Carbachol increases Na+-HCO3− cotransport activity in murine colonic crypts in a M3−, Ca2+/calmodulin-, and PKC-dependent manner

The Na+-HCO3− cotransporter (NBC) mediates HCO3− import into the colonocyte via its pNBC1 isoform. Whereas renal kNBC1 is inhibited by increased cAMP levels, pNBC1 is stimulated. Cholinergic stimulation activates renal NBC, but the effect on intestinal NBC is unknown. Therefore, crypts were isolated from the murine proximal colon by Ca2+ chelation and loaded with the pH-sensitive dye 2′,7′-bis-carboxyethyl-5,6-carboxyfluorescein. Na+-HCO3− cotransport activity was calculated from the dimethylamiloride-insensitive (500 μM) intracellular pH recovery from an acid load in the presence of CO2-HCO3− and the intracellular buffering capacity. Carbachol strongly increased Na+-HCO3− cotransport activity compared with control rates. Ca2+ chelation with BAPTA-AM, blockade of the M3 subtype of muscarinergic receptors with 4-diphenylacetoxy- N-methylpiperidine methiodide, and inhibition of Ca2+/calmodulin kinase II with KN-62 all caused significant inhibition of the carbachol-induced NBC activity increase. Furthermore, PKC inhibition with Gö-6976 and Gö-6850 significantly reduced the carbachol effect, which may be related to the unique NH2-terminal consensus site for PKC-dependent phosphorylation of pNBC1. We conclude that NBC in the murine colon is thus activated by carbachol, consistent with its presumed function as an anion uptake pathway during intestinal anion secretion, but that the signal transductions pathways are distinct from those involved in the cholinergic activation of renal NBC1.

Regulation of intracellular pH in crypt cells from rabbit distal colon

H+ secretory mechanisms and intrinsic intracellular buffering capacity were studied in crypt cells from rabbit distal colon. To this end crypts of Lieberkuhn were isolated by microdissection, and intracellular pH (pHi) was measured using digital imaging fluorescence microscopy and the pH-sensitive fluorescent dye 2',7'-bis(2-carboxyethyl)- 5(6)-carboxyfluorescein. In the absence of HCO(3-)-CO2 and presence of Na+, resting pHi was 7.51 +/- 0.04 (n = 237/23, cells/crypts). However, 6 min after superfusion with a solution containing zero Na+, 1 x 10(5) M Sch-28080 and 5 x 10(-8) M bafilomycin A1, pHi in cells at the bottom of the crypts was significantly reduced, whereas pHi in cells at the top of the crypts remained unchanged. The intrinsic buffering capacity of cells from the middle to the top portion of crypts was significantly higher in the pHi range 7.2-7.6 than of cells at the bottom of the crypt. H+ secretion after an NH(4+)-NH3 pulse amounted to 245 +/- 53 microM/s (n = 73/7) at pHi 7.1 and was largely Na+ dependent and ethylisopropylamiloride sensitive. The Na(+)-independent recovery of pHi after an acid load was insensitive to Sch-28080 and bafilomycin A1. In conclusion, pHi in colonic crypt cells is regulated through Na+/H+ exchange activity in the absence of HCO3-. In addition, intracellular buffering capacity varied with the position along the crypt axis, whereas Na+/H+ exchange activity and pHi did not.

