The role of low intracellular or extracellular pH in sensitization to hyperthermia

Cells are more sensitive to heat when they are heated in an acidic environment, and this study confirms (K. G. Hofer and N. F. Mivechi, J. Natl. Cancer Inst., 65, 621, 1980) that intracellular pH (pHi) and not extracellular pH (pHe) is responsible for the sensitization. The relationship between pHe, pHi, and heat survival of cells heated in vitro in various buffers at pHe 6.3-8.0 was investigated. Cells' adaptation to low environmental pH in terms of increases in pHi and heat survival also was investigated. Finally, we studied the relationships among pHe, pHi, and survival from heat for cells heated in sodium-free reconstructed medium. Intracellular pH was measured by the distribution of the weak acid, [2-14C]5,5-dimethyl-2,4-oxazolidinedione. Our results are summarized as follows: (1) CHO cells maintained the same relationship between pHe and pHi in four different media or buffers (McCoy's 5a medium buffered with CO2 and NaHCO3 or 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (Hepes) and 2-(N-morpholino)ethanesulfonic acid (Mes), Krebs-Ringer bicarbonate solution, and Krebs-Ringer phosphate solution) with pHi being 0.05 to 0.20 pH units higher than pHe as it varied from 7.0 to 6.4; furthermore, heat sensitization by acid was the same in medium buffered with NaHCO3 or Hepes and Mes. (2) The low pHe adapted cells multiplied with an increased doubling time of 20.7 +/- 0.7 h and appeared morphologically similar to the unadapted cells. However, the pHi of these cells was 0.15-0.30 pH units higher than that of the unadapted cells when pHe was varied between 7.0 and 6.3. (3) After being heated at 43.5 degrees C for 55 min or at 42.5 degrees C for 150 min at pHe 6.3-7.2, the pHi of the adapted cells increased by 0.2-0.1 pH units. However, heat caused no significant change in the unadapted cells. (4) Heat survival plotted versus pHe was 1000-fold higher for the adapted cells than for the unadapted cells at pHe of 6.3. However, heat survival plotted versus pHi was identical for the two cell types. (5) In sodium-free reconstructed McCoy's 5a medium, pHi was 0.25-0.1 pH units lower than that in the sodium-containing counterpart at pHe 6.3-7.2, and heat sensitization increased accordingly; however, heat survival plotted versus pHi was identical for the two types of media.     

The role of low intracellular or extracellular pH in sensitization to hyperthermic radiosensitization

Previous work showed that intracellular pH (pHi) and not extracellular pH (pHe) was the determinant in the low pH sensitization of hyperthermic killing. The present studies show that the same is true for heat-induced radiosensitization and loss of cellular DNA polymerase activities. Chinese hamster ovary cells after they had adapted to low pH (6.7) had an increase in pHi which rendered cells partially resistant to the low pH sensitization of heat-induced cell killing, radiosensitization, and loss of cellular DNA polymerase activities. These results were quantified by plotting versus pHe, both the thermal enhancement ratio (TER), defined as the ratio of the X-ray dose without heat to the X-ray dose with heat to give an isosurvival value of 0.01, and the thermal enhancement factor (TEF), defined as the ratio of the D0 of the radiation survival curve to the D0 of the radiation survival curve for heat plus radiation. Both the TER and TEF were higher for the unadapted cells than for the adapted cells, i.e., 1.3-1.4 fold higher at a pHe of 6.3. However, the TER or TEF plotted versus pHi was identical for the two cell types. Finally, heat-induced loss of cellular DNA polymerase activities correlated with pHi and not pHe. Therefore, we conclude that pHi and not pHe is responsible for the increase by acid in heat-induced radio-sensitization and loss of cellular DNA polymerase activities.     

pH-dependent effects of the ionophore nigericin on response of mammalian cells to radiation and heat treatment

