scholarly journals The Boron & De Weer Model of Intracellular pH Regulation

2020 ◽  
Author(s):  
Rossana Occhipinti ◽  
Soroush Safaei ◽  
Peter J. Hunter ◽  
Walter F. Boron
Keyword(s):  
Cell Membrane ◽  
Intracellular Ph ◽  
Ph Regulation ◽  
Quantitative Model ◽  
Historical Background ◽  
Acid Base ◽  
Experimental Conditions ◽  
Subsequent Work ◽  
Energy Dependent ◽  
Parameter Values

The classic Boron & De Weer (1976) paper provided the first evidence of active regulation of pH} in cells by an energy-dependent acid-base transporter. These authors also developed a quantitative model --- comprising passive fluxes of acid-base equivalents across the cell membrane, intracellular reactions, and an active transport mechanism in the cell membrane (modelled as a proton pump) --- to help interpret their measurements of intracellular pH under perturbations of both extracellular CO2/HCO3- and extracellular NH3/NH4+. This Physiome paper seeks to make that model, and the experimental conditions under which it was developed, available in a reproducible and well-documented form, along with a software implementation that makes the model easy to use and understand. We have also taken the opportunity to update some of the units used in the original paper, and to provide a few parameter values that were missing in the original paper. Finally, we provide an historical background to the Boron & De Weer (1976) proposal for active pH regulation and a commentary on subsequent work that has enriched our understanding of this most basic aspect of cellular physiology.

scholarly journals The Boron & De Weer Model of Intracellular pH Regulation

2020 ◽  
Author(s):  
Rossana Occhipinti ◽  
Soroush Safaei ◽  
Peter J. Hunter ◽  
Walter F. Boron
Keyword(s):  
Cell Membrane ◽  
Intracellular Ph ◽  
Ph Regulation ◽  
Quantitative Model ◽  
Historical Background ◽  
Acid Base ◽  
Experimental Conditions ◽  
Subsequent Work ◽  
Energy Dependent ◽  
Parameter Values

The classic Boron & De Weer (1976) paper provided the first evidence of active regulation of pH} in cells by an energy-dependent acid-base transporter. These authors also developed a quantitative model --- comprising passive fluxes of acid-base equivalents across the cell membrane, intracellular reactions, and an active transport mechanism in the cell membrane (modelled as a proton pump) --- to help interpret their measurements of intracellular pH under perturbations of both extracellular CO2/HCO3- and extracellular NH3/NH4+. This Physiome paper seeks to make that model, and the experimental conditions under which it was developed, available in a reproducible and well-documented form, along with a software implementation that makes the model easy to use and understand. We have also taken the opportunity to update some of the units used in the original paper, and to provide a few parameter values that were missing in the original paper. Finally, we provide an historical background to the Boron & De Weer (1976) proposal for active pH regulation and a commentary on subsequent work that has enriched our understanding of this most basic aspect of cellular physiology.

Polarity of alveolar epithelial cell acid-base permeability

2002 ◽  
Vol 282 (4) ◽  
pp. L675-L683 ◽  
Author(s):  
Dilip Joseph ◽  
Omar Tirmizi ◽  
Xiao-Ling Zhang ◽  
Edward D. Crandall ◽  
Richard L. Lubman
Keyword(s):  
Cell Membrane ◽  
Intracellular Ph ◽  
Short Circuit ◽  
Short Circuit Current ◽  
Ph Gradient ◽  
Acid Base ◽  
Alveolar Epithelial ◽  
Basolateral Cell Membrane ◽  
Fluid Compartments ◽  
Two Fluid

