyl-4-piperidino-benzoyl)-guanidine methanesulfonate were present. Current clamp recordings showed a significant membrane depolarization following anoxia in HCO(3)(-) solution but not in Hepes buffer. Our data suggest that, in hippocampal neurons: a) pH(i) regulation during O(2) deprivation is affected not only by metabolism but also by membrane exchangers, and b) besides the activation of Na(+)/H(+) exchange, anoxia activates a 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid-sensitive, Na(+)-dependent acid loader (possibly electrogenic).     

Effects of temperature on intracellular sodium, pH and cellular energy status in RIF-1 tumor cells

Most perfused tumor cell experiments are performed at 37 degrees C, the normal healthy body temperature. However, the temperature of subcutaneously implanted tumors in small animals is generally 29-33 degrees C when the rectal temperature of the animal is maintained at 37 degrees C. We have investigated the acute effects of increasing the temperature of perfused radiation-induced-fibrosarcoma (RIF-1) tumor cells from 33 to 37 degrees C (30 min) on intracellular sodium (Na(i)+) , intracellular pH (pH(i)), and bioenergetic status. Heating the cells by 4 degrees C produced a reversible increase in Na(i)+, slight acidification and no change in nucleotide triphosphate to inorganic phosphate ratio (NTP/P(i)) as measured by shift-reagent-aided (23)Na and (31)P NMR spectroscopy. In the presence of 3 microM 5-(N-ethyl-N-isopropyl) amiloride (EIPA), a potent and specific inhibitor of Na(+)/H(+) antiporter, the increase in Na(i)+ during the heating was completely abolished suggesting that the heat induced increase in Na(i)+ was caused by an increase in Na(+)/H(+) antiporter activity. However, the changes in pH(i) with the heating were identical with or without EIPA, indicating that pH(i) is controlled by other ion exchange mechanisms in addition to Na(+)/H(+) antiporter. NTP/P(i) was significantly higher in presence of EIPA for some time points during the heating suggesting that both NTP production and consumption rates may be altered during the heating. These results indicate that a slight increase in temperature from 33 to 37 degrees C induces significant changes in Na(+) physiology largely because of activation of Na(+)/H(+) antiporter but other ion exchange mechanisms are also involved in maintaining pH(i) in the RIF-1 tumor cells. Thus, care must be taken in choosing the temperature for perfused cell studies.     

Na(+)-H+ exchange is not important for pancreatic HCO3- secretion in the pig.

Pancreatic inter- and intralobular duct cells extrude H(+)-ions to interstitial fluid when they secrete HCO3- to pancreatic juice. This study assesses the potential importance of Na(+)-H(+)-ion exchange for H(+)-ion extrusion and secretion of HCO3-, using the Na(+)-H+ exchange blockers amiloride and hexamethylene-amiloride. Intracellular pH (pHi) in inter- and intralobular pancreatic duct epithelium was measured using BCECF fluorescence. H(+)-ion efflux was measured using a NH4Cl prepulse, acid-loading technique. In HCO3(-)-free media, pHi recovery following acid loading was blocked by amiloride (10(-4) M) and hexamethylene-amiloride (10(-6) M), demonstrating amiloride- and hexamethylene-amiloride-sensitive Na(+)-H+ exchange. However, 5 x 10(-6) M hexamethylene-amiloride did not reduce secretin-dependent pancreatic HCO3- secretion in vivo. Maximal H(+)-efflux through Na(+)-H+ exchange was 1.5 +/- 0.2 mumol min-1 ml cell volume-1, i.e. less than 1% of estimated net H(+)-ion efflux during HCO3- secretion. Conclusion: amiloride- and hexamethylene amiloride sensitive Na(+)-H+ exchange is not important for secretin-dependent pancreatic HCO3- secretion in the pig. Other mechanisms for H+ extrusion dominate.     

