Optimal absorptive transport of the dipeptide glycylsarcosine is dependent on functional Na+/H+ exchange activity

Optimal nutrient absorption across the intestinal epithelium is dependent on the co-ordinated activity of a number of membrane transporters. Di/tripeptide transport across the luminal membrane of the intestinal enterocyte is mediated by the H(+)-coupled di/tripeptide transporter hPepT1. hPepT1 function is dependent on the existence of a pH gradient (maintained, in part, by the action of the Na(+)/H(+) exchanger NHE3) across the apical membrane of the small intestinal epithelium. The physiological problem addressed here was to determine how two transporters (hPepT1 and NHE3), involved in nutrient absorption and pH(i) homeostasis, function co-operatively to maximise dipeptide absorption when both operate sub-optimally at typical mucosal surface pH values (pH 6.1-6.8). Functional hPepT1 activity in human intestinal epithelial (Caco-2) cell monolayers was determined by measurement of apical uptake and apical-to-basolateral transport of the dipeptide glycylsarcosine. The dependence of hPepT1 on NHE3 activity was measured (either after Na(+) removal or addition of the NHE3-selective inhibitor S1611) using both Caco-2 cell monolayers and hPepT1-expressing Xenopus laevis oocytes. Apical glycylsarcosine uptake in Caco-2 cell monolayers was modulated by apical pH, extracellular Na(+), incubation time and S1611. Uptake in hPepT1-expressing oocytes was independent of Na(+) or S1611. We conclude that functional NHE3 activity is required to allow optimal absorption of dipeptides across the human intestinal epithelium.     

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.     

Effects of diet and osmotic pressure on Na+ transport and tissue conductance of sheep isolated rumen epithelium

The intention of this study was to determine the effects of mucosal osmotic pressure on transport and barrier functions of the rumen epithelium of sheep, which were fed various diets: hay ad libitum, or 600, 1200 or 1800 g day(-1) of a supplemented diet plus hay ad libitum. The experiments were conducted by using the conventional Ussing chamber technique. Mucosal osmolarity was adjusted to 300 (control), 375 or 450 mosmol l(-1). Feeding of a supplemented diet led to a significant increase of mucosal to serosal Na+ transport and net Na+ transport, probably because of an increase of apical Na+-H+ exchange activity. An increase in mucosal osmotic pressure: (a) reduced net Na+ transport in all feeding groups, the remaining net Na+ transport being higher in tissues of sheep fed a supplemented diet; (b) increased transepithelial tissue conductance, this rise being smallest with a high intake of the supplemented diet; and (c) enhanced the serosal to mucosal Na+ transport in tissues of hay-fed sheep and sheep fed with 600 g day(-1) of the supplemented diet, while higher intakes of the supplemented diet (1200 and 1800 g) did not produce any effect. All these changes indicate a diet-dependent adaptation to luminal hypertonicity.     

In vitro primate gastric mucosa: electrical characteristics

Ion transport by the resting, isolated, rhesus gastric mucosa was assessed under conditions of minimal diffusion limitation to oxygen by 1) the substitution of Na+ and Cl- of the bathing solutions with less permeant ions, 2) the drugs amiloride and ouabain, and 3) estimation of net fluxes of 22Na by methods designed to circumvent the problem of poorly matched tissues. The mucosae developed potential differences of 51.3 +/ 3.5 mV, serosal side positive and had conductances of 5.56 +/- 0.30 mS x cm-2. The permeabilities of the tissues to D-mannitol were between 7.80 x 10(-7) and 3.15 x 10(-7) cm x s-1. The relatively high conductance of this epithelium in the absence of significant edge damage and a low (32%) paracellular conductance stems mainly from a passive permeability to Cl-; active absorption of Na+ and active secretion of Cl- contribute equally to the short-circuit current. The mucosal entry step for Na+ is amiloride sensitive, whereas the serosal exit step can be inhibited by ouabain. The entry step for Cl- at the serosal membrane is possibly sodium dependent.     