Intracellular pH recovery during respiratory acidosis in perfused hearts

Na(+)-H+ exchange and Na(+)-dependent HCO3- influx both contribute to recovery of intracellular pH (pHi) after an acidosis induced by using the NH4Cl prepulse technique in mammalian and avian cardiac tissue. We have investigated the relative contributions of these mechanisms to pHi recovery during respiratory acidosis in the Langendorff-perfused ferret heart with and without correction of extracellular pH (pHo). pHi was measured from the chemical shift of the exogenous 31P nuclear magnetic resonance pH indicator 2-deoxy-D-glucose 6-phosphate. Intrinsic intracellular buffering capacity, calculated from the change in intracellular HCO3- concentration after a change in CO2, was reduced from approximately 33 (no inhibitors of acid extrusion present) to 19 +/- 5 mM when H+ extrusion during the acid loading phase was inhibited. During respiratory acidosis (pHo approximately 6.95), the proton efflux rate (JH) calculated at pHi 6.85 was 0.30 +/- 0.04 mmol.l-1.min-1 (n = 9). When pHo was corrected by increasing external HCO3- concentration to 60 mM during respiratory acidosis (pHo approximately 7.33), JH was 1.11 +/- 0.11 mmol.l-1.min-1 (n = 7), and when pHo was partially corrected by the addition of 50 mM N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid to the perfusion solution (pHo approximately 7.1), JH was 0.64 +/- 0.08 mmol.l-1.min-1 (n = 6). In all three groups Na(+)-H+ exchange and HCO3- influx each contributed approximately 50% to acid-equivalent efflux.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of intracellular pH in the perfused heart by external HCO3- and Na(+)-H+ exchange

Both Na(+)-dependent HCO3- influx and the Na(+)-H+ antiport have been shown to contribute to recovery from intracellular acidosis in avian and mammalian cardiac tissue. We have investigated the participation of these mechanisms in the recovery of intracellular pH (pHi) after an acid load in the Langendorff-perfused ferret heart. pHi was measured from the phosphorus-31 nuclear magnetic resonance chemical shift of 2-deoxy-D-glucose 6-phosphate. Basal pHi was higher in HCO(3-)-buffered solution (7.05 +/- 0.01; n = 8) than in nominally HCO(3-)-free N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES) solution (6.98 +/- 0.02; n = 9). Addition of 5-(N-ethyl-N-isopropyl)amiloride (EIPA) caused a significant fall in pHi in HEPES solution (6.91 +/- 0.02; n = 5) but not in HCO3- solution (7.02 +/- 0.02; n = 5). Intrinsic intracellular buffering capacity in 0 Na(+)-HEPES solution was 37 +/- 2 mmol/l (n = 4), and additional buffering due to HCO(3-)-CO2 was approximately 13 mmol/l in HCO3- solution. After an intracellular acidosis induced by an NH4Cl prepulse, the proton efflux rate (JH) at pHi 6.90 was 0.5 +/- 0.2 nmol.l-1.min-1 (n = 14) in HEPES solution and 1.2 +/- 0.4 mmol.l-1.min-1 (n = 13) in HCO3- solution. The addition of 1 microM EIPA effectively blocked proton efflux in HEPES solution (JH < 0.1 mmol.l-1.min-1; n = 8), whereas it slowed pHi recovery in HCO3- solution (JH = 0.6 +/- 0.2 mmol.l-1.min-1; n = 9). There was no recovery of pHi in Na(+)-free HCO3- solution (JH < 0.1 mmol.l-1.min-1; n = 3). The Na(+)-H+ antiport and a mechanism requiring both external Na+ and HCO3- each contribute approximately 50% to proton efflux at pHi 6.90 during the recovery from intracellular acidosis in the isolated perfused mammalian heart.

Effects of osmotic stresses on isolated rat hepatocytes. II. Modulation of intracellular pH

