The 5,5-dimethyloxazolidine-2[14C],4-dione distribution technique and the measurement of intracellular pH in Acer pseudoplatanus cells

The intracellular pH of suspension-cultured Acer pseudoplatanus cells, was estimated from the distribution of 5,5-dimethyloxazolidine-2[¹⁴C],4-dione (DMO) between the culture medium and the cells. The metabolization of DMO in this biological system introduces an error in the calculated intracellular pH value. Three methods are given to overcome this difficulty and to estimate the equilibrium between intracellular and extracellular DMO molecules. A preliminary study has shown that the intracellular pH remains constant about 6.5 when the extracellular pH increases from 5.6 tp 7.3.     

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.     

Amiloride and glucose effects on the intracellular pH of Yoshida rat ascites hepatoma AH-130 cells grown in vivo

The equilibrium distribution of 5,5-dimethyloxazolidine-2,4-dione (DMO) between intra- and extracellular volume was used to estimate the intracellular pH in Yoshida rat ascites hepatoma AH-130 cells under different growth conditions (log, midlog and stationary). The cells were suspended in a Krebs-Ringer 25 mM phosphate buffer and the effects of variation of external pH, of glucose and amiloride addition on intracellular pH were measured. Proliferating cells had higher intracellular pH than stationary phase cells and this difference was inhibited by amiloride. On addition of glucose the fall in external pH was similar in all conditions and corresponded to lactate production. However, the intracellular pH decreased only in proliferating cells. Stationary phase cells showed an amiloride-sensitive cytoplasmic alkalinization with glucose. Glucose addition also caused prompt recovery to a normal polysomal pattern in these cells that might suggest increased efficiency of the initiation step of protein synthesis under these conditions. The data thus suggest that the increased intracellular pH of proliferating and of glucose-treated stationary phase cells is linked to the rate of protein synthesis and is mediated by the amiloride-sensitive Na+/H+ exchange system. This could lead to increased intracellular Na+ concentration under these conditions and to initiation of growth.     

Short-term Measurements of the Cytoplasmic pH of Chara corallina Derived from the Intracellular Equilibration of 5,5-Dimethyloxazolidine-2,4-Dione (DMO)

Smith, F. A. 1986. Short-term measurements of the cytoplasmicpH of Chara corallina derived from the intracellular equilibrationof 5,5-dimethyloxazolidine-2,4-dione (DMO).—J. exp. Bot.37: 1733–1745. Measurements of the time-course of influx of ¹⁴C-labelled 5,5-dimethyloxazolidine-2,4-dione(DMO) into the cytoplasm and vacuole of internodal cells ofChara corallina, and of efflux of DMO into non-radioactive solutions,have shown that exchange of DMO across the tonoplast is veryrapid compared with exchange across the plasma membrane. Thishas made possible calculations of cytoplasmic pH from distributionof DMO between cytoplasm and vacuole over short periods (5 or10 min) even when intracellular DMO is not at flux equilibriumwith external DMO. Using this new method, estimates have beenmade of the rates and magnitude of: (i) acidification of thecytoplasm caused by acidic growth regulators (IAA and NAA) andby metabolic inhibitors (azide, DNP, CCCP and DCMU), and (ii)alkalinization caused by uptake of ammonium and methylammoniumions. The potential application of the method to future studiesof membrane transport in charophyte cells is assessed. Key words: Charophyles, cytoplasmic pH.     

Intracellular acidification inhibits the proliferative response in BALB/c-3T3 cells

One of the earliest events to occur upon the addition of serum to quiescent cells is an increase in the intracellular pH (pHin). The relationship between this pH change and proliferation is not known. In the present study, we investigate the consequences of acidifying the cytosol using the weak acid, 5', 5"-dimethyl oxazolidine 2,4-dione (DMO). At a concentration of 50 mM, DMO inhibits the serum-induced increases in pHin, DNA synthesis, and cell number. This concentration of DMO is shown not to inhibit the steady-state rate of mitochondrial respiration and not to inhibit DNA synthesis in a pH-independent fashion. The effects of DMO treatments are also shown to be reversible, indicating that this compound is not cytotoxic. These observations indicate that DMO inhibits cell proliferation by lowering intracellular pH. One important event that must occur prior to the initiation of DNA synthesis is an elevated rate of protein synthesis. The rate of protein synthesis in situ is extremely pH sensitive. Addition of 50 mM DMO to serum-stimulated cultures reduces the rate of leucine incorporation to unstimulated levels. These observations suggest that cytoplasmic acidification may inhibit proliferation through its effects on protein synthesis.     