Regulation of pH in human skeletal muscle: adaptations to physical activity

Regulation of pH in skeletal muscle is the sum of mechanisms involved in maintaining intracellular pH within the normal range. Aspects of pH regulation in human skeletal muscle have been studied with various techniques from analysis of membrane proteins, microdialysis, and the nuclear magnetic resonance technique to exercise experiments including blood sampling and muscle biopsies. The present review characterizes the cellular buffering system as well as the most important membrane transport systems involved (Na(+)/H(+) exchange, Na-bicarbonate co-transport and lactate/H(+) co-transport) and describes the contribution of each transport system in pH regulation at rest and during muscle activity. It is reported that the mechanisms involved in pH regulation can undergo adaptational changes in association with physical activity and that these changes are of functional importance.     

Luminal ions and short chain fatty acids as markers of functional activity of the mucosa in ulcerative colitis.

Luminal concentrations of short chain fatty acids (SCFA), ammonia, sodium and potassium were measured in colonic dialysate of 16 control subjects and in 65 cases with ulcerative colitis (UC), which were graded according to mucosal changes into mild (1), moderate (2), or severe (3) inflammatory activity. Sodium concentrations were mildly but not significantly increased in severe ulcerative colitis while luminal potassium concentrations were markedly decreased in severe ulcerative colitis (p less than 0.025). Concentrations of SCFA were increased in severe ulcerative colitis. Butyrate concentrations were significantly raised in all stages of active ulcerative colitis even when other fatty acids were not raised. Of all the parameters a lowered pH and raised butyrate concentration most strikingly correlate with the severity of mucosal change. Results indirectly suggest that control of luminal pH, potassium secretion and utilisation of butyrate by the colonic mucosa are impaired with progressive mucosal inflammation.     

Colonic fermentation: metabolic and clinical implications

Colonic SCFA formation from fermentable carbohydrate is important for the maintenance of morphologic and functional integrity of the colonic epithelium. Carbohydrate-induced diarrhea occurs when the amount of carbohydrate entering the colon exceeds its fermentation capacity. Deficient availability or utilization of SCFA, mainly of n-butyrate, is the cause of diversion colitis and may play important roles in colonic carcinogenesis, in starvation and enterotoxigenic diarrhea, and in idiopathic UC.Abbreviations NSP nonstarch polysaccharide - SCFA shortchain fatty acids - SRB sulfate-reducing bacteria - UC idiopathic ulcerative colitis     

EBIO, an agent causing maintained epithelial chloride secretion by co-ordinate actions at both apical and basolateral membranes

The effect of 1-ethyl-2-benzimidazolone (EBIO) on electrogenic chloride secretion in murine colonic and nasal epithelium was investigated by the short-circuit technique. In the colon, EBIO produces a sustained current increase in the presence of amiloride, which is sensitive to furosemide. In nasal epithelium EBIO causes only a small, transient current increase. Sustained increases in current were obtained in response to forskolin in both epithelia. To examine the mechanisms by which EBIO increases chloride secretion, the effects on intracellular mediators were measured in colonic crypts. There was no effect on [Ca(2+)]i but cAMP content was increased, more so in the presence of IBMX, indicating a direct effect on adenylate cyclase. In colonic epithelia in which the apical surface was permeabilized by nystatin, and the tissue subjected to an apical to basolateral K(+) gradient, EBIO caused a current increase that was entirely sensitive to charybdotoxin (ChTX). In similarly permeabilized colons Br-cAMP caused a current increase that was entirely sensitive to 293B. Thus EBIO increases chloride secretion in the colon by coordinated actions at both the apical and basolateral faces of the cells. These include direct and indirect actions on Ca(2+)-sensitive and cAMP-sensitive K(+) channels respectively, and indirect actions on the basolateral cotransporter and apical CFTR chloride channels via cAMP. In CF colonic epithelia EBIO did not evoke chloride secretion. It is not clear why the nasal epithelium responds poorly to EBIO whereas it gives a sustained response to the related compound chlorzoxazone.     