We investigated acid-base permeability properties of electrically resistive monolayers of alveolar epithelial cells (AEC) grown in primary culture. AEC monolayers were grown on tissue culture-treated polycarbonate filters. Filters were mounted in a partitioned cuvette containing two fluid compartments (apical and basolateral) separated by the adherent monolayer, cells were loaded with the pH-sensitive dye 2′,7′-bis(2-carboxyethyl)-5(6)-carboxyfluorescein, and intracellular pH was determined. Monolayers in HCO[Formula: see text]-free Na+ buffer (140 mM Na+, 6 mM HEPES, pH 7.4) maintained a transepithelial pH gradient between the two fluid compartments over 30 min. Replacement of apical fluid by acidic (6.4) or basic (8.0) buffer resulted in minimal changes in intracellular pH. Replacement of basolateral fluid by acidic or basic buffer resulted in transmembrane proton fluxes and intracellular acidification or alkalinization. Intracellular alkalinization was blocked ≥80% by 100 μM dimethylamiloride, an inhibitor of Na+/H+exchange, whereas acidification was not affected by a series of acid/base transport inhibitors. Additional experiments in which AEC monolayers were grown in the presence of acidic (6.4) or basic (8.0) medium revealed differential effects on bioelectric properties depending on whether extracellular pH was altered in apical or basolateral fluid compartments bathing the cells. Acid exposure reduced (and base exposure increased) short-circuit current from the basolateral side; apical exposure did not affect short-circuit current in either case. We conclude that AEC monolayers are relatively impermeable to transepithelial acid/base fluxes, primarily because of impermeability of intercellular junctions and of the apical, rather than basolateral, cell membrane. The principal basolateral acid exit pathway observed under these experimental conditions is Na+/H+ exchange, whereas proton uptake into cells occurs across the basolateral cell membrane by a different, undetermined mechanism. These results are consistent with the ability of the alveolar epithelium to maintain an apical-to-basolateral (air space-to-blood) pH gradient in situ.

scholarly journals American alligator (Alligator mississippiensis) embryos tightly regulate intracellular pH during a severe acidosis

2018 ◽  
Vol 96 (7) ◽  
pp. 723-727 ◽  
Author(s):  
R.B. Shartau ◽  
D.A. Crossley ◽  
Z.F. Kohl ◽  
R.M. Elsey ◽  
C.J. Brauner
Keyword(s):  
Intracellular Ph ◽  
Ph Regulation ◽  
Alligator Mississippiensis ◽  
American Alligator ◽  
Acid Base ◽  
Tissue Ph ◽  
Snapping Turtle ◽  
Blood Ph ◽  
Brain Ph

Crocodilian nests naturally experience high CO2 (hypercarbia), which leads to increased blood Pco2 and reduced blood pH (pHe) in embryos; their response to acid–base challenges is not known. During acute hypercarbia, snapping turtle embryos preferentially regulate tissue pH (pHi) against pHe reductions. This is proposed to be associated with CO2 tolerance in reptilian embryos and is not found in adults. In the present study, we investigated pH regulation in American alligator (Alligator mississippiensis (Daudin, 1802)) embryos exposed to 1 h of hypercarbia hypoxia (13 kPa Pco2, 9 kPa Po2). Hypercarbia hypoxia reduced pHe by 0.42 pH unit, while heart and brain pHi increased, with no change in the pHi of other tissues. The results indicate that American alligator embryos preferentially regulate pHi, similar to snapping turtle embryos, which represents a markedly different strategy of acid–base regulation than what is observed in adult reptiles. These findings suggest that preferential pHi regulation may be a strategy of acid–base regulation used by embryonic reptiles.

scholarly journals Intracellular pH regulation in human Sertoli cells: role of membrane transporters

Reproduction ◽  
2009 ◽  
Vol 137 (2) ◽  
pp. 353-359 ◽  
Author(s):  
P F Oliveira ◽  
M Sousa ◽  
A Barros ◽  
T Moura ◽  
A Rebelo da Costa
Keyword(s):  
Intracellular Ph ◽  
Sertoli Cells ◽  
Ph Regulation ◽  
Primary Cultures ◽  
Disulfonic Acid ◽  
Cell Physiology ◽  
Experimental Conditions ◽  
Concanamycin A ◽  
Wide Range ◽  
Phi Regulation