Regulatory role of cAMP in transport of Na+, Cl- and short-chain fatty acids across sheep ruminal epithelium

Sodium is absorbed in considerable amounts across the ruminal epithelium, whilst its transport is strongly interrelated with the permeation of chloride and short-chain fatty acids (SCFAs). However, regulation of ruminal Na+, Cl-, and SCFA absorption is hardly understood. The present study was therefore performed to characterize the influence of cAMP on sodium and sodium-coupled transport mechanisms in short-circuited, stripped ruminal epithelia of sheep. Elevation of intracellular cAMP concentrations by theophylline (10 mM) or theophylline in combination with forskolin (0.1 mM) significantly reduced mucosal-to-serosal sodium transport, leading to a reduction of net transport. The theophylline- or theophylline-forskolin-induced reduction of sodium transport was accompanied by a decrease in chloride net transport but revealed no effect on propionate flux. Short-chain fatty acids stimulated Na+ transport but their stimulatory effect was almost completely blocked by theophylline-forskolin. In solutions with and without SCFAs, the inhibitory effect of 1 mM amiloride on sodium transport was strongly reduced after theophylline-forskolin pretreatment of the tissues. Blocking the production of endogenous prostaglandins by addition of indomethacin (10 microM) led to a theophylline-sensitive stimulation of unidirectional and net fluxes of sodium. The findings indicate that apical, amiloride-sensitive Na+-H+ exchange and/or basolateral Na+-K+-ATPase can effectively be blocked by cAMP, leading to a decrease in sodium and chloride transport. In the ruminal epithelium, cAMP is a second messenger of prostaglandins, which are released spontaneously under in vitro conditions.     

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.     

Sodium chloride absorption and solute-linked water flow across the epithelium of the coprodeum and large intestine in the normal and dehydrated fowl (Gallus domesticus). In vivo perfusion studies

1. The transmural net flow of salt and water in the coprodeum and large intestine of normal and dehydrated hens was investigated by means of an intraluminal in vivo perfusion technique. The lumen was perfused with hypo-, iso-, and hyperosmotic salt solutions. Polyethylene glycol (PEG 4000) and [(14)C]inulin served as water markers.2. The maximal net Na(+) flow (J(Na)) from the mucosal to the serosal side was nearly the same in the two states of hydration: normal birds 308 mu-equiv/kg.hr, dehydrated birds 281 mu-equiv/kg.hr, while the J(Na) was half maximal at luminal Na(+) concentrations of 99 and 43 mu-equiv/l. respectively. The ;affinity' for Na(+) in the dehydrated bird was thus twice that in the normal bird. K(+) was secreted into the gut lumen at a constant rate against the electrochemical gradient, J(K) = -97 mu-equiv/kg.hr (S.E. = 5). Cl(-) was absorbed from lumen to plasma down the electrochemical gradient with J(Cl) ranging from 0 to 94 mu-equiv/kg.hr. The low J(Cl) was observed at low luminal NaCl concentrations when the J(Na) was also small.3. The solute-linked water flow, J(vs), occurring in the absence of an osmolality difference across the epithelium, was 1.1 mul. H(2)O/mu-equiv Na(+) in normal birds and 1.5 in dehydrated birds. The J(vs) was calculated as an operational parameter in experiments with luminal osmolalities different from plasma osmolality by subtracting the water flow observed in an experiment without Na(+) in the perfusion fluid from the water flow in an experiment with Na(+) containing perfusion fluids, both fluids being of the same osmolality. J(vs) was maximal at luminal osmolalities close to plasma osmolality. These observations are compatible with the hypothesis that the J(vs) is due to an osmotic flow into a confined region between the cells.4. When the perfusion rate was lowered from 5-9 ml./kg.hr to 0.8-1.0 the incoming perfusion fluid osmolality at which net water flow across the epithelium was zero went up from 100 to 180 m-osmolal higher than plasma osmolality. This observation suggests that a significant fraction of ureteral urine in the dehydrated bird may be absorbed in the coprodeum and large intestine.     

Water and sodium movements across the ruminal epithelium in fed and food-deprived sheep

Fluid and electrolyte movements across the ruminal epithelium of sheep were studied using the temporarily isolated rumen technique. The sheep were all subjected to the following treatments: (1) fed sheep (fed twice daily), after rumen emptying, received rumen contents from a fed sheep; (2) food-deprived sheep (two meals were omitted), after rumen emptying, received rumen contents from a food-deprived sheep; (3) fed sheep, after rumen emptying, received rumen contents from a food-deprived sheep; and (4) food-deprived sheep, after rumen emptying, received rumen contents from a fed sheep. Food deprivation led to an increased Na concentration of the rumen fluid while K and Cl concentrations, as well as osmolality, decreased. Plasma Na and osmolality decreased. During the 40 min after the rumen contents were exchanged no net movements of water occurred. Then the sheep were given an intraruminal load of saline which gave rise to a significant net absorption of fluid from the rumens of those sheep which had received rumen contents from fed sheep. The change in composition of the rumen contents after food deprivation impaired the absorption of Na and water from the rumen. Furthermore food deprivation reduced the Na absorptive function of the ruminal epithelium, but not the water permeability.     