5,5′-dimethyloxazolidine-2,4-dione is a strong inducer of differentiation of human promyelocytic leukemia (HL-60) cells

5,5′-Dimethyloxazolidine-2,4-dione (DMO), a weak non-metabolizable acid, is commonly utilized for determining intracellular pH. In these studies, DMO was tested as an inducer of differentiation on the basis that its uptake and subsequent dissociation might transiently raise intracellular pH and activate ion-fluxes critical for triggering maturation. After 5 days of exposure to 40 mM DMO, >60% of HL-60 cells displayed phenotypic and functional changes characteristic of mature granulocytes. As with other inducers of HL-60 cell differentiation, commitment to differentiation required culture in the presence of DMO for more than 24 h, indicating that if transient effects on pH or ion-fluxes occurred, they were not sufficient to trigger this process.DMO was either weak or inactive as an inducer of murine erythroleukemia cell (FLC) differentiation. Although other weak acids and bases triggered differentiation of both HL-60 cells and FLC, the spectrum of response differed markedly between the two lines. These results suggest that: (1) a number of common buffering agents have the potential to alter cell phenotype, and (2) their effects must be evaluated for each individual cell type.     

Osmoregulation in Dunaliella tertiolecta: effects of salt stress,and the external pH on the internal pH

The intracellular pH of the halotolerant green algae Dunaliella tertiolecta, was determined by the distribution of 5,5-dimethyl-2(¹⁴C)-oxalolidine-2,5-dione (DMO) between the cell and the surrounding medium. 5,5-dimethyl-2(¹⁴C)oxalolidine-2,4-dione was not metabolized by the algal cells. The intracellular pH of Dunaliella tertiolecta was 6.8 in the dark and 7.4 in the light. During a salt stress, after two hours, the intracellular pH was increased by 0.2 pH units in both light and dark. The salt stressed cells maintained a constant pH of about 7.5 over the pH range of 6.5 to 8.5. Because of the relatively low permeability coefficient of the plasma membrane for DMO, this technique does not permit rapid pH determinations during the induction period after a salt stress. The magnitude of the salt induced pH changes measured 2 h after the salt stress implies a minor importance of this alkalization in this time range, but does not exclude a larger importance of pH changes for osmoregulation during the induction period.Abbreviations Chl chlorophyll - DMO 5,5-dimethyl-2(¹⁴C)oxalolidine-2,4-dione - PCV packed cell volume - SDS sodium dodecyl sulfate     

Energetics of sucrose transport into protoplasts from developing soybean cotyledons

The accumulation of tetraphenylphosphonium (TPP⁺), 5,5′-dimethyl-oxazolidine-2,4-dione (DMO), and a micro pH electrode were used to measure membrane potential, intracellular and extracellular pH, respectively, upon the addition of exogenous sucrose to soybean cotyledon protoplasts. Addition of sucrose caused a specific and transient (a) depolarization of the membrane potential (measured by TPP⁺ accumulation), (b) acidification of the intracellular pH (measured by DMO accumulation), and (c) alkalization of the external medium (measured by a micro pH electrode). The time course for all these changes was similar (i.e. 5 to 10 minutes). Based on the rate of sucrose uptake and alkalization of the external medium, a stoichiometry of 1.02 to 1.10 for proton to sucrose was estimated. These data strongly support a proton/sucrose cotransporting mechanism in soybean cotyledon cells.     

Effect of glucose on the intracellular pH of pancreatic islet cells.

