The Effect of Dehydration on the in vivo Acid-Base Status of the Blood in the Toad Bufo Viridis

1980 ◽  
Vol 88 (1) ◽  
pp. 403-406
Author(s):  
URI KATZ
Keyword(s):  
Acid Base ◽  
Bufo Viridis ◽  
Acid Base Status ◽  
Toad Bufo

The Effect of Salt Adaptation and Amiloride on the In Vivo Acid-Base Status of the Euryhaline Toad Bufo Viridis

1981 ◽  
Vol 93 (1) ◽  
pp. 93-99
Author(s):  
U. KATZ
Keyword(s):  
Tap Water ◽  
Salt Adaptation ◽  
Acid Base ◽  
Bufo Viridis ◽  
Acid Base Status ◽  
Simultaneous Decrease ◽  
Toad Bufo

1. The acid-base status of the blood of the toad Bufo viridis was studied during adaptation to high salinity and in tap water containing amiloride. 2. Both salt adaptation and immersion for 2-3 days in 5 x10−4 M amiloride in tap water resulted in a decrease in blood pH (from 7.720 ± 0.026 in tap water to 7.456±0.051 in 500 mOsm NaCl-adapted toads; mean ± S.E.), and a simultaneous decrease in the concentration of HCO3- (from 17.8 ±1.4 in tap water to 9.5±1.2 in salt-adapted toads). 3. In vitro determination of Na+/H+ exchange across the skin showed a 1:1 relation in skins from tap-water-adapted toads; this exchange was inhibited by amiloride. H+ secretion was abolished in skins from salt-adapted toads and the uptake of sodium was reduced.

scholarly journals Damage to the gastric epithelium activates cellular bicarbonate secretion via SLC26A9 Cl−/HCO3−exchange

2010 ◽  
Vol 299 (1) ◽  
pp. G255-G264 ◽  
Author(s):  
Elise S. Demitrack ◽  
Manoocher Soleimani ◽  
Marshall H. Montrose
Keyword(s):  
Interstitial Fluid ◽  
Gastric Epithelium ◽  
Acid Base ◽  
Surface Ph ◽  
Two Photon ◽  
Acid Base Status ◽  
Genetic Deletion ◽  
Knockout Animals ◽  
Tissue Compartments

Gastric surface pH (pHo) transiently increases in response to focal epithelial damage. The sources of that increase, either from paracellular leakage of interstitial fluid or transcellular acid/base fluxes, have not been determined. Using in vivo microscopy approaches we measured pHowith Cl-NERF, tissue permeability with intravenous fluorescent-dextrans to label interstitial fluid (paracellular leakage), and gastric epithelial intracellular pH (pHi) with SNARF-5F (cellular acid/base fluxes). In response to two-photon photodamage, we found that cell-impermeant dyes entered damaged cells from luminal or tissue compartments, suggesting a possible slow transcellular, but not paracellular, route for increased permeability after damage. Regarding cytosolic acid/base status, we found that damaged cells acidified (6.63 ± 0.03) after photodamage, compared with healthy surface cells both near (7.12 ± 0.06) and far (7.07 ± 0.04) from damage ( P < 0.05). This damaged cell acidification was further attenuated with 20 μM intravenous EIPA (6.34 ± 0.05, P < 0.05) but unchanged by addition of 0.5 mM luminal H2DIDS (6.64 ± 0.08, P > 0.05). Raising luminal pH did not realkalinize damaged cells, suggesting that the mechanism of acidification is not attributable to leakiness to luminal protons. Inhibition of apical HCO3−secretion with 0.5 mM luminal H2DIDS or genetic deletion of the solute-like carrier 26A9 (SLC26A9) Cl−/HCO3−exchanger blocked the pHoincrease normally observed in control animals but did not compromise repair of damaged tissue. Addition of exogenous PGE2significantly increased pHoin wild-type, but not SLC26A9 knockout, animals, suggesting that prostaglandin-stimulated HCO3−secretion is fully mediated by SLC26A9. We conclude that cellular HCO3−secretion, likely through SLC26A9, is the dominant mechanism whereby surface pH transiently increases in response to photodamage.