The extracellular pH (pHe) in many solid tumors is often lower than the pH of normal tissues. The K+/H+ ionophore nigericin is toxic to CHO cells when pHe is below but not above 6.5, and thus it has potential for selective killing of tumor cells in an acidic environment. This study examines the pH-dependent effects of nigericin on the response of CHO cells to radiation and heat treatment. Cells held for 4 h in Hank's balanced salt solution, after 9 Gy irradiation, exhibit potentially lethal damage recovery (PLDR) which is maximal at pHe 6.7-6.8. Addition of nigericin, postirradiation, not only inhibits PLDR when pHe is below 6.8, but interacts synergistically with radiation to reduce survival below that of cells plated immediately after irradiation when pHe is 6.4 or lower. Nigericin enhances heat killing of CHO cells perferentially under acidic conditions, and where neither heat nor drug treatment alone is significantly toxic. Survival of cells held for 30 min at 42.1 degrees C in the presence of 1.0 microgram/ml nigericin is 0.6, 0.08, 0.003, and 0.00003 at pHe 7.4, 6.8, 6.6, and 6.4, respectively, relative to survival of 1.0 in untreated cultures. The biochemical effects of nigericin at pHe 7.4 vs pHe 6.4 have been investigated. Nigericin inhibits respiration, stimulates glucose consumption, and causes dramatic changes in intracellular concentrations of Na+ and K+ at pHe 7.4 as well as 6.4. The drug reduces intracellular levels of ATP, GTP, and ADP but has more pronounced effects under acidic incubation conditions. Others have shown that nigericin equilibrates pHe and intracellular pH (pHi) only when pHe is 6.5 or lower. Our observations and those of others have led us to conclude that lowering of pHi by nigericin is either the direct or indirect cause of enhancement of radiation and heat killing of cells in an acidic environment.     

Influence of extracellular pH on intracellular pH and cell energy status: relationship to hyperthermic sensitivity

The effect of variable extracellular pH on intracellular pH, cell energy status, and thermal sensitivity was evaluated in CHO cells over the extracellular pH range of 6.0 to 8.6. Extracellular pH was adjusted with either lactic acid, HCl, or NaOH. Regardless of the method of pH adjustment, the results obtained were similar. The relationship between extracellular and intracellular pH was dependent upon the pH range examined. Intracellular pH was relatively resistant to a change in extracellular pH over the pHe range of 6.8 to 7.8 (i.e., delta pHi congruent to delta pHe X 0.33). Above and below this range, delta pHi congruent to delta pHe X 1.08 or X 0.76, respectively. Cellular survival after a 30-min heat treatment at 44 degrees C remained constant over the extracellular pH range of 7.0 to 8.4, but varied substantially over a similar intracellular pH range. The cellular concentration of the high energy phosphate reservoir, phosphocreatine, decreased with decreasing pH. However, the cellular concentrations of ATP, ADP, and AMP remained constant over the entire pH range examined. It is concluded that increased thermal sensitivity resulting from a change in extracellular pH is not due to cellular energy depletion. Furthermore, intracellular pH is a more accurate indicator of thermal sensitivity than is extracellular pH.     

Low pH does not affect the dose response for 5'-amino-5'-deoxythymidine modulation of IdUrd DNA incorporation and radiosensitization in a human bladder cancer cell line.

We report that coincubation of 647V cells for one cell cycle with low concentrations (30 microM) of 5'-amino-5'-deoxythymidine increased IdUrd DNA incorporation and radiosensitivity at low extracellular pH (pHe 6.8) in a fashion similar to treatment at normal pHe. IdUrd DNA incorporation is inhibited by high (300 microM) 5'-AdThd concentrations at both normal and low pHe (7.4 and 6.8), resulting in no significant radiosensitization. These results at low pHe were not anticipated based on previously published studies of 5'-AdThd modulation of thymidine kinase (TK) activity and nucleoside cellular uptake. Our results suggest that regulation of intracellular pH (pHi) during the course of one cell cycle negates the 5'-AdThd dose-dependent modulation of TK activity demonstrated previously. Flow cytometric measurement of pHi in 647V cells showed that normal pHi (pH 7.4) was maintained in 647V cells over a 12- to 24-h exposure to low pHe (pH 6.8). Thus the concomitant use of IdUrd and high concentrations of 5'-AdThd (> 30 microM) is unlikely to result in selective in vivo radiosensitization of human tumors under conditions which are intermittently or chronically acidic. However, low concentrations of 5'-AdThd may prove to be an effective in vivo modulator of IdUrd radiosensitization of human tumors under both normal and acidic conditions.     