Sertoli cells are responsible for regulating a wide range of processes that lead to the differentiation of male germ cells into spermatozoa. Intracellular pH (pHi) is an important parameter in cell physiology regulating namely cell metabolism and differentiation. However, pHi regulation mechanisms in Sertoli cells have not yet been systematically elucidated. In this work, pHi was determined in primary cultures of human Sertoli cells. Sertoli cells were exposed to weak acids, which caused a rapid acidification of the intracellular milieu. pHi then recovered by a mechanism that was shown to be particularly sensitive to the presence of the inhibitor DIDS (4,4′-diisothiocyanostilbene disulfonic acid). In the presence of amiloride and PSA (picrylsulfonic acid), pHi recovery was also significantly affected. These results indicate that, in the experimental conditions used, pHi is regulated by the action of an Na+-driven HCO3−/Cl−exchanger and an Na+/HCO3−co-transporter and also by the action of the Na+/H+exchanger. On the other hand, pHi recovery was only slightly affected by concanamycin A, suggesting that V-Type ATPases do not have a relevant action on pHi regulation in human Sertoli cells, and was independent of the presence of bumetanide, suggesting that the inhibition of the Na+/K+/Cl−co-transporter does not affect pHi recovery, not even indirectly via the shift of ionic gradients. Finally, pHi was shown to be sensitive to the removal of external Cl−, but not of Na+or K+, evidencing the presence of a membrane Cl−-dependent base extruder, namely the Na+-independent HCO3−/Cl−exchanger, and its role on pHi maintenance on these cells.

scholarly journals Intracellular pH regulation by acid-base transporters in mammalian neurons

2014 ◽  
Vol 5 ◽  
Author(s):  
Vernon A. Ruffin ◽  
Ahlam I. Salameh ◽  
Walter F. Boron ◽  
Mark D. Parker
Keyword(s):  
Intracellular Ph ◽  
Ph Regulation ◽  
Acid Base ◽  
Intracellular Ph Regulation

scholarly journals Role of Na-H exchangers and vacuolar H+ pumps in intracellular pH regulation in neonatal rat osteoclasts.

1995 ◽  
Vol 105 (2) ◽  
pp. 177-208 ◽  
Author(s):  
J H Ravesloot ◽  
T Eisen ◽  
R Baron ◽  
W F Boron
Keyword(s):  
Intracellular Ph ◽  
Imaging System ◽  
Ph Regulation ◽  
Neonatal Rat ◽  
Hill Coefficient ◽  
Acid Base ◽  
Buffering Power ◽  
Acid Extrusion