Na(+) transport across rumen epithelium of hay-fed sheep is acutely stimulated by the peptide IGF-1 in vitro

An energy-rich diet leads to enhanced ruminal Na(+) absorption, which is associated with elevated plasma insulin-like growth factor 1 (IGF-1) levels and an increased number of IGF-1 receptors in rumen papillae. This study examined the in vitro effect of IGF-1 on Na(+) transport across the rumen epithelium of hay-fed sheep, in which the IGF-1 concentration in plasma is lower than in concentrate-fed animals. At concentrations ranging from 20 to 100 μg l(-1), serosal LR3-IGF-1, a recombinant analogue of IGF-1, rapidly (within 30 min) stimulated the mucosal-to-serosal Na(+) flux (J(ms)Na) and consequently the net Na(+) flux (J(net)Na). Compared with controls, J(net)Na increased by about 60% (P < 0.05) following the serosal application of LR3-IGF-1 (20 μg l(-1)). The IGF-1-induced increment of J(ms)Na and J(net)Na was inhibited by mucosal amiloride (1 mmol l(-1)). Neither IGF-1 nor amiloride altered tissue conductance or the short-circuit current of the isolated rumen epithelium. These data support the assumption that the stimulating effect of serosally applied IGF-1 on Na(+) transport across the rumen epithelium is mediated by Na(+)-H(+) exchange (NHE). A further study was performed with cultured rumen epithelial cells and a fluorescent probe (BCECF) to estimate the rate of pH(i) recovery after acid loading. The pH(i) of isolated rumen epithelial cells was 6.43 ± 0.15 after butyrate loading and recovered by 0.26 ± 0.02 pH units (15 min)(-1). Application of LR3-IGF-1 (20 μg l(-1)) significantly increased the rate of pH(i) recovery to 0.33 ± 0.02 pH units (15 min)(-1). Amiloride administration reduced the recovery rate in both control and IGF-1-stimulated cells. These results show, for the first time, that an acute effect of IGF-1 on Na(+) absorption across rumen epithelium results from increased NHE activity. Insulin-like growth factor 1 is thus important for the fast functional adaptation of ruminal Na(+) transport via NHE.     

Secretin stimulates bile ductules to secrete both H+ and HCO3(-)-ions.

Secretin-dependent ductular HCO3- secretion into bile may involve secretion of H+ to interstitial fluid and HCO3- to bile by the ductular epithelium. To determine whether secretin causes bile ductules to secrete H+, we have examined the effect of secretin on the elimination of an intracellular acid load from bile ductular epithelium during pharmacological blockade of Na(+)-H+ exchange and in the absence of HCO3-. Microdissected bile ductules from pigs were suspended in HCO3- free HEPES buffer and loaded with acid using an NH4Cl prepulse technique. Intracellular pH was measured using dual-wavelength excitation of BCECF fluorescence. Na(+)-H+ exchange was defined as a Na(+)-dependent and amiloride- and 5-(N,N-hexamethylene)-amiloride-sensitive efflux of H(+)-ions following acid loading. We found that secretin stimulated ductular H+ secretion independent of Na(+)-H+ exchange. Blockade of Na(+)-H+ exchange by hexamethylene-amiloride did not affect secretin-dependent ductular HCO3- choleresis in vivo. We conclude that secretin stimulates bile ductules to secrete H(+)-ions to interstitial fluid as well as HCO3- ions to bile by a mechanism independent of Na(+)-H+ exchange.     

