Intracellular pH control in Dictyostelium discoideum: a 31P-NMR analysis

Phosphorus metabolites and intracellular pH have been examined in the slime mold Dictyostelium discoideum by non-destructive 31P-NMR measurements. In a spectrum from a suspension of aerobic amoebae, the major peaks are inorganic phosphate, nucleotide di- and triphosphates. In the corresponding perchloric acid extract, resonances originating from purine and pyrimidine nucleotides are resolved. Adenine nucleotides are the most abundant components, but the other nucleotides are present in significant amounts. In a spectrum from intact spores in a dormant state, only inorganic phosphate and polyphosphates are detected and nucleotides are no longer present in large amounts. Of particular importance is the ability to observe separately in aerobic amoebae the resonance of inorganic phosphate localized in two different cell compartments: the cytosol and the mitochondria. The cytosolic pH and mitochondrial pH have been measured as 6.7 and 7.7, respectively, on the basis of intracellular inorganic phosphate chemical shifts. They are essentially unaffected over a large range of external pH and they are not modified transiently or permanently during the initiation of the developmental program of the organism. A weak acid, such as propionate, which modifies the progression of differentiation by favoring prestalk cells, perturbs intracellular pH gradients by selectively decreasing mitochondrial pH without any effect on cytosolic pH.     

Intracellular pH Regulation in an Acidophilic Unicellular Alga, Cyanidium caldarium: 31P-NMR Determination of Intracellular pH

The intracellular pH of an acidophilic unicellular alga, Cyanidiumcaldarium, was determined as a function of external pH by ³¹Pnuclear magnetic resonance. The algal cells incubated underaerobic conditions or under anaerobic and illuminated conditionsmaintained the intracellular pH in the range from 6.8 to 7.0even when the external pH was changed from 1.2 to 8.4. Underanaerobic and dark conditions, however, the intracellular pHacidified at the acidic pH region of the external medium. Theacidified intracellular pH reversibly returned to neutral eitheron aeration or illumination. The results indicate that, in Cyanidiumcells growing in extremely acidic environments, an active H⁺efflux (H⁺ pump) which depends on metabolic activity (respirationor photosynthesis) is essential to maintain the intracellularpH at a constant physiological level against the passive H⁺leakage due to the steep pH gradient across the cell membrane. (Received March 19, 1986; Accepted July 17, 1986)     

Intracellular pH and Proton-Transport in Barley Root Cells under Salt Stress: in Vivo 31P-NMR Study

Salt stress-induced changes of intracellular pH and in levelsof phosphorous compounds were monitored in intact root tipsof barley seedlings (Hordeum vulgare cv. Akashin-riki) by invivo ³¹P-nuclear magnetic resonance (NMR) spectroscopy. Vacuolaralkalization was observed after treatment with both 300 and500 mM NaCl. Much of the observed apparent alkalization of thecytoplasm was eliminated when the effect of Na⁺ ions on thetitration curve was considered. Within 1 h after the initiationof salt stress, levels of glucose-6-phosphate and UDP-glucosedecreased markedly, and such decreases might lead directly orindirectly to cell death. Simultaneous measurements of the externaland intracellular pH revealed the promotion of external acidificationand internal alkalization during salt stress. Possible mechanismsof Na⁺/H⁺ antiport at the tonoplast and the role of proton-pumpin the plasma membrane are discussed. ³Present address: Shijonawate Gakuen Women's Junior College,Daito, Osaka, 574 Japan.     

Intracellular pH determination by a 31P-NMR technique. The second dissociation constant of phosphoric acid in a biological system

To evaluate the accuracy of pH determination by 31P-NMR, factors which influence the pK value of phosphate were appraised on the basis of the titration of 1 mM phosphate buffer solution. When the method is used for the determination of cytoplasmic pH, ionic strength is the major factor causing shifts of apparent pK (pK') value, and the magnitude of the shift can be predicted from the ionic strength calculated by means of the Debye-Hückel equation. Ions (Na+, K+, Mg2+, and Ca2+) and salivary protein affected the pK' value by 0.1 to 0.3 units in solution with a given ionic strength depending on the species of ion. The form of the titration curve varied with temperature. Based on these results, the value of 6.75 was obtained with the uncertainty of 0.12 for the intracellular pK' of frog muscle at 24 degrees C.     