Osteoclasts resorb bone by pumping of H+ into a compartment between the cell and the bone surface. Intracellular pH (pHi) homeostasis requires that this acid extrusion, mediated by a vacuolar-type H+ ATPase, be complemented by other acid-base transporters. We investigated acid-extrusion mechanisms of single, freshly isolated, neonatal rat osteoclasts. Cells adherent to glass coverslips were studied in the nominal absence of CO2/HCO3-, using the pH-sensitive dye BCECF and a digital imaging system. Initial pHi averaged 7.31 and was uniform throughout individual cells. Intrinsic buffering power (beta 1) decreased curvilinearly from approximately 25 mM at pHi = 6.4 to approximately 6.0 mM at pHi = 7.4. In all polygonally shaped osteoclasts, and approximately 60% of round osteoclasts (approximately 20% of total), pHi recovery from acid loads was mediated exclusively by Na-H exchange. In these pattern-1 cells, pHi recovery was 95% complete within 200 s, and was blocked by removing Na+, or by applying 1 mM amiloride, 50 microM ethylisopropylamiloride (EIPA), or 50 microM hexamethyleneamiloride (HMA). The apparent K1/2 for HMA ([Na+]o = 150 mM) was 49 nM, and the apparent K1/2 for Na+ was 45 mM. Na-H exchange, corrected for amiloride-insensitive fluxes, was half maximal at pHi 6.73, with an apparent Hill coefficient for intracellular H+ of 2.9. Maximal Na-H exchange averaged 741 microM/s. In the remaining approximately 40% of round osteoclasts (pattern-2 cells), pHi recovery from acid loads was brisk even in the absence of Na+ or presence of amiloride. This Na(+)-independent pHi recovery was blocked by 7-chloro-4-nitrobenz-2-oxa-1,3-diazol (NBD-Cl), a vacuolar-type H+ pump inhibitor. Corrected for NBD-Cl insensitive fluxes, H+ pump fluxes decreased approximately linearly from 96 at pHi 6.8 to 11 microM/s at pHi 7.45. In approximately 45% of pattern-2 cells, Na+ readdition elicited a further pHi recovery, suggesting that H+ pumps and Na-H exchangers can exist simultaneously. We conclude that, under the conditions of our study, most neonatal rat osteoclasts express Na-H exchangers that are probably of the ubiquitous basolateral subtype. Some cells express vacuolar-type H+ pumps in their plasma membrane, as do active osteoclasts in situ.

scholarly journals Regulation of Extra- and Intracellular pH in the Brain in Severe Hypoglycemia

1981 ◽  
Vol 1 (1) ◽  
pp. 85-96 ◽  
Author(s):  
Dale Pelligrino ◽  
Bo K. Siesjö
Keyword(s):  
Intracellular Ph ◽  
Ph Regulation ◽  
Cell Damage ◽  
Energy State ◽  
Energy Charge ◽  
Severe Hypoglycemia ◽  
Cell Membrane Permeability ◽  
Adenylate Energy Charge ◽  
Acid Base ◽  
The Brain

Severe hypoglycemia is associated with a marked curtailment of cerebral glucose supply and with consumption of endogenous carbohydrate metabolites and amino acids, many of which exist as anions of acids. Since metabolic control of intracellular pH in acute hypo- and hypercapnia seems to be dependent on the production and consumption of metabolic acids, it must be suspected that intracellular pH in the brain is poorly regulated in hypoglycemic animals. We induced hypocapnia (Paco2 about 15 mm Hg) and hypercapnia (Paco2 about 90 mm Hg) in insulin-injected animals in “precoma” (EEG pattern of slow waves, polyspikes) and “coma” (cessation of EEG activity) and measured CSF and intracellular acid-base changes using the CO2 method. The induced hypoglycemia did not measurably alter CSF acid-base changes from the normal during hypercapnia, but it did impair CSF pH regulation in hypocapnia. Animals in precoma showed an unchanged cerebral energy state during both hypo- and hypercapnia. Regulation of intracellular pH was not measurably affected in hypercapnia but was reduced in hypocapnia. These results could be accounted for by a reduced ability of the hypoglycemic animals to produce metabolic acids in response to the decrease in Pco2, while the capacity to “consume” acids was largely retained. In comatose animals, cerebral energy state was held at normocapnic levels during hypercapnia but deteriorated during hypocapnia. In the latter condition, the reduction in adenylate energy charge correlated to a decrease in blood pressure. The capacity to alter metabolic acid levels was abolished. In spite of this, hypocapnia was associated with a marked rise in intracellular pH, in some animals to values of about 7.7 (control, 7.0), and hypercapnia caused only very moderate reduction in intracellular pH. It is proposed that the excessive increase in intracellular pH during hypocapnia was due to hypotension-induced energy failure with subsequent depolarization of cells and passive equilibration of HCO3− (or H+) across the cell membranes. In hypercapnia, the influx of HCO3− into cells was unrelated to further deterioration of cerebral energy state but could possibly have been caused by CO2-induced depolarization and/or increased cell membrane permeability to HCO3−/H+ ions. It is concluded that severe hypoglycemia disrupts intracellular pH regulation in the brain and that hypocapnia combined with moderate hypotension leads to an excessive intracellular alkalosis of potential importance for the development of cell damage.

