Contributions of cellular leak pathways to net NaHCO3 and NaCl absorption.

Proton and formic acid permeabilities were measured in the in vivo microperfused rat proximal convoluted tubule by examining the effect on intracellular pH when [H] and/or [formic acid] were rapidly changed in the luminal or peritubular fluids. Apical and basolateral membrane H permeabilities were 0.52 +/- 0.07 and 0.67 +/- 0.18 cm/s, respectively. Using these permeabilities we calculate that proton backleak from the luminal fluid to cell does not contribute significantly to net proton secretion in the early proximal tubule, but may contribute in the late proximal tubule. Apical and basolateral membrane formic acid permeabilities measured at extracellular pH 6.62 were 4.6 +/- 0.5 X 10(-2) and 6.8 +/- 1.5 X 10(-2) cm/s, respectively. Control studies demonstrated that the formic acid permeabilities were not underestimated by either the simultaneous movement of formate into the cell or the efflux of formic acid across the opposite membrane. The measured apical membrane formic acid permeability is too small to support all of transcellular NaCl absorption in the rat by a mechanism that involves Na/H-Cl/formate transporters operating in parallel with formic acid nonionic diffusion.

Regulation of cell pH by ambient bicarbonate, carbon dioxide tension, and pH in the rabbit proximal convoluted tubule.

UNLABELLED: To study the regulation of cell pH by ambient pH, carbon dioxide tension (PCO2), and bicarbonate (HCO3), cell pH was measured in the isolated, in vitro microperfused rabbit proximal convoluted tubule using the fluorescent dye (2',7')-bis-(carboxyethyl)-(5,6)-carboxyfluorescein. For the same changes in external pH, changes in [HCO3] and PCO2 affected cell pH similarly ([HCO3]: pHi/pHe = 0.67, PCO2: pHi/pHe = 0.64, NS). Isohydric changes in extracellular [HCO3] and PCO2 did not change cell pH significantly. Changes in peritubular [HCO3] elicited larger changes in cell pH than changes in luminal [HCO3], which were enhanced by peritubular 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonate (SITS). The cell pH defense against acute increases and decreases in PCO2 was inhibited by sodium, but not by chloride removal. Peritubular SITS inhibited the cell pH defense against increases and decreases of PCO2, whereas luminal amiloride inhibited cell pH defense against increases in PCO2. CONCLUSIONS: (a) Steady-state cell pH changes in response to changes in extracellular [HCO3] and PCO2 are quantitatively similar for a given change in extracellular pH; (b) the rate of the basolateral Na/(HCO3)3 cotransporter is a more important determinant of cell pH than the rate of the apical membrane mechanism(s); (c) cell pH defense against acute changes in PCO2 depends on the basolateral Na/(HCO3)3 cotransporter (acid and alkaline loads) and the luminal Na/H antiporter (acid loads).

Bicarbonate secretion and chloride absorption by rabbit cortical collecting ducts. Role of chloride/bicarbonate exchange.

Cortical collecting ducts (CCD) from rabbits treated with deoxycorticosterone (DOC) actively secrete bicarbonate at high rates. To investigate the mechanism of bicarbonate secretion, we measured bicarbonate and chloride transport in CCD from rabbits treated with DOC for 9-24 d. Removal of chloride (replaced with gluconate) from both perfusate and bath inhibited bicarbonate secretion without changing transepithelial voltage. Removal of chloride only from the bath increased bicarbonate secretion, while removal of chloride only from the perfusate inhibited secretion. In contrast to the effect of removing chloride, removal of sodium from both the perfusate and bath (replacement with N-methyl-D-glucamine) did not change the rate of bicarbonate secretion. The rate of bicarbonate secretion equaled the rate of chloride absorption in tubules bathed with 0.1 mM ouabain to inhibit any cation-dependent chloride transport. Under these conditions, chloride absorption occurred against an electrochemical gradient. Removal of bicarbonate from both the perfusate and bath inhibited chloride absorption. Removal of bicarbonate only from the bath inhibited chloride absorption, while removal of bicarbonate from the lumen stimulated chloride absorption. We conclude that CCD from DOC-treated rabbits actively secrete bicarbonate and actively absorb chloride by an electroneutral mechanism involving 1:1 chloride/bicarbonate exchange. The process is independent of sodium.

