Bath HCO3 Research Articles

Conductive pathways for HCO3- in basolateral membrane of salamander intestinal cells

To understand the route of HCO3- exit across the basolateral membrane of Amphiuma small intestinal cells during active H+ secretion the influence of bath HCO3- on serosal membrane potential (Vs) was measured using conventional microelectrodes. The villus sheet preparation was used, which allowed direct access to the basal membrane for microelectrode impalement. When tissues were incubated in Cl(-)-free (SO2-4 based) medium, Vs averaged -85.8 mV. Elevation of serosal bath [HCO3-] at constant CO2 increased Vs; reduction of the [HCO3-] reduced Vs and increased the fractional resistance of the serosal membrane. When serosal bath HCO3- and CO2 were completely replaced, Vs was -44.8 mV. The serosal membrane was also depolarized on complete replacement of medium HCO3- and CO2 when bath pH was buffered with phosphate. 4,4'-Dinitro-2,2'-stilbene disulfonate (DNDS) and acetazolamide blocked the decline in Vs produced by lowering serosal medium [HCO3-]. Replacement of serosal Na+ reduced Vs 32.7 mV. DNDS blocked this response. It is concluded that a Na+-dependent, stilbene-sensitive HCO3- exit pathway resides in the basolateral membrane of the intestinal cells. Possibly there is also a parallel, conductive pathway for HCO3-.

Absence of transepithelial anion exchange by rabbit OMCD: evidence against reversal of cell polarity.

In the rabbit cortical collecting duct (CCD), Cl tracer crosses the epithelium predominantly via an anion exchange system that operates in either a Cl-Cl or Cl-HCO3 exchange mode. In the present study, we used the 36Cl lumen-to-bath rate coefficient (KCl, nm/s), a sensitive measurement of CCD transepithelial anion transport, to investigate the nature of Cl transport in the medullary collecting duct dissected from inner stripe, outer medulla (OMCD). The KCl in OMCD perfused and bathed in HCO3-Ringer solution was low (46.2 +/- 8.5 nm/s) and similar to that value observed in the CCD when anion exchange is inhibited and Cl permeates the epithelium by diffusion. Unlike KCl in CCD, KCl in OMCD was not stimulated by adenosine 3',5'-cyclic monophosphate (cAMP). OMCD KCl was not altered by bath Cl and/or HCO3 removal, demonstrating the absence of transepithelial Cl-Cl and Cl-HCO3 exchange. To test the hypothesis that metabolic alkalosis could reverse the polarity of intercalated cells and thus induce an apical Cl-HCO3 exchanger in H+-secreting OMCD cells, we measured KCl in OMCD from rabbits made alkalotic by deoxycorticosterone and furosemide. Although the base-line KCl was slightly higher than in OMCD from control rabbits, the value was still far lower than the KCl under comparable conditions in CCD. Moreover, KCl in OMCD from alkalotic rabbits was unchanged by cAMP, or by sequential removal of bath HCO3 and Cl. Immunocytochemistry using peanut lectin and a monoclonal antibody to-erythrocyte band 3 failed to reveal any evidence for alkalosis-induced reversal of either CCD or OMCD intercalated cell polarity.(ABSTRACT TRUNCATED AT 250 WORDS)

Basolateral membrane H/OH/HCO3 transport in the rat cortical thick ascending limb. Evidence for an electrogenic Na/HCO3 cotransporter in parallel with a Na/H antiporter.

Mechanisms involved in basolateral H/OH/HCO3 transport in the in vitro microperfused rat cortical thick ascending limb were examined by the microfluorometric determination of cell pH using (2',7')-bis-(carboxyethyl)-(5,6)-carboxyfluorescein. The mean cell pH in this segment perfused with 147 mM sodium and 25 mM HCO3 at pH 7.4 was 7.13 +/- 0.02 (n = 30). Lowering bath HCO3 from 25 to 5 mM (constant PCO2 of 40 mmHg) acidified the cells by 0.31 +/- 0.02 pH units at a rate of 0.56 +/- 0.08 pH units/min. Removal of bath sodium acidified the cells by 0.28 +/- 0.03 pH units at a rate of 0.33 +/- 0.04 pH units/min. The cell acidification was stilbene inhibitable and independent of chloride. There was no effect of bath sodium removal on cell pH in the absence of CO2/HCO3. Depolarization of the basolateral membrane (step increase in bath potassium) independent of the presence of chloride. Cell acidification induced by bath sodium removal persisted when the basolateral membrane was voltage clamped by high potassium/valinomycin. Although these results are consistent with a Na/(HCO3)n greater than 1 cotransporter, a Na/H antiporter was also suggested: 1 mM bath amiloride inhibited the cell pH defense against an acid load (rapid ammonia washout), both in the presence and absence of CO2/HCO3, and inhibited the cell acidification induced by bath sodium reduction from 50 to 0 mM. In conclusion, an electrogenic Na/(HCO3)n greater than 1 cotransporter in parallel with a Na/H antiporter exist on the basolateral membrane of the rat cortical thick ascending limb.