To characterize the effect of glucose on the intracellular pH (pHi) of pancreatic islet cells, we measured the accumulation of 14C-labelled 5,5-dimethyloxazolidine-2,4-dione ( [14C]DMO) in beta-cell-rich islets from ob/ob mice. D-Glucose (20 mM) stimulated insulin release and enhanced the [14C]DMO equilibrium uptake corresponding to an increase of pHi by about 0.15 unit. The glucose effect on DMO uptake was concentration-dependent, with half-maximal effect at about 4 mM-glucose and maximum effect at about 10 mM-glucose. It was inhibited by 20 mM-mannoheptulose and potentiated by 4 mM-L-5-hydroxytryptophan, but not affected by 2 mM-theophylline. Mannoheptulose is an inhibitor and L-5-hydroxytryptophan and theophylline are potentiators of glucose-stimulated insulin release. The glucose-induced increase in pHi appeared rapidly (7 min) and persisted for at least 30 min and it was observed both in bicarbonate/CO2-buffered and in Hepes [4-(2-hydroxyethyl)-1-piperazine-ethanesulphonic acid]-buffered media. Addition of extracellular bicarbonate buffer lowered the pHi, but did not affect basal insulin release, whereas 5 mM-NH4+ increased pHi and induced a 4-fold increase of basal insulin release. We conclude that, in contrast with previous assumptions, glucose increases intracellular pH in the islet cells. This effect may be coupled to the glucose metabolism and associated with triggering of insulin release.     

Intravesicular pH and iron uptake by immature erythroid cells

The intravesicular pH of intact rabbit reticulocytes was measured by two methods; one based on the intracellular:extracellular distribution of DMO (5, 5, dimethyl + oxazolidin-2,4-dione), methylamine, and chloroquine and the other by quantitative fluorescence microscopy of cell-bound transferrin. The latter method was also applied to nucleated erythroid cells from the fetal rat liver. A pH value of approximately 5.4 was obtained with both methods and in both types of cells. Treatment of the cells with lysosomotrophic agents, metabolic inhibitors, and ionophores elevated the intravesicular pH and inhibited iron uptake from transferrin. When varying concentrations of NH4Cl were used, a close correlation was observed between the inhibition of iron uptake and elevation of the intravesicular pH. At pH 5.4 iron release from rabbit iron-bicarbonate transferrin in vitro was much more rapid than from iron-oxalate transferrin. The bicarbonate complex donates its iron to rabbit reticulocytes approximately twice as quickly as the oxalate complex. It is concluded that the acidic conditions within the vesicles provide the mechanism for iron release from the transferrin molecule after its endocytosis and that the low vesicular pH is dependent on cellular metabolism.     

Regulation of intracellular pH in human neutrophils

The intracellular pH (pHi) of isolated human peripheral blood neutrophils was measured from the fluorescence of 6-carboxyfluorescein (6-CF) and from the equilibrium distribution of [14C]5,5-dimethyloxazolidine -2,4-dione (DMO). At an extracellular pH (pHo) of 7.40 in nominally CO2-free medium, the steady state pHi using either indicator was approximately 7.25. When pHo was suddenly raised from 7.40 to 8.40 in the nominal absence of CO2, pHi slowly rose by approximately 0.35 during the subsequent hour. A change of similar magnitude in the opposite direction occurred when pHo was reduced to 6.40. Both changes were reversible. Intrinsic intracellular buffering power, determined by using graded pulses of CO2 or NH4Cl, was approximately 50 mM/pH over the pHi range of 6.8-7.9. The course of pHi obtained from the distribution of DMO was followed during and after imposition of intracellular acid and alkaline loads. Intracellular acidification was brought about either by exposing cells to 18% CO2 or by prepulsing with 30 mM NH4Cl, while pHo was maintained at 7.40. In both instances, pHi (6.80 and 6.45, respectively) recovered toward the control value at rates of 0.029 and 0.134 pH/min. These rates were reduced by approximately 90% either by 1 mM amiloride or by replacement of extracellular Na with N-methyl-D-glucamine. Recovery was not affected by 1 mM SITS or by 40 mM alpha-cyano-4-hydroxycinnamate (CHC), which inhibits anion exchange in neutrophils. Therefore, recovery from acid loading is probably due to an exchange of internal H for external Na. Intracellular alkalinization was achieved by exposing the cells to 30 mM NH4Cl or by prepulsing with 18% CO2, both at a constant pHo 7.40. In both instances, pHi, which was 7.65 and 7.76, respectively, recovered to the control value. The recovery rates (0.033 and 0.077 pH/min, respectively) were reduced by 80-90% either by 40 mM CHC or by replacement of extracellular Cl with p-aminohippurate (PAH). SITS, amiloride, and ouabain (0.1 mM) were ineffective.(ABSTRACT TRUNCATED AT 400 WORDS)     