Chronic metabolic acidosis causes an adaptation in the apical membrane Na/H antiporter and basolateral membrane Na(HCO3)3 symporter in the rat proximal convoluted tubule.

The effect of chronic dietary acid on the apical membrane Na/H antiporter and basolateral membrane Na(HCO3)3 symporter was examined in the in vivo microperfused rat proximal tubule. Transporter activity was assayed with the epifluorescent measurement of cell pH using the intracellular, pH-sensitive fluorescent dye, (2'7')-bis(carboxyethyl)-(5,6)-carboxy-fluorescein (BCECF). BCECF was calibrated intracellularly, demonstrating similar pH-sensitivity of the dye in control and acidotic animals. In subsequent studies, lumen and peritubular capillaries were perfused to examine Na/H and Na(HCO3)3 transporter activity in the absence of contact with native fluid. The initial rate of change in cell pH (dpHi/dt) was 97, 50, and 44% faster in tubules from acidotic animals when peritubular [HCO3] was changed from 25 to 10 mM in the presence or absence of chloride, or peritubular [Na] was changed from 147 to 50 mM, respectively. dpHi/dt was 57% faster in tubules from acidotic animals when luminal [Na] was changed from 152 to 0 mM. Buffer capacities, measured using NH3/NH+4 addition, were similar in the two groups. The results demonstrate that chronic metabolic acidosis causes an adaptation in the intrinsic properties of both the apical membrane Na/H antiporter and basolateral membrane Na(HCO3)3 symporter.

Bicarbonate, not CO2, is the species required for the stimulation of Photosystem II electron transport.

Evidence is presented that the bicarbonate ion (HCO3-), not CO2, H2CO3 or CO32-, is the species that stimulates electron transport in Photosystem II from spinach (Spinacia oleracea). Advantage was taken of the pH dependence of the ratio of HCO3- to CO2 at equilibrium in order to vary effectively the concentration of one species while holding the other constant. The Hill reaction was stimulated in direct proportion with the equilibrium HCO3- concentration, but it was independent of the equilibrium CO2 concentration. The other two carbonic species, H2CO3 and CO32-, are also shown to have no direct involvement. It is suggested that HCO3- is the species which binds to the effector site.

Potential difference responses due to K+, Na+ and Cl- changes in bullfrog antrum with and without HCO3-.

The effect of changing [K+], [Na+] and [Cl-] in nutrient solution was studied in bullfrog antrum with and without HCO3- in nutrient. In 25 mM HCO3- (95% O2/5% CO2) and in zero HCO3- (100% O2), nutrient pH was maintained at 7.3. Changing from 4 to 40 mM K+ or from 81 to 8.1 mM Cl- gave a decrease 10 min later in transmucosal PD (nutrient became more negative)--a normal response. These responses were less in zero than in 25 mM HCO3-. A decrease from 102 to 8 mM Na+ decreased PD (anomalous response of electrogenic NaCl symport). This effect was attenuated or eliminated in zero HCO3-. In contrast, change from 4 to 40 mM K+ gave initial anomalous PD response and change from 102 to 8 mM Na+, initial normal PD response with either zero or 25 mM HCO3-. Both responses were associated with (Na+ + K+)-ATPase pump and were greater in zero than in 25 mM HCO3-. Initial PD increases in zero HCO3- are explained as due to increase in the resistance of passive conductance and/or NaCl symport pathways. Thus, removal of HCO3- modifies conductance pathways of nutrient membrane.

Absence of a bicarbonate-depletion effect in electron transfer between quinones in chromatophores and reaction centers of Rhodobacter sphaeroides.