Comparison of DMO and flow cytometric methods for measuring intracellular pH and the effect of hyperthermia on the transmembrane pH gradient

Intracellular pH (pHi) was measured in both unheated and heated cells by the distribution of the weak acid, 5,5-dimethyl-2,4-oxazolidinedione-2-14C (14C-DMO), and by the fluorescence intensity ratio (I530/I630) of the pH sensitive fluorescent dye, 2',7'-bis(carboxyethyl)-5,6-carboxy-fluorescein (BCECF), analyzed by flow cytometry (FCM). BCECF-loaded Chinese hamster ovary (CHO) cells were analyzed by FCM after they had incubated in fresh medium at 37 degrees C for 90 min, during which time a decrease in fluorescence ratio stabilized. After stabilization, the pHi determined for CHO cells by the FCM method at pHe values of 6.0-8.1 agreed-within 0.1 pH units with that determined by the 14C-DMO method. There is a pH gradient across the plasma membrane that is not affected by heat. In CHO cells, the gradient, determined by DMO and FCM, is less or greater than pHe by 0.30 and 0.15 pH units at pHe 7.4 and 6.3, respectively, and in NG108-15 cells, the gradient determined by DMO increases to 0.50 pH units at pHe 6.3. Both cells maintained their pH gradients for at least 4 h after heating, although 99.9% of the cells were reproductively dead (survival of 10(-3)) after heating at 45.5 degrees C either at the normal pHe of 7.4 or at a low pHe of 6.4-6.7.     

Intracellular pH (pHi) of red cells stored in acid citrate dextrose medium. Effects of temperature and citrate anions.

The intracellular pH (pHi) of red cells stored in acid citrate dextrose (ACD) medium was estimated by the 5,5'-dimethyloxazoldine,-2,4-dione (DMO) method. The initial pHi at 4degrees was about 7.6 and was higher than the extracellular pH (pHe) at 4degrees. During storage, both pHi and pHe decreased, but the former was always higher than the latter and the former decreased more slowly than the latter. The high pHi of ACD blood was a results of the temperature at which the pHe and the pHi were measured (4degrees) and the presence of citrate anions in the medium, and could be explained by application of the Donnan-Gibbs equilibrium. ATP and 2,3-diphosphoglycerate (DPG) were well-maintained in heparinized blood when it was acidified and pHe and pHi at 4degrees were both about 7.4, which suggests that improvement of blood preservation may be attained by suitable adjustment of the pHi and pHe of the blood.     

Dihydrotetrabenazine Binding and Monoamine Uptake in Mouse Brain Regions

The objective of the present study was to estimate extracellular pH (pHe) and intracellular pH (pHi) during near-complete forebrain ischemia in the rat, and to evaluate the relative importance of lactic acidosis and rise in tissue Pco2 (Ptco2) in causing pHe and pHi to fall. The animals, which were ventilated, normoxic, normocapnic, and normothermic, were subjected to 15 min of ischemia, either without or with 30-60 min of recirculation. Ptco2 was measured with a tissue electrode, pHe with a double-barrel liquid ion-exchanger microelectrode, changes in extracellular fluid (ECF) volume by impedance measurements, tissue CO2 content by a microdiffusion technique, and labile tissue metabolites by enzymatic fluorometric methods. Ischemia caused Ptco2 to rise to between 95 and 190 mm Hg (mean 149 mm Hg), and pHe to fall by 0.45-1.05 units (mean 0.70 units). During recovery, Ptco2 normalized within 5 min and pHe after 15-30 min. During ischemia, high-energy phosphates were depleted and tissue lactate content increased to 15 mumol X g-1. The total CO2 content (Tco2) was minimally or moderately reduced (normal, 11.9 mumol X g-1; range of ischemic values, 7.9-12.1 mumol X g-1), this range probably reflecting variable amounts of remaining blood flow. Impedance measurements demonstrated that ECF volume during ischemia was reduced to 55% of control, with gradual normalization during the first 15-30 min of recirculation. From values for Ptco2, Tco2, [HCO3-]e, and ECF volume, [HCO3-]i and pHi could be calculated. These values pertain to an idealized homogeneous intracellular compartment, and the methods used cannot detect whether different intracellular compartments diverge in their acid-base responses.(ABSTRACT TRUNCATED AT 250 WORDS)     

The regulation of intracellular pH studied by 31P- and 1H-NMR spectroscopy in superfused guinea-pig cerebral cortex slices.