Red cell pH of lamprey (Lampetra fluviatilis) is actively regulated

Summary The red cell pH of lamprey (Lampetra fluviatilis) was measured using the DMO method (based on the passive distribution of the wead acid, DMO, across the red cell membrane). The measured red cell pH was higher than the pH of the incubation medium throughout the pH range (7.2–8.2) studied, and higher than the red cell pH calculated from the chloride distribution ratio. Treatment of cells with the metabolic inhibitors 2,4-dinitrophenol or KCN caused a drop in the red cell pH to values lower than the pH of incubation medium, and abolished the difference between the measured red cell pH and the pH calculated from the chloride distribution ratio. These data strongly suggest that the proton gradient across lamprey red cell membrane is actively maintained. Acid extrusion from lamprey red cells may require sodium, as indicated by the observation that when choline was substituted for sodium in the incubation medium, the intracellular pH decreased significantly.     

The Mechanism of Onset of the Stationary Phase in Euglena gracilis Grown with 10 mM Succinate: Intracellular pH Values*

SYNOPSIS. When Euglena gracilis were grown with 10mM succinate at pH 3.5 the extracellular pH averaged 3.62 and the cultures had produced 6 × 10⁵ cells/ml when the stationary phase began. Oxygen consumption values reached a maximum of 30 μliters/10⁶ cells/hr. Total protein and dry weights per cell remained constant during the logarithmic phase and began to decline when the late logarithmic phase was reached. Added succinate caused the cultures in stationary phase to commence logarithmic growth once more. Onset of the stationary phase in cultures grown at pH 3.5 was due to depletion of succinate. When cultures were grown at pH 6.9 the extracellular pH averaged 7.62 and the cultures produced 3 × 10⁵ cells/ml when the stationary phase began. Oxygen consumption values reached a maximum of 20 μliters/10⁶ cells/hr during the logarithmic phase. The decline in total protein and dry weights per cell began at the beginning of the logarithmic phase and continued into the stationary phase of growth. Cultures grown at pH 3.5 should produce a larger number of cells/ml than cultures grown at pH 6.9 if the cells are responding to the unionized moiety of succinate and not the ionized moiety. At pH 3.5 83% of the succinate is unionized, whereas at pH 6.9 0.20% of the succinate is unionized. The onset of the stationary phase in cultures grown at pH 3.5 and pH 6.9 is due to lack of an adequate amount of extracellular unionized succinate. Intracellular pH values were determined in cultures grown at pH 6.9 using the weak acid DMO (5.5-dimethyl-2,4-oxazolidinedione). As the extracellular pH increased from 6.90 to 7.62, the intracellular pH increased from 5.89 to 6.89. As the extracellular pH increased from 7.62 to 8.44, the intracellular pH increased from 6.89 to 7.50.     

The intracellular pH of isolated,photosynthetically active Asparagus mesophyll cells

The intracellular pH of isolated, photosynthetically active mesophyll cells of Asparagus sprengeri Regel has been determined, in the light and dark, by the distribution of the weak acid 5,5-dimethyl-[2-¹⁴C]oxazolidine-2,4-dione ([¹⁴C]DMO) between the cells and the liquid medium. [¹⁴C]DMO was taken up rapidly, reaching equilibrium in 7–10 min of incubation, but was not metabolized by the cells, and intracellular binding of the compound was minimal. The intracellular pH, measured at saturating light fluence and 1.5 mM sodium bicarbonate, was found to remain relatively constant at 6.95–7.21 over the external pH range of 5.5–7.2. Illumination of the cells increased the intracellular pH compared to dark controls. The pH of the cytoplasm, excluding and including the chloroplasts (cytoplasmic and bulk cytoplasmic, respectively) was calculated from the experimentally derived intracellular [¹⁴C]DMO concentration and estimates of the vacuolar, chloroplastic and cytoplasmic volumes. The calculated cytoplasmic pH was similar in the light and dark, being 7.75 and 7.74, respectively, while the calculated pH of bulk cytoplasm was 7.85 in the light and 7.49 in the dark. Theoretical analysis indicated that intracellular pH is a good indicator of changes in the bulk cytoplasmic pH but insensitive to changes in vacuolar pH. The external pH optimum for photosynthesis (O₂ evolution) of isolated Asparagus cells was pH 7.2. At pH 8.0 photosynthesis was inhibited by 30% and at pH 5.25 by 45%. Inhibition at alkaline pH may be the result of a decrease in the pH gradient between the cells and the medium, causing CO₂ limitation in the cell. At acid pH, decrease in internal pH caused by substantial accumulation of inorganic carbon may account for the loss in photosynthetic activity.Abbreviations [¹⁴C]DMO 5,5-dimethyl[2-¹⁴C]oxazolidine-2,4-dione - pH_i overall intracellular pH - pH_e pH of external medium     