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     

Na+ transport by mammalian stomach.

Gastric mucosas from newborn pigs (0--20 days) and rabbits (0--20 days) were used for in vitro investigation of active Na+ transport during resting (no HCl secretion) conditions. As measured with 22Na+, these tissues actively absorb Na+ from the mucosal-to serosal (m-t-s) bathing solution during both open-circuit and short-circuit current (Is) conditions. In the nonsecreting state, net Na+ transport accounts for 40--60% of Isc. The remaining current is provided by net s-to-m flux of Cl-. Amiloride (2-5 X 10(-5) M) in the mucosal solution abolishes this active Na+ transport by inhibiting m-to-s fluxes of Na+ (JNams). In vivo-in vitro experiments showed that active Na+ transport is a normal function of the resting mammalian stomach. Decreasing pH of the mucosal solution below pH 5 reversibly causes decreased current-generating capability of the tissue. Pretreatment of the tissue with amiloride abolishes this pH effect. The implication is that the low pH affects the Na+-entry step into cells. "Titration curves" of current vs. pH had an apparent pK approximately 4.0. Ouabain and K+-free solutions both cause decreases in active Na+ and Cl- current. Calculations indicate that a shunt may account for only a small (less than 30%) percentage of total transepithelial conductance.     

Mechanism of electrically silent Na and Cl transport across the rumen epithelium of sheep

This study was designed to study the mechanism of electroneutral Na and Cl transport across the isolated rumen epithelium of sheep. Net sodium transport (5.75 +/- 0.35 microequiv cm-2 h-1) was significantly higher than the short-circuit current (0.95 +/- 0.08 microequiv cm-2 h-1). Both, net sodium and net chloride transport were markedly reduced by replacement of chloride, bicarbonate and sodium, respectively, but were not changed by the absence of mucosal potassium. Net sodium and net chloride absorption was significantly decreased by 1.0 mM-amiloride. Mucosal addition of bumetanide, furosemide, hydrochlorothiazide or low concentrations of amiloride (less than 0.1 mM) did not change sodium fluxes. These results provide compelling evidence consistent with the presence of Na-H exchange as the predominant electroneutral mechanism for transepithelial sodium movement. The ion replacement studies and data from literature suggest that the Na-H exchange is working in parallel with a Cl-HCO3 exchange although luminal addition of DIDS (4,4'diisothiocyanatostilbene-2,2'-disulphonate, 1 mM) did not significantly influence Cl transport.     

The effect of ouabain on ion transport across isolated sheep rumen epithelium.

1. The net flux of Na from the lumen to the blood side of isolated sheep rumen epithelium was reduced to zero in the third 30 min period after treatment with ouabain. 2. The net flux of K from blood to lumen side of the epithelium was reduced from 0-34 to 0-13 mumole/cm2. hr in the third 30 min period after ouabain treatment. 3. The net flux of Cl from lumen to blood side of the epithelium was reduced from 1-4 to 0-72 mumole/cm2. hr in the third 30 min period after ouabain treatment. 4. The results support the existence of a Cl pump independent of Na transport and also a K pump in sheep rumen epithelium.     

Muscarinic down-regulation of cAMP-stimulated potassium ion secretion by rabbit distal colon