Higher plants, algae, and cyanobacteria are known to require bicarbonate ions for electron flow from the first stable electron acceptor quinone QA to the second electron acceptor quinone QB, and to the intersystem quinone pool. It has been suggested that in Photosystem II of oxygenic photosynthesis, bicarbonate ion functions to maintain the reaction center in a proper conformation and, perhaps, to provide the protons needed to stabilize the semiquinone (QB-). In this paper, we show that bicarbonate ions do not influence the electron flow, from the quinone QA to QB and beyond, in the photosynthetic bacterium Rhodobacter sphaeroides. No measurable effect of bicarbonate depletion, obtained by competition with formate, was observed on cytochrome b-561 reduction in chromatophores; on the flash-dependent oscillation of semiquinone formation in reaction centers; on electron transfer from QA- to QB; or on either the fast or slow recovery of the oxidized primary donor (P+) which reflects the P+QA- ----PQA or the P+QB- ----PQB reaction. The lack of an observed effect in Rhodobacter sphaeroides in contrast to the effect seen in Photosystem II is suggested to be due to the amino-acid sequence differences between the reaction centers of the two systems.

Evidence for HCO3- conductance pathways in nutrient membrane of bullfrog antrum.

The effect of changing the nutrient HCO3- concentration on potential difference (PD) and resistance in bullfrog antrum bathing in CI- media was determined. Changes in HCO3- concentration were from 25 mM to several lower concentrations and back to 25 mM. A plot of /delta PD/ versus log [HCO3-] gave a linear relation for changes of HCO3- concentration from 25 down to 3.1 mM and back to 25 mM but deviated to some extent for changes to 1.6 mM. In these experiments, changes from higher to lower HCO3- concentrations gave a less rapid initial PD response than those in the reverse direction. This result eliminated H+ conductance pathways as being predominant. Experiments were done in which in the first part changes were made in nutrient solution from 5 percent CO2 and 25 mM HCO3- to 0.6 percent CO2 and 3 mM HCO3- and in the second part the same changes with a simultaneous changes of secretory solution from 5 percent to 10 percent CO2. The magnitude of PD decrease was greater by 4.5 mV in the second part. This result indicated that HCO3- conductance pathways rather than OH- conductance pathways are predominated . There was no evidence of HCO3-, OH-, and H+ conductance pathways in secretory membranes.

Stoichiometry and ion dependencies of the intracellular-pH-regulating mechanism in squid giant axons.

The ion transport system responsible for intracellular pH (pHi) regulation in squid giant axons was examined in experiments with pH-sensitive microelectrodes and isotopic fluxes of Na+ and Cl-. In one study, axons were acid-loaded and the rate of the subsequent pHi recovery was used to calculate the acid extrusion rate. There was an absolute dependence of acid extrusion on external Na+, external HCO-3 (at constant pH), and internal Cl-. Furthermore, the dependence of the acid extrusion rate on each of these three parameters was described by Michaelis-Menten kinetics. Acid extrusion was stimulated by an acid pHi, required internal ATP, and was blocked by external 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonate (SITS). Under a standard set of conditions (i.e., [HCO-3]o = 12 mM, pHo = 8.00, [Na+]o = 425 mM, [Cl-]i = 150 mM, [ATP]i = 4 mM, pHi = 6.5, and 16 degrees C), the mean acid extrusion rate was 7.5 pmol X cm-2 X s-1. In a second study under the above standard conditions, the unidirectional Na+ efflux (measured with 22Na) mediated by the pHi-regulating system was found to be approximately 0, whereas the mean influx was about 3.4 pmol X cm-2 X s-1. This net influx required external HCO-3, internal Cl-, and acid pHi, internal ATP, and was blocked by SITS. In the final series of experiments under the above standard conditions, the unidirectional Cl- influx (measured with 36Cl) mediated by the pHi-regulating system was found to be approximately 0, whereas the mean efflux was approximately 3.9 pmol X cm-2 X s-1. This net efflux required external HCO-3, external Na+, an acid pHi, internal ATP, and was blocked by SITS. We conclude that the pHi-regulating system mediates the obligate net influx of HCO-3 (or equivalent species) and Na+ and the net efflux of Cl- in the stoichiometry of 2:1:1. The transport system is stimulated by intracellular acid loads, requires ATP, and is blocked by SITS.