To assess the roles of acid-base transport systems in cell volume regulation in rat hepatocytes, intracellular pH (pHi) was measured in subconfluent monolayers loaded with 2'-7'-bis(carboxyethyl)-5,6-carboxyfluorescein (BCECF) after exposure to hypotonic and relative hypertonic media, interventions that stimulate regulatory volume decrease (RVD) and increase (RVI), respectively. During RVD, pHi decreased from 6.98 +/- 0.11 to 6.85 +/- 0.08 in the absence of HCO3- and from 7.26 +/- 0.10 to 7.19 +/- 0.06 in its presence. Omission of Na+ or addition of 1 mM amiloride prevented the decline in pHi. Acute withdrawal or replacement of Na+ in hypotonic medium resulted in a slower rate of fall or recovery in pHi, respectively, than when the same maneuvers were carried out in isotonic medium. In contrast, during RVI, pHi increased from 6.86 +/- 0.11 to 7.15 +/- 0.15 in the absence of HCO3-, a rise in pHi that was also completely abolished by Na+ removal or by 1 mM amiloride. In the presence of HCO3-, the rise in pHi was less marked than in its absence, although net acid efflux was greater because of a greater intracellular buffering capacity. Cl- removal in the presence of HCO3- had no effect on the change in pHi during either RVD or RVI. Perfusion with 0.5 mM 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) during RVD lowered pHi further and accentuated the subsequent pHi rise seen after the return to isotonic medium. These data suggest that Na(+)-H+ exchange in rat hepatocytes is downregulated during RVD and activated during RVI. Cl(-)-HCO3- exchange does not appear to be involved in hepatocyte volume regulation.

Na+-H+ and Cl(-)-OH-(HCO3-) exchange in gastric glands

The pH-sensitive, fluorescent, cytoplasmic-trapped dye 2,7-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF) has been used to measure intracellular (pHi) and pH electrode to measure extracellular pH (pHo) in suspensions of gastric glands isolated from rabbit stomachs. The fluorescence of BCECF-loaded glands was calibrated in terms of pHi by equilibrating pHo and pHi using ionophores or digitonin and titrating pHo to different values. An APPENDIX is included that covers details of dye calibration and interpretation of fluorescence signals. Glands incubated in NaCl Ringer solution had pHi 7.11. Na+-free Ringer solution caused pHi to decrease reversibly to 6.80. Na+-dependent alkalinization of pHi followed a similar time course to the acidification of pHo. These changes were blocked by 1 mM amiloride. When gland cells were acidified (using two different techniques) realkalinization was completely Na+ dependent but was independent of the presence of Cl-; also, neither high extracellular K+ concentration ([K+]o) nor high [K+]o plus 10(-5) M valinomycin affected the rates of Na+-dependent alkalinization. A neutral Na+-H+ exchanger was implicated. Glands also exhibited Cl(-)-dependent changes of pHi that were blocked by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (2 X 10(-4) M). A Cl(-)-OH-(HCO3-) exchanger was indicated. Other studies showed that intracellular buffering capacity was approximately 45 mM (pH-1) and that the apparent proton conductance of gland cell membranes was small.

Control of intracellular pH. Predominant role of oxidative metabolism, not proton transport, in the eukaryotic microorganism Neurospora.

Recessed-tip microelectrodes were used to measure internal pH (pHi) in the fungus Neurospora, and to examine the response of pHi to several kinds of stress: changes of extracellular pH (pHo), inhibition of the principal proton pump in the plasma membrane, and inhibition of respiration. Under control conditions, at pHo = 5.8, pHi in Neurospora is 7.19 +/- 0.04. Changes of pHo between 3.9 and 9.3 affect pHi linearly but with a slope of only approximately 0.1 unit pHi per unit pHo, stable pHi being reached within 3 min of changed pHo. Despite a postulated high passive permeability of the Neurospora membrane to protons (Slayman, 1970), neither active nor passive H+ transport appears critical to pHi because (alpha) specific inhibition of the proton pump by orthovanadate has little effect on pHi, and (b) cytoplasmic acidification produced by respiratory blockade is unaffected by the size or direction of proton gradient. To convert measured changes in pHi into net proton fluxes, intracellular buffering capacity (beta i) was measured by the weak acid/weak base technique. At pHi = 7.2, beta i was (-) 35 mmol H+ (liter cell water)-1 (pH unit)-1, but beta i increased substantially in both the acid and alkaline directions, which suggests that amino acid side chains are the principal source of buffer.