Loss of the NHE2 Na+/H+ exchanger has no apparent effect on diarrheal state of NHE3-deficient mice

2001 ◽  
Vol 281 (6) ◽  
pp. G1385-G1396 ◽  
Author(s):  
Clara Ledoussal ◽  
Alison L. Woo ◽  
Marian L. Miller ◽  
Gary E. Shull
Keyword(s):  
Absorptive Capacity ◽  
Apparent Effect ◽  
Acid Base ◽  
Intestinal Brush Border ◽  
Apparent Reduction ◽  
Acid Base Status ◽  
Deficient Mice ◽  
Additional Loss ◽  
Partial Compensation

The expression of NHE2 and NHE3 on intestinal-brush border membranes suggests that both Na+/H+ exchangers serve absorptive functions. Studies with knockout mice showed that the loss of NHE3, but not NHE2, causes diarrhea, demonstrating that NHE3 is the major absorptive exchanger and indicating that any remaining absorptive capacity contributed by NHE2 is not sufficient to compensate fully for the loss of NHE3. To test the hypothesis that NHE2 provides partial compensation for the diarrheal state of NHE3-deficient mice, we crossed doubly heterozygous mice carrying null mutations in the Nhe2and Nhe3 genes and analyzed the phenotypes of their offspring. The additional loss of NHE2 in NHE3-deficient mice caused no apparent reduction in viability, no further impairment of systemic acid-base status or increase in aldosterone levels, and no apparent worsening of the diarrheal state. These in vivo phenotypic correlates of the absorptive defect suggest that the NaCl, HCO[Formula: see text], and fluid absorption that is dependent on apical Na+/H+ exchange is due overwhelmingly to the activity of NHE3, with little contribution from NHE2.

Cellular actions of cAMP on HCO3(-)-secreting cells of rabbit CCD: dependence on in vivo acid-base status

1994 ◽  
Vol 266 (4) ◽  
pp. F528-F535 ◽  
Author(s):  
C. Emmons ◽  
J. B. Stokes
Keyword(s):  
Anion Exchanger ◽  
Collecting Duct ◽  
Basolateral Membrane ◽  
Disulfonic Acid ◽  
Intercalated Cells ◽  
Cortical Collecting Duct ◽  
Acid Base ◽  
Acid Base Status

HCO3- secretion by cortical collecting duct (CCD) occurs via beta-intercalated cells. In vitro CCD HCO3- secretion is modulated by both the in vivo acid-base status of the animal and by adenosine 3',5'-cyclic monophosphate (cAMP). To investigate the mechanism of cAMP-induced HCO3- secretion, we measured intracellular pH (pHi) of individual beta-intercalated cells of CCDs dissected from alkali-loaded rabbits perfused in vitro. beta-Intercalated cells were identified by demonstrating the presence of an apical anion exchanger (cell alkalinization in response to removal of lumen Cl-). After 180 min of perfusion to permit decrease of endogenous cAMP, acute addition of 0.1 mM 8-bromo-cAMP or 1 microM isoproterenol to the bath caused a transient cellular alkalinization (> 0.20 pH units). In the symmetrical absence of either Na+, HCO3-, or Cl-, cAMP produced no change in pHi. Basolateral dihydrogen 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (0.1 mM) for 15 min before cAMP addition also prevented this alkalinization. In contrast to the response of cells from alkali-loaded rabbits, addition of basolateral cAMP to CCDs dissected from normal rabbits resulted in an acidification of beta-intercalated cells (approximately 0.20 pH units). The present studies demonstrate the importance of the in vivo acid-base status of the animal in the regulation of CCD HCO3- secretion by beta-intercalated cells. The results identify the possible existence of a previously unrecognized Na(+)-dependent Cl-/HCO3- exchanger on the basolateral membrane of beta-intercalated cells in alkali-loaded rabbits.

Is urea formation regulated primarily by acid-base balance in vivo?

1986 ◽  
Vol 250 (4) ◽  
pp. F605-F612 ◽  
Author(s):  
M. L. Halperin ◽  
C. B. Chen ◽  
S. Cheema-Dhadli ◽  
M. L. West ◽  
R. L. Jungas
Keyword(s):  
Dietary Protein ◽  
Urea Synthesis ◽  
Acid Base Balance ◽  
Severe Metabolic Acidosis ◽  
Acid Base ◽  
Wide Range ◽  
Base Balance ◽  
Acid Load ◽  
Acid Base Status