Basolateral membrane Cl/HCO3 exchange in the rat proximal convoluted tubule. Na-dependent and -independent modes.

To examine whether Cl-coupled HCO3 transport mechanisms were present on the basolateral membrane of the mammalian proximal tubule, cell pH was measured in the microperfused rat proximal convoluted tubule using the pH-sensitive, intracellularly trapped fluorescent dye (2',7')-bis(carboxyethyl)-(5,6)-carboxyfluorescein. Increasing the peritubular Cl concentration from 0 to 128.6 meq/liter caused cell pH to decrease from 7.34 +/- 0.04 to 7.21 +/- 0.04 (p less than 0.001). With more acid extracellular fluid (pH 6.62), a similar increase in the peritubular Cl concentration caused cell pH to decrease by a similar amount from 6.97 +/- 0.04 to 6.84 +/- 0.05 (p less than 0.001). This effect was blocked by 1 mM SITS. To examine the Na dependence of Cl/HCO3 exchange, the above studies were repeated in the absence of luminal and peritubular Na. In alkaline Na-free solutions, peritubular Cl addition caused cell pH to decrease from 7.57 +/- 0.06 to 7.53 +/- 0.06 (p less than 0.025); in acid Na-free solutions, peritubular Cl addition caused cell pH to decrease from 7.21 +/- 0.04 to 7.19 +/- 0.04 (p less than 0.05). The effect of Cl on cell pH was smaller in the absence of luminal and peritubular Na than in its presence. To examine whether the previously described Na/(HCO3)n greater than 1 cotransporter was coupled to or dependent on Cl, the effect of lowering the peritubular Na concentration from 147 to 25 meq/liter was examined in the absence of ambient Cl. Cell pH decreased from 7.28 +/- 0.03 to 7.08 +/- 0.03, a response similar to that observed previously in the presence of Cl. The results demonstrate that Cl/HCO3 (or Cl/OH) exchange is present on the basolateral membrane. Most of Cl/HCO3 exchange is dependent on the presence of Na and may be coupled to it. The previously described Na/(HCO3)n greater than 1 cotransporter is the major basolateral membrane pathway for the coupling of Na and HCO3 and is not coupled to Cl.

Basolateral membrane Na/base cotransport is dependent on CO2/HCO3 in the proximal convoluted tubule.

The mechanism of basolateral membrane base transport was examined in the in vitro microperfused rabbit proximal convoluted tubule (PCT) in the absence and presence of ambient CO2/HCO3- by means of the microfluorometric measurement of cell pH. The buffer capacity of the cells measured using rapid NH3 washout was 42.8 +/- 5.6 mmol.liter-1.pH unit-1 in the absence and 84.6 +/- 7.3 mmol.liter-1.pH unit-1 in the presence of CO2/HCO3-. In the presence of CO2/HCO3-, lowering peritubular pH from 7.4 to 6.8 acidified the cell by 0.30 pH units and lowering peritubular Na from 147 to 0 mM acidified the cell by 0.25 pH units. Both effects were inhibited by peritubular 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonate (SITS). In the absence of exogenous CO2/HCO3-, lowering peritubular pH from 7.4 to 6.8 acidified the cell by 0.25 pH units and lowering peritubular Na from 147 to 0 mM decreased cell pH by 0.20 pH units. Lowering bath pH from 7.4 to 6.8 induced a proton flux of 643 +/- 51 pmol.mm-1.min-1 in the presence of exogenous CO2/HCO3- and 223 +/- 27 pmol.mm-1.min-1 in its absence. Lowering bath Na from 147 to 0 mM induced proton fluxes of 596 +/- 77 pmol.mm-1.min-1 in its absence. The cell acidification induced by lowering bath pH or bath Na in the absence of CO2/HCO3- was inhibited by peritubular SITS or by acetazolamide, whereas peritubular amiloride had no effect. In the absence of exogenous CO2/HCO3-, cyanide blocked the cell acidification induced by bath Na removal, but was without effect in the presence of exogenous CO2/HCO3-. We reached the following conclusions. (a) The basolateral Na/base n greater than 1 cotransporter in the rabbit PCT has an absolute requirement for CO2/HCO3-. (b) In spite of this CO2 dependence, in the absence of exogenous CO2/HCO3-, metabolically produced CO2/HCO3- is sufficient to keep the transporter running at 30% of its control rate in the presence of ambient CO2/HCO3-. (c) There is no apparent amiloride-sensitive Na/H antiporter on the basolateral membrane of the rabbit PCT.