Effects of in vivo and in vitro alkali treatment on intracellular pH regulation of OMCDis cells

1993 ◽  
Vol 265 (5) ◽  
pp. F729-F735
Author(s):  
M. Hayashi ◽  
M. Iyori ◽  
Y. Yamaji ◽  
T. Saruta
Keyword(s):  
Intracellular Ph ◽  
Cell Function ◽  
Ph Regulation ◽  
Alkali Treatment ◽  
Acid Base ◽  
Acetoxymethyl Ester ◽  
Functional Changes ◽  
Significant Difference

To examine functional changes of the transporters in the inner stripe of the outer medullary collecting ducts (OMCDis) by the peritubular acid-base status, in vitro microperfusion using the acetoxymethyl ester of 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein was performed. Cell alkalinization systems were assessed by the recovery rate (dpHi/dt) of intracellular pH (pHi) after intracellular acid loading by NH(4+)-NH3 prepulse with bath amiloride. In alkali-loaded rabbits (0.15 M NaHCO3 drinking for 14 days), dpHi/dt showed a significant decrease (1.80 +/- 0.29 pH units/s x 10(3)) compared with either control (3.30 +/- 0.59) or acid-loaded rabbits (0.15 M NH4Cl drinking for 14 days, 3.05 +/- 0.46). The difference of dpHi/dt between control and alkali-loaded rabbits was eliminated by lumen N-ethylmaleimide (NEM), suggesting that H+ pump activity was decreased. The effect of in vitro alkali treatment (50 mM HCO3-, pH 7.7) for 3-4 h was also examined. This incubation significantly decreased the dpHi/dt (1.83 +/- 0.35) compared with the time control experiments (3.18 +/- 0.28), whereas no significant difference was seen in the presence of lumen NEM. Anion exchanger activity, as determined from the pHi changes after Cl- addition to the bath, showed no significant change with in vivo or in vitro alkali treatment. The results indicate that cell function of the OMCDis is regulated in response to the peritubular acid-base environment via changes in the H(+)-adenosinetriphosphatase.

scholarly journals Intracellular pH regulation in mantle epithelial cells of the Pacific oyster, Crassostrea gigas

2020 ◽  
Vol 190 (6) ◽  
pp. 691-700 ◽  
Author(s):  
Kirti Ramesh ◽  
Marian Y. Hu ◽  
Frank Melzner ◽  
Markus Bleich ◽  
Nina Himmerkus
Keyword(s):  
Epithelial Cells ◽  
Intracellular Ph ◽  
Crassostrea Gigas ◽  
Pacific Oyster ◽  
Ph Regulation ◽  
Carbonic Anhydrases ◽  
Limited Information ◽  
Acid Base ◽  
Regulatory Machinery ◽  
The Pacific

Abstract Shell formation and repair occurs under the control of mantle epithelial cells in bivalve molluscs. However, limited information is available on the precise acid–base regulatory machinery present within these cells, which are fundamental to calcification. Here, we isolate mantle epithelial cells from the Pacific oyster, Crassostrea gigas and utilise live cell imaging in combination with the fluorescent dye, BCECF-AM to study intracellular pH (pHi) regulation. To elucidate the involvement of various ion transport mechanisms, modified seawater solutions (low sodium, low bicarbonate) and specific inhibitors for acid–base proteins were used. Diminished pH recovery in the absence of Na+ and under inhibition of sodium/hydrogen exchangers (NHEs) implicate the involvement of a sodium dependent cellular proton extrusion mechanism. In addition, pH recovery was reduced under inhibition of carbonic anhydrases. These data provide the foundation for a better understanding of acid–base regulation underlying the physiology of calcification in bivalves.

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