Ammonia inhibits sodium and chloride absorption in rat distal colon

It was recently demonstrated that ammonia inhibits sodium absorption in the proximal colon of rats. In order to investigate the effect of luminal ammonia in the distal colon, sodium and chloride transport were measured in Ussing chambers. Under short-circuit conditions, distal colon absorbed sodium and chloride. When luminal ammonia (30 mmol l(-1)) was present, sodium and chloride absorption was diminished. Inhibition of the two Na(+)-H(+) exchanger isoforms NHE2 and NHE3, which are known to be located in the apical membrane of the distal colon epithelium, failed to influence the effect of ammonia on transepithelial sodium and chloride fluxes. The inhibitory effect of ammonia was eliminated under the following conditions: after block of carbonic anhydrases with acetazolamide, in the presence of an unspecific blocker of Na(+)-H(+) exchangers, and under chloride-free conditions. Ammonia did not alter electrogenic sodium absorption. These results demonstrate that luminal ammonia inhibits sodium and chloride absorption in rat distal colon. We suggest that ammonia inhibits NaCl absorption by interfering with a Na(+)-H(+) exchanger that is not NHE2 or NHE3     

Transcellular and paracellular pathways of transepithelial fluid secretion in Malpighian (renal) tubules of the yellow fever mosquito Aedes aegypti

Isolated Malpighian tubules of the yellow fever mosquito secrete NaCl and KCl from the peritubular bath to the tubule lumen via active transport of Na(+) and K(+) by principal cells. Lumen-positive transepithelial voltages are the result. The counter-ion Cl(-) follows passively by electrodiffusion through the paracellular pathway. Water follows by osmosis, but specific routes for water across the epithelium are unknown. Remarkably, the transepithelial secretion of NaCl, KCl and water is driven by a H(+) V-ATPase located in the apical brush border membrane of principal cells and not the canonical Na(+), K(+) -ATPase. A hypothetical cation/H(+) exchanger moves Na(+) and K(+) from the cytoplasm to the tubule lumen. Also remarkable is the dynamic regulation of the paracellular permeability with switch-like speed which mediates in part the post-blood-meal diuresis in mosquitoes. For example, the blood meal the female mosquito takes to nourish her eggs triggers the release of kinin diuretic peptides that (i) increases the Cl(-) conductance of the paracellular pathway and (ii) assembles V(1) and V(0) complexes to activate the H(+) V-ATPase and cation/H(+) exchange close by. Thus, transcellular and paracellular pathways are both stimulated to quickly rid the mosquito of the unwanted salts and water of the blood meal. Stellate cells of the tubule appear to serve a metabolic support role, exporting the HCO(3)(-) generated during stimulated transport activity. Septate junctions define the properties of the paracellular pathway in Malpighian tubules, but the proteins responsible for the permselectivity and barrier functions of the septate junction are unknown.     

Elevated intracellular zinc and altered proton homeostasis in forebrain neurons

Using the H(+)-sensitive fluorophore 2',7'-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein (BCECF) and microfluorimetry, we investigated how elevated intracellular free zinc ([Zn(2+)](i)) altered intracellular proton concentration (pH(i)) in dissociated cultures of rat forebrain neurons. Neurons exposed to extracellular zinc (3 microM) in the presence of the Zn(2+)-selective ionophore pyrithione (20 microM) underwent intracellular acidification that was not reversed upon washout of the stimulus. Application of a membrane-permeant Zn(2+) chelator, but not an impermeant chelator, partially restored pH(i). Removal of extracellular Ca(2+) greatly inhibited [Zn(2+)](i)-induced acidification, suggesting that acidification was a secondary consequence of Ca(2+) entry. Additional experiments suggested that Ca(2+) entered through the plasma membrane sodium/calcium exchanger (NCE), because a specific inhibitor of reverse mode NCE operation, KB-R7943 (1 microM), significantly inhibited Zn(2+)-induced acidification.In addition to the phenomenon of [Zn(2+)](i)-induced acidification, we found that elevated [Zn(2+)](i) inhibited neuronal recovery from low pH(i). Neurons exposed to a protonophore underwent robust acidification, and pH(i) recovery ensued upon protonophore washout. In contrast, neurons acidified by the protonophore in the presence of Zn(2+) (3 microM) and pyrithione (20 microM) showed no ability to recover from low pH(i). Application of a membrane-permeant Zn(2+) chelator partially restored pH(i) to pre-stimulus values. Experiments designed to elucidate mechanisms responsible for pH(i) regulation revealed that neurons relied primarily on bicarbonate exchange for proton export, suggesting that elevated [Zn(2+)](i) might impede pH(i) by inhibiting proton efflux via bicarbonate exchange. These results provide novel insights into the physiological effects of raising [Zn(2+)](i), and may help illuminate the mechanisms by which Zn(2+) injures neurons.     