The influence of bicarbonate ions on the GABA-mimetic activity of ethylenediamine.

A study was performed to investigate the GABA-mimetic activity of ethylenediamine (EDA) and piperazine at mammalian gamma-aminobutyric acid (GABA) receptors using radioligand binding assays and in vitro isolated tissues. The potency of ethylenediamine and piperazine as inhibitors of the binding of GABA receptors to synaptic membranes from rat brain was measured in Tris-buffers and Krebs-Henseleit solution (KHS). The potency of ethylenediamine and piperazine at GABAA and ethylenediamine at GABAB receptors was raised if Krebs-Henseleit solution was used for the assay. Piperazine was inactive at GABAB receptors. The potency of the antagonist of GABAA receptors bicuculline methobromide, was also increased in Krebs-Henseleit when compared with Tris-citrate buffer. Of the ions present in Krebs-Henseleit, bicarbonate ions were responsible for the increase in the GABA-mimetic potency of ethylenediamine and piperazine. Addition of either NaHCO3 or KHCO3 (25 mM) to Tris-HCl buffer (for GABAA binding) or Tris-HCl plus 2.5 mM CaCl2 (for GABAB binding) yielded IC50 values similar to those measured in Krebs-Henseleit solution. Bicarbonate ions also enhanced the ability of ethylenediamine to potentiate the binding of [3H]diazepam to membranes from rat brain (raising both the potency of ethylenediamine and its maximum effect) in this system. In the absence of HCO-3 ions, ethylenediamine potentiated the binding of [3H]diazepam by raising the maximum binding capacity (Bmax) without changing the affinity (Kd) of the receptors. Potassium bicarbonate (25 mM) caused ethylenediamine to further potentiate the binding of [3H]diazepam by changing both Bmax and Kd.(ABSTRACT TRUNCATED AT 250 WORDS)

The role of bicarbonate ions and of adenosine 3',5'-monophosphate (cAMP) in chloride transport by epithelial cells of bullfrog small intestine.

In an HCO3-free medium, isolated segments of bullfrog small intestine, stripped of their external muscle layers, displayed a small, serosal positive PD that did not, on the average, differ significantly from zero. Similarly, in this medium, the mean values of Isc and of net Na+ and Cl- absorption under short-circuit conditions did not differ significantly from zero. External HCO3- (25 mM) induced a highly significant serosal negative PD and Isc and a large net absorption of Cl-. Net Cl- absorption exceeded Isc, i.e., there was a significant net flux, JR, which was consistent with a net secretion of HCO3-. The ratio of the internal Cl-activity of the absorptive cells (alpha Cli) to its equilibrium value was larger in the presence than in the absence of HCO3-. In the presence of HCO3-, cAMP, added to the serosal medium, reversed the serosal negative PD and Isc, and inhibited, though it did not completely abolish, net Cl- absorption. JR was unchanged; tissue Cl- and alpha Cli were reduced, and tissue Na+ decreased and tissue K+ increased. When HCO3- and Cl- were removed from the bathing medium, the electrical response of the tissue to cAMP, though greatly attenuated, was not completely abolished. Under these conditions, cAMP induced a significant net Na+ absorption. A model for ion transport in the absorptive cells of the small intestine is proposed that is consistent with these findings.

Regulation of intracellular chloride in bullfrog choroid plexus.