(1) The intracellular pH (pHi) of superfused slices of guinea-pig cerebral cortex was measured in 31P-NMR spectra using the chemical shifts of intracellular inorganic phosphate (Pi) and of 2-deoxyglucose 6-phosphate (DOG6P). The pHi was found to be 7.30 +/- 0.04 (SD, n = 15) in bicarbonate-buffered medium and 7.20 +/- 0.05 (n = 10, P < 0.001) in bicarbonate-free HEPES buffer of the same pH (7.4). (2) Decreases in pHe below 7.05 resulted in pHi falling to similar values, with a decrease in the energy state. There was no change in intracellular lactate as assessed by 1H-NMR. (3) The tissues showed an ability to buffer higher pH: increasing pHe to 8.0 had no effect on pHi, PCr or lactate. (4) In order to characterize possible mechanisms of pH regulation in the tissue, the recovery from acid insult was investigated under various conditions. Initially pHi was decreased to 6.44 +/- 0.15 (n = 15) by exposure to media containing 6 mM bicarbonate gassed with O2/CO2, 80:20 (pHe 6.4). When this medium was replaced by normal bicarbonate buffer (pH 7.4) there was full recovery of pHi to 7.31 +/- 0.05 (n = 15), whereas replacing the buffer with HEPES resulted in incomplete recovery of pHi to 6.88 +/- 0.15 (n = 15, P < 0.001). (5) In the presence of the carbonic anhydrase inhibitor, acetazolamide (1 mM), or the sodium/proton exchange inhibitor, amiloride (1 mM), there was an incomplete return of pHi to the control value (pHi 6.90 +/- 0.20, n = 5, P < 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxygen binding and acid base status of the blood from the freshwater turtle, Phrynops hilarii

Oxygenation studies with the whole blood of Phrynops hilarii show a P50 of 38 torr at extracellular pH (pHe) of 7.4 which corresponds to an intracellular pH (pHi) of 7.05 at 25 degrees C. The blood CO2 Bohr effect was -0.56 when related to pHi. pHi is related to pHe by the following equation: pHi = 0.75.pHe + 1.54 (r = 0.99); pHi = 0.72. pHe + 1.72 (r = 0.96) at 10 and 25 degrees C respectively. Blood pHe, for 25 degrees C, was 7.519 +/- 0.254 (n = 6). Blood gas partial pressures were: pCO2 = 25.8 +/- 3.8 torr (n = 6); pO2 = 61.7 +/- 21.2 torr (n = 6). The major red cell phosphates, in mmole/l erythrocytes, n = 6, were: ATP (3.66 +/- 0.86); GTP (0.53 +/- 0.28); 2.3-DPG (0.32 +/- 0.12) and inorganic phosphates (2.00 +/- 0.35). The plasma inorganic ion composition, n = 6, was, in mEq/l: K+ (3.04 +/- 0.40); Na+ (148.4 +/- 12.6); Ca2+ (4.75 +/- 1.32); Cl- (106.6 +/- 5.0). Additional blood parameters of interest (n = 6) were: lactate (2.07 +/- 1.72 mM in plasma); erythrocytes/mm3 (416 X 10(3) +/- 4.6 X 10(3)); leucocytes/mm3 (44636 +/- 2618); haematocrit (%) (14.5 +/- 3.6); haemoglobin, g/dl (3.2 +/- 0.5); plasma protein g/dl (4.4 +/- 0.4); osmolarity (293 +/- 10 mOsm/l). The non-bicarbonate buffer value was -22.6 mmol/kg H2O/pH. For a constant CO2 content, delta pHe/delta t = 0.0141 +/- 0.002 (n = 18) and delta pHi/delta t = 0.0157 +/- 0.003 (n = 18).     

Use of flow cytometry and SNARF to calibrate and measure intracellular pH in NS0 cells.