Properties of the luminal membrane of isolated perfused rat pancreatic ducts

The aim of the present study was to investigate by what transport mechanism does HCO-3 cross the luminal membrane of pancreatic duct cells, and how do the cells respond to stimulation with dibutyryl cyclic AMP (db-cAMP). For this purpose a newly developed preparation of isolated and perfused intra- and interlobular ducts of rat pancreas was used. Responses of the epithelium to inhibitors and agonists were monitored by electrophysiological techniques. Addition of HCO-3/CO2 to the bath side of nonstimulated ducts depolarized the PD across the basolateral membrane (PDbl) by about 9 mV, as also observed in a previous study [21]. This HCO-3 effect was abolished by Cl- channel blockers or SITS infused into the lumen of the duct: i.e. 5-nitro-2-(3-phenylpropylamino)-benzoic acid (NPPB, 10(-5) M) hyperpolarized PDbl by 8.2 +/- 1.6 mV (n = 13); 3',5-dichlorodiphenylamine-2-carboxylic acid (DCl-DPC, 10(-5) M) hyperpolarized PDbl by 10.3 +/- 1.7 mV (n = 10); and SITS hyperpolarized PDbl by 7.8 +/- 0.9 mV (n = 4). Stimulation of the ducts with db-cAMP in the presence of bath HCO-3/CO2 resulted in depolarization of PDbl, the ductal lumen became more negative and the fractional resistance of the luminal membrane decreased. Together with forskolin (10(-6) M), db-cAMP (10(-4) M) caused a fast depolarization of PDbl by 33.8 +/- 2.5 mV (n = 6). When db-cAMP (5 x 10(-4) M) was given alone in the presence of bath HCO-3/CO2, PDbl depolarized by 25.3 +/- 4.2 mV (n = 10).(ABSTRACT TRUNCATED AT 250 WORDS)

Electrophysiological study of transport systems in isolated perfused pancreatic ducts: properties of the basolateral membrane.

In order to study the mechanism of pancreatic HCO3- transport, a perfused preparation of isolated intra- and interlobular ducts (i.d. 20-40 microns) of rat pancreas was developed. Responses of the epithelium to changes in the bath ionic concentration and to addition of transport inhibitors was monitored by electrophysiological techniques. In this report some properties of the basolateral membrane of pancreatic duct cells are described. The transepithelial potential difference (PDte) in ducts bathed in HCO3(-)-free and HCO3(-)-containing solution was -0.8 and -2.6 mV, respectively. The equivalent short circuit current (Isc) under similar conditions was 26 and 50 microA . cm-2. The specific transepithelial resistance (Rte) was 88 omega cm2. In control solutions the PD across the basolateral membrane (PDbl) was -63 +/- 1 mV (n = 314). Ouabain (3 mmol/l) depolarized PDbl by 4.8 +/- 1.1 mV (n = 6) within less than 10 s. When the bath K+ concentration was increased from 5 to 20 mmol/l, PDbl depolarized by 15.9 +/- 0.9 mV (n = 50). The same K+ concentration step had no effect on PDbl if the ducts were exposed to Ba2+, a K+ channel blocker. Application of Ba2+ (1 mmol/l) alone depolarized PDbl by 26.4 +/- 1.4 mV (n = 19), while another K+ channel blocker TEA+ (50 mmol/l) depolarized PDbl only by 7.7 +/- 2.0 mV (n = 9). Addition of amiloride (1 mmol/l) to the bath caused 3-4 mV depolarization of PDbl. Furosemide (0.1 mmol/l) and SITS (0.1 mmol/l) had no effect on PDbl. An increase in the bath HCO3- concentration from 0 to 25 mmol/l produced fast and sustained depolarization of PDbl by 8.5 +/- 1.0 mV (n = 149). It was investigated whether the effect of HCO3- was due to a Na+-dependent transport mechanism on the basolateral membrane, where the ion complex transferred into the cell would be positively charged, or whether it was due to decreased K+ conductance caused by lowered intracellular pH. Experiments showed that the HCO3- effect was present even when the bath Na+ concentration was reduced to a nominal value of 0 mmol/l. Similarly, the HCO3- effect remained unchanged after Ba2+ (5 mmol/l) was added to the bath. The results indicate that on the basolateral membrane of duct cells there is a ouabain sensitive (Na+ + K+)-ATPase, a Ba2+ sensitive K+ conductance and an amiloride sensitive Na+/H+ antiport. The HCO3- effect on PDbl is most likely due to rheogenic anion exit across the luminal membrane.