The role of bicarbonate, chloride and sodium ions in the regulation of intracellular pH in snail neurones

1. Intracellular pH (pH(i)), Cl(-) and Na(+) levels were recorded in snail neurones using ion-sensitive micro-electrodes, and the mechanism of the pH(i) recovery from internal acidification investigated.2. Reducing the external HCO(3) (-) concentration greatly inhibited the rate of pH(i) recovery from HCl injection.3. Reducing external Cl(-) did not inhibit pH(i) recovery, but reducing internal Cl(-), by exposing the cell to sulphate Ringer, inhibited pH(i) recovery from CO(2) application.4. During pH(i) recovery from CO(2) application the internal Cl(-) concentration decreased. The measured fall in internal Cl(-) concentration averaged about 25% of the calculated increase in internal HCO(3) (-).5. Removal of external Na inhibited the pH(i) recovery from either CO(2) application or HCl injection.6. During the pH(i) recovery from acidification there was an increase in the internal Na(+) concentration ([Na(+)](i)). The increase was larger than that occurring when the Na pump was inhibited by K-free Ringer.7. The increase in [Na(+)](i) that occurred during pH(i) recovery from an injection of HCl was about half of that produced by a similar injection of NaCl.8. The inhibitory effects of Na-free Ringer and of the anion exchange inhibitor SITS on pH(i) recovery after HCl injection were not additive.9. It is concluded that the pH(i) regulating system involves tightly linked Cl(-)-HCO(3) (-) and Na(+)-H(+) exchange, with Na entry down its concentration gradient probably providing the energy to drive the movement inwards of HCO(3) (-) and the movement outward of Cl(-) and H(+) ions.     

Na+-H+ exchange activity in taste receptor cells

mRNA for two Na(+)-H(+)-exchanger isoforms 1 and 3 (NHE-1 and NHE-3) was detected by RT-PCR in fungiform and circumvallate taste receptor cells (TRCs). Anti-NHE-1 antibody binding was localized to the basolateral membranes, and the anti-NHE-3 antibody was localized in the apical membranes of fungiform and circumvallate TRCs. In a subset of TRCs, NHE-3 immunoreactivity was also detected in the intracellular compartment. For functional studies, an isolated lingual epithelium containing a single fungiform papilla was mounted with apical and basolateral sides isolated and perfused with nominally CO(2)/HCO(3)(-)-free physiological media (pH 7.4). The TRCs were monitored for changes in intracellular pH (pH(i)) and Na(+) ([Na(+)](i)) using fluorescence ratio imaging. At constant external pH, 1) removal of basolateral Na(+) reversibly decreased pH(i) and [Na(+)](i); 2) HOE642, a specific blocker, and amiloride, a nonspecific blocker of basolateral NHE-1, attenuated the decrease in pH(i) and [Na(+)](i); 3) exposure of TRCs to basolateral NH(4)Cl or sodium acetate pulses induced transient decreases in pH(i) that recovered spontaneously to baseline; 4) pH(i) recovery was inhibited by basolateral amiloride, 5-(N-methyl-N-isobutyl)-amiloride (MIA), 5-(N-ethyl-N-isopropyl)-amiloride (EIPA), HOE642, and by Na(+) removal; 5) HOE642, MIA, EIPA, and amiloride inhibited pH(i) recovery with K(i) values of 0.23, 0.46, 0.84, and 29 microM, respectively; and 6) a decrease in apical or basolateral pH acidified TRC pH(i) and inhibited spontaneous pH(i) recovery. The results indicate the presence of a functional NHE-1 in the basolateral membranes of TRCs. We hypothesize that NHE-1 is involved in sour taste transduction since its activity is modulated during acid stimulation.     