BACKGROUND: Two calibration methods have been proposed for determining the relation between the fluorescence ratio of a pH-sensitive fluorescent indicator and intracellular pH (pHi). The first method uses nigericin to clamp pHi to external pH (pHe) and the second is the null point method. We compared these different calibration methods, solution conditions, and temperatures by using flow cytometry and the fluorescent dye 1,5- (and-6)-carboxy seminaphtorhodafluor-1-acetoxymethyl ester with an NS0 cell line. METHODS: The nigericin method was performed in glucose solutions supplemented with KCl and 2-(N-morpholino)ethane sulphonic acid plus tris(hydroxymethyl)aminomethane (solution 1A), a mixture of K2HPO4/KH2PO4 in glucose-solution supplemented solutions (solution 2A), or bicarbonate buffered growth medium supplemented with K2HPO4/KH2PO4 (solution 2B); this allowed a range of pHe values to be used. The effect of temperature (22 degrees C or 37 degrees C) on the nigericin calibration curve was also investigated. The null point method was performed by using a series of solutions with a mixture of weak acid and base with a known pHi response. RESULTS: Using solution 1A as the calibration solution resulted in acidic values of pHi for cells cultured in medium as compared with the values achieved with solution 2A. Using solution 2B did not affect the calibration curve. For the temperatures considered in this study, there was no affect on the calibration curve, but temperature did affect the pHi value of cells in phosphate buffered saline. The pseudo-null point method used with flow cytometry resulted in a calibration curve that was significantly different (P<0.05) from that achieved using the nigericin method. CONCLUSIONS: Our data indicates that the choice of calibration solution can affect the reported pHi value; therefore, careful choice of solution is important.     

Bicarbonate abolishes intracellular alkalinization in mitogen-stimulated 3T3 cells

An increase in intracellular pH (pHi) following mitogenic stimulation has been reported in a variety of mammalian cells (W. Moolenaar, Annu. Rev. Physiol., 48:363-376, 1986; E. Rozengurt, Science, 234:161-166, 1986). This increase is currently believed to constitute a "permissive" signal in the process of cell activation (A.E. Lagarde and J.M. Pouyssegur, Cancer Biochem. Biophys. 9:1-14, 1986). Since the majority of studies of this phenomenon have been conducted in the nonphysiological milieu of bicarbonate-free solutions, we have undertaken a study of the effects of bicarbonate and CO2 on mitogen-induced intracellular alkalinization in NIH 3T3 cells. Using nuclear magnetic resonance (NMR) spectroscopy and novel 31P NMR pH indicators (2-amino-phosphono-carboxylic acids) we found that mitogen induces an increase in pHi of 0.16 units only in cells bathed in medium containing low concentrations of bicarbonate (less than 1 mM) and not in cells bathed in medium containing physiological levels of bicarbonate (10-30 mM). In addition to abolishing the mitogen-induced alkalinization, bicarbonate stabilizes pHi at 7.25 units as the external pH (pHe) is varied from 7.0 to 7.6. In contrast, in a bicarbonate-free medium pHi increases from 6.9 to 7.3 over the same range of external pHs. At a constant external pH, increasing the bicarbonate/CO2 concentration results in an increase in pHi from 6.9 in bicarbonate-free solution to 7.25 in a bicarbonate-buffered medium. This relationship is hyperbolic with half-maximal effect occurring at a concentration of 0.4 mM bicarbonate at pH 7.05 and 37 degrees C. Our results suggest that the observations of mitogen-induced alkalinization may be due to the use of nonphysiological bicarbonate-free media. Since this increase in pHi is not observed in physiological media where bicarbonate concentrations are usually greater than 20 mM, we conclude that an increase in pHi is not an obligatory or usual part of the cellular response to growth factors in vivo.     

Rapid method for measuring intracellular pH in vivo.

Intracellular pH (pHi) was simultaneously measured in 6 normal tissues and a malignant tumour of rats by a rapid triple isotope technique, based on the in vivo distribution of 5,5-dimethyl-2,4-oxazolidinedione-2-14C (DMO), tritiated water and sodium chloride-36. Results compared favourably with pH measured directly in the same rat by capillary glass electrode, and with values of other workers for pHi in rat tissues. Mean pHi of normal tissues was close to pH 7, and in each organ there was a linear relationship between pHi and extracellular pH (pHe) over the normal range of pHe encountered (pH 6.9-7.6). Organ pHi altered in response to administration of NH4Cl or NaHCO3 to the host.     