Axial heterogeneity of sodium-bicarbonate cotransport in proximal straight tubule of rabbit kidney.

Intracellular microelectrodes were used to investigate rheogenic Na+ (HCO3-)n cotransport in different segments of isolated proximal straight tubule (PST) of rabbit kidney. In the first portion (S2 segment) the peritubular cell membrane potential Vb averaged -46.0, SE +/- 1.3 mV (n = 20), while in terminal portion (S3 segment) it averaged -68.3, SE +/- 2.5 mV (n = 10). This difference may reflect different modes of anion permeation across the peritubular cell membrane. In S2 segments, sudden 10:1 reduction of bath HCO3- concentration caused a fast transient cell depolarization, delta Vb = -45.8, SE +/- 1.2 mV (n = 33) as expected from the presence of Na+ (HCO3-)n cotransport. As the puncture site moved further distally, delta Vb declined and gradually changed its time course by superposition of a slower secondary depolarization. In this region the transient cell depolarization could be recuperated by inhibiting the peritubular K+ conductance with Ba2+ (1 mmol/l). In S3 segments, however, the HCO3(-)-dependent transient cell depolarization was completely lost both in the absence and presence of Ba2+. In addition, sudden reduction of bath Na+ concentration did not acidify the cell, as it did in the S2 segment. The data indicate that the expression of Na+ (HCO3-)n cotransport in the peritubular cell membrane gradually diminishes towards the end of the S2 segment and is lost in the S3 segment.

Mechanism of bicarbonate exit across basolateral membrane of rabbit proximal straight tubule.

To clarify the mechanism(s) of HCO3- (or related base) transport across the basolateral membrane, rabbit proximal straight tubules were perfused in vitro, and intracellular pH (pHi) and Na+ activity (aiNa) were measured by double-barreled ion-selective microelectrodes. Lowering bath HCO3- from 25 to 5 mM at constant PCO2 depolarized basolateral membrane potential (Vbl), and reduced pHi. Most of these changes were inhibited by adding 1 mM 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid (SITS) to the bath. Total replacement of bath Na+ with choline also depolarized Vbl and reduced pHi, and these changes were also inhibited by SITS. Reduction in aiNa was observed when bath HCO3- was lowered. Taken together, these findings suggest that HCO3- exists the basolateral membrane with Na+ and negative charge. Calculation of the electrochemical driving forces suggests that the stoichiometry of HCO3-/Na+ must be larger than two for maintaining HCO3- efflux. Total replacement of bath Cl- with isethionate depolarized Vbl gradually and increased pHi slightly, implying the existence of a Cl(-)-related HCO3- exit mechanism. The rate of decrease in pHi induced by lowering bath HCO3- was slightly reduced (20%) by the absence of bath Cl-. Therefore, the importance of Cl(-)-related HCO3- transport is small relative to total basolateral HCO3- exit. Accordingly, these data suggest that most of HCO3- exits the basolateral membrane through the rheogenic Na+/HCO3- cotransport mechanism with a stoichiometry of HCO3-/Na+ of more than two.

Bicarbonate-dependent chloride absorption in small intestine: ion fluxes and intracellular chloride activities.

Proximal, stripped segments of small intestine from the urodeleAmphiuma were short-circuited in media containing Na+, Cl− and HCO 3 − . Under these conditions there was a large net absorption of Cl−, a small net absorption of Na+ and a residual flux (J Net R ) consistent with HCO 3 − secretion. Net Cl− absorption correlated with the short-circuit current (I sc); net Na+ absorption correlated negatively withJ Net R . Acetazolamide eliminated theI sc, lowered Cl− absorption by 50%, and reduced net Na+ absorption without alteringJ Net R . Benzolamide inhibited theI sc without alteringJ Net R . Benzolamide inhibited theI sc more rapidly when applied on the mucosal surface. Replacement of Na+ or HCO 3 − (and CO2) in the media eliminated theI sc, net Cl− absorption and the residual flux. Likewise, inclusion of the stilbene SITS in the serosal media eliminated theI sc, net Cl− absorption and the residual flux. The cytoplasmic activity of Cl− (a ) was determined with single and double-barreled microelectrodes. Thea of villus absorptive cells in normal media was 21.0mm and in excess of that expected on the basis of electrochemical equilibrium of Cl− at the mucosal membrane. Active Cl− accumulation was also observed in the presence of acetazolamide but was eliminated upon replacement of media Na+ with choline. The mucosal membrane potential was depolarized upon replacement of media Na+. It is concluded that Cl− is actively absorbed into intestinal cells ofAmphiuma by an electrogenic process located in the mucosal membrane. Depending on the level of intracellular HCO 3 − , accumulated Cl− may diffuse passively back into the mucosal media or undergo exchange with bath HCO 3 − at the serosal membrane.