Changes in intracellular pH in French-bean nodules induced by senescence and nitrate treatment

Intracellular pH of Phaseolus nodules was determined by using radioactive 5,5-dimethyloxazolidine-2,4-dione (DMO) as a probe. A continuous decline in the intracellular pH was observed when nodule age increased. The extracellular volume of nodules, required for the pH calculation, was the lowest in mature nodules and increased in senescing nodules. Low concentrations of nitrate in the culture medium induced a drop in nitrogen fixation associated with a decrease in the intracellular pH. Acidic proteolysis measured by in vitro hydrolysis of leghemoglobin was strongly stimulated under these conditions. In Phaseolus nodules, senescence and nitrate treatment were similarly characterized by a lower intracellular pH and an active proteolysis which both contributed to a decline in nitrogen fixation capacities.     

Measurement of Cytoplasmic pH by the DMO Technique in Hydrodictyon africanum

The 5, 5-dimethyl-[2-¹⁴C]oxazolidine-2, 4-dione (DMO) distributiontechnique for the measurement of intracellular pH has been appliedto giant cells of Hydrodictyon africanum. Significant metabolism of DMO was found in this alga; the free[DMO + DMO–] in subcellular samples is thus derived fromthe total label in cells equilibrated in [¹⁴C]DMO solutionsby measuring and subtracting the label in metabolic productsof DMO. A further problem arises from the observation that theDMO concentration in the vacuolar sap is always lower than thatpredicted by the transmembrane equilibration of undissociatedDMO from the bathing medium. This is interpreted in terms ofa finite permeability to the anion DMO–. Since the effectof P_DMO– on the DMO distribution is much smaller at thetonoplast (where the transmembrane electrical potential differenceis small) than at the plasmalemma, the values of cytoplasmicpH are computed assuming equilibration of undissociated DMOacross the tonoplast. At an external pH of 7.0 the cytoplasmic pH is about 7.4; decreaseor increase of external pH by 1 unit causes a decrease and anincrease in cytoplasmic p11 respectively of about 0.2 pH units.Determinations of _vo at pH 6, 7, and 8, together with an assumedconstant value of _cv, permit calculations of µ_H+ at theplasmalemma and tonoplast. The values are relatively independentof external pH in the range pH 6–8 at 21–25 and12–14 kJ mol^–1 respectively. The significance ofthese results for the regulation of intracellular pH, and forthe regulation and energising of the fluxes of ions, is discussed.     

pH homeostasis in human lymphocytes: modulation by ions and mitogen

Quiescent human peripheral blood lymphocytes have been shown to maintain a relatively constant intracellular pH of 7.0-7.2 over an extracellular pH range of 6.9-7.4. Two methods of measuring intracellular pH were used in these studies, 19F nuclear magnetic resonance and [14C]5,5-dimethyloxazolidine-2,4-dione (DMO) equilibrium distributions. When ATP levels were decreased in these cells, actively maintained pH regulation was abolished and cells exhibited a constant pH gradient of 0.2 pH unit (acid inside relative to outside). Possible mechanisms for pH regulation are discussed. The effects of the Na+ and K+ composition of the medium on pH regulation showed no correlation with their effects on mitogen-induced proliferative response, which we have previously determined (Deutsch, C., and M. Price, 1982, J. Cell. Physiol., 111:73-79). In low-Na+ mannitol medium, pH regulation was similar to that observed for lymphocytes in normal medium, whereas mitogen-induced proliferation was severely inhibited in low-Na+ mannitol. In contrast, high-K+, low Na+ medium caused loss of pH homeostasis, whereas it restored the proliferative response. Loss of pH homeostasis was also observed on prolonged exposure of lymphocytes to mitogen (greater than 6 h in culture). However, mitogen stimulation led to little or no change in intracellular pH in the first few hours of cell culture. Therefore, a shift in intracellular pH is not a necessary or general event in mitogen-stimulated proliferation of lymphocytes.     

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.