Regulation of intracellular pH in LLC-PK1 cells studied using 31P-NMR spectroscopy

31P-NMR spectroscopy was used to monitor intracellular pH (pHi) in a suspension of LLC-PK1 cells, a renal epithelial cell line. The regulation of intracellular pH (pHi) was studied during intracellular acidification with 20% CO2 or intracellular alkalinization with 30 mM NH4Cl. The steady-state pHi in bicarbonate-containing Ringer's solution (pHo 7.40) was 7.14 +/- 0.04 and in bicarbonate-free Ringer's solution (pHo 7.40) 7.24 +/- 0.04. When pHo was altered in nominally HCO3(-)-free Ringer's, the intracellular pHi changed to only a small extent between pHo 6.6 and pHo 7.6; beyond this range pHi was linearly related to pHo. Below pHo 6.6 the cell was capable of maintaining a delta pH of 0.2 pH unit (inside more alkaline), above pH 7.6 a delta pH of 0.4 unit could be generated (inside more acid). During exposure to 20% CO2 in HCO3(-)-free Ringer's solution, pHi dropped initially to 6.9 +/- 0.05, the rate of realkalinisation was found to be 0.071 pH unit X min-1. After removal of CO2 the pHi increased by 0.65 and the rate of reacidification was 0.056 pH unit X min-1. Exposure to 30 mM NH4Cl caused a raise of pHi by 0.48 pH unit and an initial rate of re-acidification of 0.063 pH unit X min-1, after removal of NH4Cl the pHi fell by 0.58 pH unit below the steady-state pHi, followed by a subsequent re-alkalinization of 0.083 pH unit X min-1. Under both experimental conditions, the pHi recovery after an intracellular acidification, introduced by exposure to 20% CO2 and by removal of NH4+, was found to be inhibited by 53% and 63%, respectively, in the absence of sodium and 60% and 72%, respectively, by 1 mM amiloride. These studies indicate that 31P-NMR can be used to monitor steady-state intracellular pH as well a pHi transients in suspensions of epithelial cells. The results support the view that LLC-PK1 cells use an Na+-H+ exchange system to readjust their internal pH after acid loading of the cell.     

Development of thermotolerance and changes in intracellular pH in CHO cells heated at 45.0 degrees C at pH 6.6

Chinese hamster ovary (CHO) cells were given short heat pulses (5 to 20 min) at 45.0 degrees C and incubated at 37 degrees C for up to 20 h under either pH 7.3 or 6.6 conditions. Thermotolerance developed under both pH conditions, but at a slower rate in the pH 6.6 medium. Intracellular pH (pHi) was measured with the dye, 1,4-diacetoxy-2,3-dicyanobenzene, combined with flow cytometry. Time-dependent changes in the intracellular pH occurred under either pH condition. CHO cells incubated under normal pH conditions had a transient increase in the pHi. This pHi elevation was followed by a rapid intracellular acidification of approximately 0.15 to 0.25 pH units. The timing of both the increases and decreases in the pHi was dependent on the magnitude of the initial heat dose. With heat doses less than or equal to 10 min, the pHi returned to normal unheated levels after the acidification phase. Although cells incubated under low pH (6.6) conditions showed similar pHi alterations, differences in the kinetics were measured. The intracellular pH increased immediately after heating. In addition, when intracellular acidification occurred, the rate of acidification was significantly reduced. With heat doses longer than 5 min under the low pH conditions, the pHi did not return to normal unheated levels.     

Counteractive Effects of ABA and GA3 on Extracellular and Intracellular pH and Malate in Barley Aleurone

Barley (Hordeum vulgare L.) aleurone layers are known to constitutively acidify their surroundings, primarily by L-malic acid release (J. Mikola, M. Virtanen [1980] Plant Physiol 66: S-142). Here we demonstrate the antagonistic effects of the plant hormones gibberellic acid (GA3) and abscisic acid (ABA) on the regulation of extracellular pH (pHe) of barley aleurone layers. We observed a strong correlation between ABA-induced enhancement of extracellular acidification and an ABA-induced increase in L-malic acid release. In addition, ABA caused an increase in intracellular L-malate level. GA3 caused a slight decrease in intracellular L-malate level and was able to inhibit the ABA-induced increase in L-malate intracellular concentration and release. In addition, this ABA-induced L-malate release could be completely inhibited by GA3. The ABA-induced release of L-malic acid could not account for the total ABA-induced pHe decrease, suggesting the existence of an additional mechanism involved in the regulation of pHe. It has been reported that ABA induces an intracellular pH (pHi) increase, possibly due to the activation of plasma membrane proton pumps (R. Van der Veen, S. Heimovaara-Dijkstra, M. Wang [1992] Plant Physiol 100: 699-705). A pHi increase, such as that caused by ABA, might be correlated with the intracellular L-malate increase as suggested by the pH stat model of D.D. Davies ([1986] Physiol Plant 67: 702-706). We studied if the effects of GA3 on L-malate concentration were correlated with changes in pHi and found that GA3 caused a pHi decrease and that GA3 and ABA could interfere in the regulation of pHi. In addition, we were able to mimic the effect of both hormones on L-malate release by bringing about artifical pHi changes with the weak acid 5,5-dimethyl-2,4-oxazolidinedione and the weak base methylamine. The physiological meaning of the effects of GA3 and ABA on the regulation of both pHe and pHi during grain germination are discussed.     