Acid-base balance and CO2 excretion in fish: unanswered questions and emerging models

Carbon dioxide (CO(2)) excretion and acid-base regulation in fish are linked, as in other animals, though the reversible reactions of CO(2) and the acid-base equivalents H(+) and HCO(3)(-): CO(2)+H(2)O<-->H(+)+HCO(3)(-). These relationships offer two potential routes through which acid-base disturbances may be regulated. Respiratory compensation involves manipulation of ventilation so as to retain CO(2) or enhance CO(2) loss, with the concomitant readjustment of the CO(2) reaction equilibrium and the resultant changes in H(+) levels. In metabolic compensation, rates of direct H(+) and HCO(3)(-) exchange with the environment are manipulated to achieve the required regulation of pH; in this case, hydration of CO(2) yields the necessary H(+) and HCO(3)(-) for exchange. Because ventilation in fish is keyed primarily to the demands of extracting O(2) from a medium of low O(2) content, the capacity to utilize respiratory compensation of acid-base disturbances is limited and metabolic compensation across the gill is the primary mechanism for re-establishing pH balance. The contribution of branchial acid-base exchanges to pH compensation is widely recognized, but the molecular mechanisms underlying these exchanges remain unclear. The relatively recent application of molecular approaches to this question is generating data, sometimes conflicting, from which models of branchial acid-base exchange are gradually emerging. The critical importance of the gill in acid-base compensation in fish, however, has made it easy to overlook other potential contributors. Recently, attention has been focused on the role of the kidney and particularly the molecular mechanisms responsible for HCO(3)(-) reabsorption. It is becoming apparent that, at least in freshwater fish, the responses of the kidney are both flexible and essential to complement the role of the gill in metabolic compensation. Finally, while respiratory compensation in fish is usually discounted, the few studies that have thoroughly characterized ventilatory responses during acid-base disturbances in fish suggest that breathing may, in fact, be adjusted in response to pH imbalances. How this is accomplished and the role it plays in re-establishing acid-base balance are questions that remain to be answered.     

A role for Na+/H+ exchange in pH regulation in Helix neurones

We have used the pH-sensitive fluorescent dye 8-hydroxypyrene-1,3,6-trisulphonic acid (HPTS) to reexamine the mechanisms that extrude acid from voltage-clamped Helix aspersa neurones. Intracellular acid loads were imposed by three different methods: application of weak acid, depolarization and removal of extracellular sodium. In nominally CO2/HCO3-free Ringer the rate of recovery from acid loads was significantly slowed by the potent Na+/H+ exchange inhibitor 5-[N-ethyl-N-isopropyl]-amiloride (EIPA, 50 microM). Following depolarization-induced acidifications the rate of intracellular pH (pHi) recovery was significantly reduced from 0.41 +/- 0.13 pH units.h-1 in controls to 0.12 +/- 0.09 pH units.h-1 after treatment with EIPA at pHi approximately equal to 7.3 (n = 7). The amiloride analogue also reduced the rate of acid loading seen during extracellular sodium removal both in the presence and absence of the Na(+)-dependent Cl-/HCO3- exchange inhibitor 4-acetamido-4'-isothiocyanato-stilbene-2,2'-disulphonic acid (SITS, 50 microM). This is consistent with EIPA inhibiting reverse-mode Na+/H+ exchange. In 2.5% CO2/20 mM HCO3-buffered Ringer pHi recovery was significantly inhibited by SITS, but unaffected by EIPA. Our results indicate that there are two separate Na(+)-dependent mechanisms involved in the maintenance of pHi in Helix neurones: Na(+)-dependent Cl-/HCO3- exchange and Na+/H+ exchange. Acid extrusion from Helix neurones is predominantly dependent upon the activity of Na(+)-dependent Cl-/HCO3- exchange with a lesser role for Na+/H+ exchange. This adds further weight to the belief that the Na+/H+ exchanger is ubiquitous.