Intracellular Cl- activity (AiCl) of the bullfrog choroidal epithelium has been studied using double-barreled Cl(-)-selective microelectrodes. In bicarbonate-buffered saline, the brush-border membrane potential (VVC) was -43 mV, and AiCl was 24 mM which was twice the predicted equilibrium activity. The uphill Cl- accumulation required the presence of external Na+ and was inhibited by furosemide added to the basolateral side. Removal of HCO3- from the bath solution slightly increased AiCl. On addition of 3-isobutyl-1-methylxanthine (IBMX), VVC depolarized, and AiCl approached the equilibrium activity. It is concluded that net Cl- secretion by the choroidal epithelium is mediated by a furosemide-sensitive, Na+-coupled Cl- uptake mechanism at the basolateral border and a Cl- conductive pathway at the brush border membrane. The results suggest that intracellular cAMP either increases the Cl- conductance of the epithelial membranes and/or inhibits the NaCl co-transport mechanism.

Lowered levels of bicarbonate in seminal plasma cause the poor sperm motility in human infertile patients.

Both the adenylate cyclase activity and the motility of human sperm were stimulated by bicarbonate with the same concentration dependency. The correlation between bicarbonate levels in semen and the motility of sperm from the patients with male infertility was investigated. Bicarbonate in semen was found to originate mainly from the seminal vesicles, and a significant positive correlation was observed between bicarbonate levels and volume of semen. The motility of infertile sperm was also found to correlate positively to the seminal levels of bicarbonate. These results suggest that the lowered levels of bicarbonate in semen are at least in part responsible for the poor sperm motility in infertile patients, as a result of the failure in the activation of sperm adenylate cyclase.

[Current concepts in gastric ulcer pathogenesis (author's transl)]. / Aktuelle Konzepte der Ulkusentstehung im Magen.

Recent research has opened up new aspects in the pathogenesis of gastric ulcers. The central role of luminal acid remains unchallenged, although hypersecretion of acid is not necessarily a prerequisite factor in acute or chronic ulceration. A delicate balance is now known to exist between several protective mechanisms and this is essential in enabling the gastric mucosa to withstand the high H-ion gradient between lumen and surface cells. Apart from the role played by other protective mechanisms like mucosal permeability, alkaline secretion and secretory status, blood flow and intracellular buffering of influxing H+ seem to be the most important factors in maintaining the integrity of the gastric mucosa, because their absence always leads to ulceration. Chronic ulcer disease may, however, be dependent on a defect in the regeneration of the gastric mucosa, in addition to the lack of one or more protective mechanisms.

Pathogenetic mechanisms in experimental gastric stress ulceration.

The studies reviewed suggest that the presence of luminal acid is essential for acute gastric stress ulceration to occur and that acid promotes ulceration by diffusing into the mucosa in an ulcerogenic situation. Disruption of the mucosal barrier by the presence of e.g. intragastric bile salts, aspirin, or ethanol increases the hydrogen ion back diffusion, thereby increasing the susceptibility of the mucosa to ulceration. Such a disruption is presumably needed for development of ulcerations in species with a "tight" gastric mucosa, such as the dog, the pig and man, whereas in species with a "leaky" mucosa, such as the rabbit or rat, ulceration occurs even without these agents. However, the response of the mucosa to hydrogen ions is not uniform. Luminal acidities and rates of hydrogen ion back diffusion that are normally harmless may in certain situations cause severe damage to the mucosa. Thus, the ability of the mucosa to withstand the influxing hydrogen ions is as important as the absolute amount of hydrogen ions diffusing into the mucosa. If the rate of hydrogen ion back diffusion exceeds the ability of the mucosa to dispose of hydrogen ions, acidification of the mucosa occurs, with resultant breakdown of the tissue. The main factors modulating the response of the mucosa to hydrogen ions are availability of bicarbonate in the mucosa and the mucosal blood flow. Bicarbonate contributes to mucosal protection through secretion by the epithelium to form an "alkaline" buffer layer at the epithelial surface, which seems to act as a "firstline" defence mechanism against the influxing hydrogen ions.(ABSTRACT TRUNCATED AT 250 WORDS)