High plasma buffering and the absence of a red blood cell beta-NHE response in brown bullhead (Ameiurus nebulosus)

The high non-bicarbonate buffer capacity of brown bullhead (Ameiurus nebulosus) plasma was postulated to function as an alternative mechanism for the protection of red blood cell (RBC) intracellular pH (pHi) in the absence or attenuation of a RBC adrenergic response. The requirement for protecting RBC pHi arises from the presence of a Root effect haemoglobin in bullhead. In support of this hypothesis, bullhead RBCs incubated in vitro with isoproterenol (10(-8)-10(-5) mol l(-1)) or forskolin (10(-4) mol l(-1)) exhibited significant cyclic AMP accumulation, but failed to exhibit cell swelling or significant Na(+) or Cl(-) accumulation; plasma pH (pHe) was also unaffected. Similarly, no significant effect on RBC water content, Na(+) or Cl(-) concentration, or pHe was detected in bullhead blood incubated with 8-bromo cyclic AMP (10(-4)-10(-2) mol l(-1)) in vitro. These results suggest that while bullhead RBCs possess a beta-adrenoreceptor linked to cyclic AMP formation, stimulation of this adrenergic receptor does not result in measurable activation of a Na(+)/H(+) exchanger.     

Causes and consequences of tumour acidity and implications for treatment

Tumour cells have a lower extracellular pH (pHe) than normal cells; this is an intrinsic feature of the tumour phenotype, caused by alterations either in acid export from the tumour cells or in clearance of extracellular acid. Low pHe benefits tumour cells because it promotes invasiveness, whereas a high intracellular pH (pHi) gives them a competitive advantage over normal cells for growth. Molecular genetic approaches have revealed hypoxia-induced coordinated upregulation of glycolysis, a potentially important mechanism for establishing the metabolic phenotype of tumours. Understanding tumour acidity opens up new opportunities for therapy.     

Intracellular pH changes during the cell cycle in Tetrahymena.

The equilibrium distribution of 5,5-dimethyloxazoladine 2,4-dione (DMO) between intra- and extracellular volume was used to estimate intracellular pH (pHi) in Tetrahymena pyiformis. In control experiments, DMO was found to equilibrate rapidly in response to a pH gradient. Under normal growth conditions, pHi was constant over a finite range of external pH, being maintained near pH 7.1 over the external pH range 5.2 to 7.3. This same range of external pH was also optimal for growth. pHi was monitored during the cell cycle of a synchronous population of T. pyriformis GL. The cells were synchronized either by starvation/refeeding or heat shock. Under both conditions, there were two alkaline shifts of approximately 0.4 pH units per cell cycle. These shifts in pH retained a constant remporal relationship to S phase and were not affected by changes in the time, duration, or magnitude of cytokinesis.     

Simultaneous measurement of water volume and pH in single cells using BCECF and fluorescence imaging microscopy

Regulation and maintenance of cell water volume and intracellular pH (pHi) are vital functions that are interdependent; cell volume regulation affects, and is in turn affected by, changes in pHi. Disruption of either function underlies various pathologies. To study the interaction and kinetics of these two mechanisms, we developed and validated a quantitative fluorescence imaging microscopy method to measure simultaneous changes in pHi and volume in single cells loaded with the fluorescent probe BCECF. CWV is measured at the excitation isosbestic wavelength, whereas pHi is determined ratiometrically. The method has a time resolution of <1 s and sensitivity to osmotic changes of approximately 1%. It can be applied in real time to virtually any cell type attached to a coverslip, independently of cellular shape and geometry. Calibration procedures and algorithms developed to transform fluorescence signals into changes in cell water volume (CWV) and examples of applications are presented.