The sustained effects of the cholinergic agonist carbachol (CCh) on electrolyte transport across the isolated, short-circuited rabbit distal colon were examined in the absence and presence of secretagogue (di-butyryl cyclic-adenosine monophosphate, dB-cAMP). Steady-state, basal absorption of 22Na+, 42K+ (86Rb+), and 36Cl- were not significantly altered by addition of the CCh (10(-4) mmol/l) to the serosal reservoir. Stimulation with dB-cAMP (1.0 mmol/l, serosal) promoted K+ (or Rb+) and Cl- secretion across the colon, without significantly affecting the unidirectional or net fluxes of Na+. Serosal (but not mucosal) addition of CCh to dB-cAMP-stimulated tissues reduced the serosal to mucosal flux of Rb+ (J(Rb)SM) in a concentration-dependent manner with a half-maximum concentration approximately equal 5 micromol/l. Pretreatment with CCh (100 micromol/l, serosal) inhibited dB-cAMP-induced K+ secretion, but had no significant effect on the steady-state unidirectional fluxes of Na+ or Cl-. Serosal histamine (20 micromol/l) also inhibited J(Rb)SM in dB-cAMP-stimulated tissues. Serosal epinephrine (10 micromol/l) promoted a decrease in short-circuit current (Isc) and transepithelial potential (VT) that was mirrored by increases in J(Rb)SM. Both Isc, and VT became more positive and J(Rb)SM was reduced when CCh was added to the epinephrine-stimulated tissues. Serosal muscarine (50 micromol/l) mimicked the CCh-induced inhibition of J(Rb)SM, but serosal nicotine (50 micromol/l) had no effect. In atropine-treated tissues (1 micromol/l, serosal), CCh failed to block dB-cAMP-stimulated increases in J(Rb)SM. The inhibitory action of CCh was observed in tissues that had been pretreated with 50 micromol/l serosal hexamethonium (a ganglionic transmission blocker) or 2 micromol/l serosal tetrodotoxin (a voltage-gated Na+ channel blocker), indicating that the inhibitory action of this cholinergic agonist does not depend on remnant enteric neural pathways. Rubidium ion transport across confluent monolayers of T84 cells was similarly affected by dB-cAMP and CCh, supporting the notion that enteric neural pathways are not required. Serosal charybdotoxin (20 nmol/l) mitigated the inhibitory action of CCh on J(Rb)SM in dB-cAMP-stimulated tissues, suggesting a role for basolateral, Ca2+-dependent K+ channels in the actions of CCh. It is concluded that basolateral muscarinic receptors (and possibly other Ca2+-dependent receptor pathways) of secretory colonocytes mediate the down-regulation of potassium ion secretion by rabbit distal colon, possibly by increasing basolateral membrane K+ conductance.     

Ileal HCO3 secretion: relationship to Na and Cl transport and effect of theophylline.

Interrelationships among Na, Cl, and HCO3 transport processes were examined in short-circuited rabbit ileal mucosa. As serosal (HCO3) was increased from 10 to 50 mM (pH from 7.1 to 7.8), net Na absorption decreased from 4.6 to 0.3 mueq/h-cm2, net Cl flux changed from absorption of 0.9 to secretion of 0.9 and a net HCO3 secretion of 3.0 developed. A similar change in net Cl flux was also observed when serosal Pco2 was altered at constant (HCO3). In Cl-free SO4-Ringer, serosal alkalinization produced net HCO3 secretion which was not significantly less than that observed in Cl-containing Ringer. Theophylline caused secretory changes in net Na and Cl fluxes at both 10 and 50 mM serosal (HCO3). Theophylline did not alter net HCO3 flux in Cl-Ringer but increased net HCO3 flux in SO4-Ringer. Total dc conductance was decreased by both serosal alkalinization and theophylline. Shortcircuit current was consistently increased by theophylline but not by serosal alkalinization. The results indicate that ileal ion transport is regulated in part by serosal pH and/or (HCO3) and that resulting changes in Cl and HCO3 transport are coupled one-for-one with changes in Na transport. Furthermore, HCO3 secretion does not require the presence of Cl in the bathing medium.     

Evidence for Na+ independent active secretion of K+ and HCO 3 − by rat salivary duct epithelium

In order to elucidate whether or not active secretion of potassium and bicarbonate by the rat submaxillary duct epithelium operates independently of sodium reabsorption, Na+ transport was blocked by amiloride, which is known to inhibit Na+ entry from lumen into cell. With 10(-4) M amiloride in HCO - 3 -Ringer at the luminal side, the transepithelial electrical potential difference approached zero, the Na+ conductance of the luminal cell membrane was drastically reduced, and the K+ conductance was significantly reduced. Net K+ secretion was reduced by 80%, whereas net HCO - 3 secretion was significantly increased. The remaining 20% of net K+ secretion proceeded at zero net Na+ transport and in the absence of significant chemical and electrical potential differences between lumen and interstitium of the duct. This active component of net K+ secretion was accompanied by an equal rate of active HCO - 3 secretion. These findings confirm the independence of this active secretion of K+ and HCO - 3 from Na+ transport. They indicate an electrically neutral secretion of K+ and HCO - 3, probably by the postulated luminal K+ -H+ -exchange mechanism. The 80% of net K+ secretion, which were abolished by amiloride together with Na+ reabsorption, seem to be functionally coupled with Na+ transport. The linkage of K+ -to- Na+ is probably mediated by a luminal carrier exchanging Na+ for K+ and H+.     