Large quantities of ammonium and bicarbonate are produced each day from the metabolism of dietary protein. It has recently been proposed that urea synthesis is regulated by the need to remove this large load of bicarbonate. The purpose of these experiments was to test whether the primary function of ureagenesis in vivo is to remove ammonium or bicarbonate. The first series of rats were given a constant acid load as hydrochloric acid or ammonium chloride; individual rats received a constant nitrogen load at a time when their plasma acid-base status ranged from normal (pH 7.4, 28 mM HCO3) to severe metabolic acidosis (pH 6.9, 6 mM HCO3). Urea plus ammonium excretions and the blood urea, glutamine, and ammonium concentrations were monitored with time. Within the constraints of non-steady-state conditions, the rate of urea synthesis was constant and the plasma glutamine and ammonium concentrations also remained constant; thus it appears that the rate of urea synthesis was not primarily regulated by the acid-base status of the animal in vivo over a wide range of plasma ammonium concentrations. In quantitative terms, the vast bulk of the ammonium load was converted to urea over 80 min; only a small quantity of ammonium appeared as circulating glutamine or urinary ammonium. Urea synthesis was proportional to the nitrogen load. A second series of rats received sodium bicarbonate; urea synthesis was not augmented by a bicarbonate load. We conclude from these studies that the need to dispose of excess bicarbonate does not primarily determine the rate of ureagenesis in vivo. The data support the classical view that ureagenesis is controlled by the quantity of ammonium to be removed.

scholarly journals Temperature Effects on Haemolymph Acid-Base Status In Vivo and In Vitro in the Two-Striped Grasshopper Melanoplus Bivittatus

1988 ◽  
Vol 140 (1) ◽  
pp. 421-435 ◽  
Author(s):  
JON M. HARRISON
Keyword(s):  
Body Temperature ◽  
Carbonic Acid ◽  
Temperature Shift ◽  
Effect Of Temperature ◽  
Locomotory Activity ◽  
Acid Base ◽  
Protein Dissociation ◽  
Acid Base Status

In this study, I examine the effect of temperature on haemolymph acid-base status in vivo and in vitro in the two-striped grasshopper Melanoplus bivittatus. Melanoplus bivittatus experience wide (up to 40 °C) diurnal body temperature fluctuations in the field, but maintain body temperature relatively constant during sunny days by behavioural thermoregulation. Haemolymph pH was statistically constant (7.12) between 10 and 25°C, but decreased by −0.017 units °C− from 25 to 40°C. Relative alkalinity and fractional protein dissociation were conserved only at body temperatures at which feeding and locomotory activity occur, above 20°C. Haemolymph total CO2 (Ctot) increased from 10 to 20°C and decreased from 20 to 40°C. Haemolymph Pco2 increased from 10 to 20°C and was statistically constant between 20 and 40°C. Carbonic acid pKapp in haemolymph was 6.122 at 35°C, and decreased with temperature by −0.0081 units°C−1. Haemolymph buffer value averaged −35mequivl−1pHunit−1. Haemolymph pH changes with temperature were small (less than −0.004 units°C−1) in vitro at constant Pco2. Therefore, passive physicochemical effects cannot account for the pattern of acid-base regulation in vivo. The temperature shift from 10 to 20°C was accompanied by a net addition of 4.2-6.2 mmoll−1 of bicarbonate equivalents to the haemolymph. The temperature shift from 20 to 40°C was accompanied by a net removal of 10–14 mmoll−1 of bicarbonate equivalents from the haemolymph. Haemolymph acid-base regulation in vivo during temperature changes is dominated by active variation of bicarbonate equivalents rather than by changes in Pco2 as observed for most other air-breathers.

Acid-Base Relationships in the Blood of the Toad, Bufo Marinus: II. The Effects of Dehydration

1979 ◽  
Vol 82 (1) ◽  
pp. 345-355
Author(s):  
R. G. BOUTILIER ◽  
D. J. RANDALL ◽  
G. SHELTON ◽  
D. P. TOEWS
Keyword(s):  
Water Loss ◽  
Respiratory Acidosis ◽  
Acid Base ◽  
Arterial Blood ◽  
Blood Ph ◽  
Acid Base Status ◽  
Toad Bufo ◽  
Circulating Levels ◽  
Bladder Urine ◽  
Co2 Excretion

Cutaneous CO2 excretion is reduced as the skin dries during dehydration but an increase in breath frequency acts to regulate the arterial blood Pcoco2 and thus pHα. Moreover, the toad does not urinate and water is reabsorbed from the bladder to replace that lost by evaporation at the skin and lung surfaces. The animal does, however, produce a very acid bladder urine to conserve circulating levels of plasma [HCO3-] and this together with an increased ventilation effectively maintains the blood acid-base status for up to 48 h of dehydration in air. Water loss and acid production are presumably also reduced by the animal's behaviour; animals remain still, in a crouched position or in a pile if left in groups. Dehydrated toads are less able than hydrated toads to regulate blood pH during hypercapnia: they hyperventilate and mobilize body bicarbonate stores in much the same fashion as hydrated animals but due to the restrictions on cutaneous CO2 excretion and renal output, there is comparatively little reduction in the PCOCO2 difference between arterial blood and inspired gas thereby resulting in a more severe respiratory acidosis. These factors further contribute to the persistent acidosis which continues even when the animals are returned to air.

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