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.     

Sodium- and bicarbonate-independent regulation of intracellular pH in culture mouse astrocytes

The intracellular pH (pHi) of cultured mouse astrocytes was measured with double-barrelled pH-sensitive microelectrodes. In bicarbonate-buffered saline pHi was 7.05 and in HEPES-buffered saline 6.68. In both solutions H+ was not in electrochemical equilibrium; pHi was 0.7-1 pH unit more alkaline than expected from passive H+ distribution. Cells were acidified by applying NH4+ and the subsequent regulation of pHi was studied in bicarbonate-free saline. The mean rate of pHi recovery was 0.2 pH units min-1 which was not changed by amiloride or by removal of external Na+. Thus, the cells recovered from an acid load independently of Na(+)-H+ exchange, Na(+)-HCO3- cotransport or any other bicarbonate- or Na(+)-dependent mechanism.     

Intracellular carbonic anhydrase contributes to the red blood cell adrenergic response in rainbow trout Oncorhynchus mykiss

In many teleost fish, catecholamines activate a red blood cell (RBC) Na(+)/H(+) exchanger (βNHE), raising RBC intracellular pH to protect haemoglobin-O(2) loading. The present study tested the hypothesis that RBC intracellular carbonic anhydrase (CA) contributes to this adrenergic response. The pH of rainbow trout (Oncorhynchus mykiss) blood was monitored continuously in vitro using blood flowing in a semi-closed loop or in vivo using an extracorporeal circulation. Addition or injection of isoproterenol activated the βNHE, causing blood pH to fall (in vitro ΔpH=-0.28±0.03 pH units, N=16; in vivo, -0.12±0.02 pH units, N=6). Both in vitro and in vivo, inhibition of RBC CA by acetazolamide significantly decreased the magnitude of the adrenergic response (in vitro, ΔpH=-0.22±0.02 pH units, N=16; in vivo, -0.02±0.01 pH units, N=6) as well as the rate of recovery of blood pH following the adrenergic response. These results support the hypothesis that RBC intracellular CA plays an important role in the RBC adrenergic response of rainbow trout, and fuel speculation that interspecific differences in RBC CA activity are associated with the magnitude of the RBC adrenergic response.     

Effects of the Potassium Channel Blocker Barium on Sodium and Potassium Transport in the Rat Loop of Henle In Vivo

In vitro evidence suggests that the 'recycling' of K(+) ions through luminal K(+) channels in the thick ascending limb of the loop of Henle (TALH) is essential for the normal operation of the luminal Na(+)-K(+)-2Cl(-) co-transporter. In the present study these channels were investigated in vivo by perfusing superficial loops of Henle in anaesthetised rats with and without the K(+) channel blocker barium. Using a standard perfusate, intraluminal barium (5 mmol l(-1)) reduced sodium reabsorption (J(Na)) from 1887 +/- 50 to 1319 +/- 53 pmol min(-1) (P < 0.001). When the experiment was repeated using a low-Na(+) perfusate, designed to inhibit reabsorption in the pars recta (the initial segment of the loop of Henle), a similar reduction in J(Na) was observed (from 698 +/- 47 to 149 +/- 23 pmol min(-1), P < 0.001), strongly suggesting that the effect of barium is localised to the TALH. The magnitude of the reduction in J(Na) during blockade of K(+) channels confirms the importance of K(+) recycling in facilitating Na(+) reabsorption in the TALH in vivo. However, the reduction in J(Na) was not associated with a fall in the K(+) concentration of the fluid collected at the early distal tubule. When bumetanide, an inhibitor of the Na(+)-K(+)-2Cl(-) co-transporter, was included in the low-Na(+) perfusate, net K(+) secretion was observed. Addition of barium to this perfusate reduced, but did not abolish, the secretion, suggesting that bumetanide-induced K(+) secretion results partly from paracellular transport. Experimental Physiology (2001) 86.4, 469-474.