Microviscosity of human erythrocytes studied with hypophosphite and 31P-NMR

A 31P-NMR method, which complements earlier 13C-NMR procedures for probing the intra-erythrocyte microenvironment, is described. Hypophosphite is an almost unique probe of the erythrocyte microenvironment, since it is rapidly transported into the cell via the band 3 protein, and intra- and extracellular populations give rise to distinct resonances in the 31P-NMR spectrum. Relaxation mechanisms of the 31P nucleus in the hypophosphite ion were shown to be spin-rotation and dipole-dipole. Analysis of longitudinal relaxation rates in human erythrocytes, haemolysates and concentrated glycerol solutions allowed the determination of microviscosity using the Debye equation. Bulk viscosities of lysates and glycerol solutions were measured using Ostwald capillary viscometry. Translational diffusion coefficients were then calculated from the viscosity estimates using the Stokes-Einstein equation. The results with a range of solvent systems showed that 'viscosity' is a relative phenomenon and that bulk (i.e., macro-) viscosity is therefore not necessarily related to the NMR-determined viscosity. The intracellular NMR-determined viscosities from red cells, ranging in volume from 65.5 to 100.1 fl, varied from 2.10 to 2.67 mPa s. This is consistent with the translational diffusion coefficients of the hypophosphite ion altering by only 20%, whereas the values determined from bulk viscosity measurements conducted on lysates of these cells are consistent with a 230% change.     

Characterization of methylphosphonate as a 31P NMR pH indicator

The 31P NMR pH indicator, methylphosphonate, has been extensively characterized, and the uncertainty in pH determination by its chemical shift has been analyzed. The pKa decreases by 0.003 pH unit/degrees C and 0.06 pH unit/100 mM ionic strength. The pKa appears not to be sensitive to Ca2+ but is sensitive to Mg2+, resulting in an uncertainty of +/- 0.05 pH unit. Substituting 300 mM Na+ for 300 mM K+ causes the pKa to decrease by 0.1 pH unit. Taking the effects of temperature, ionic strength, and cation identity into account, the overall estimated uncertainty in pH determination can be as high as +/- 0.1 pH unit. Methylphosphonate was tested as a pH indicator in Ehrlich ascites tumor cells. Our data indicate that both the unchanged and monoanion forms of methyl phosphonate are very permeable, rendering this compound unsuitable as a pH indicator in this system. However, the sensitivity of this compound's chemical shift to pH and the relative insensitivity to other parameters suggest that phosphonates, as a group, may be applicable as pH indicators by 31P NMR.     

Further investigation of the use of dimethyl methylphosphonate as a 31P-NMR probe of red cell volume

We have refined a method for measuring erythrocyte volume using the 31P-NMR spectrum of a probe molecule, dimethyl methylphosphonate. This compound, when added to an erythrocyte suspension, gives rise to two 31P-NMR resonances, and the frequency separation between them is linearly dependent on the intracellular haemoglobin concentration. If, for a given cell sample (under standard conditions), the separation of the two dimethyl methylphosphonate peaks has been measured and an independent estimation of the mean cell haemoglobin content and concentration has been obtained, then changes in the mean cell volume due to altered experimental conditions may be estimated from the peak separation measured under the new conditions. Although the peak separation was independent of extracellular pH, it did vary with (i) a range of extracellular suspension media, (ii) temperature, (iii) dimethyl methylphosphonate concentration, (iv) haemoglobin ligand state and (v) different blood donors.     

Intra- and extracellular pH of the brain in vivo studied by 31P-NMR during hyper- and hypocapnia.

Studies were performed to determine the pH relationships among the extracellular, intracellular, and arterial blood compartments in the brain in vivo. Resolution of the extracellular monophosphate resonance peak from the intracellular peak in 31P nuclear magnetic resonance (NMR) spectra of sheep brain with the calvarium intact enabled pH measurement in these respective compartments. Sheep were then subjected to both hyper- and hypoventilation, which resulted in a wide range of arterial PCO2 and pH values. Linear regression analysis of pH in these compartments yielded slopes of 0.56 +/- 0.05 for extracellular pH (pHe) vs. arterial pH, 0.43 +/- 0.078 for intracellular pH (pHi) vs. pHe, and 0.23 +/- 0.056 for pHi vs. arterial pH. These data indicate that CO2 buffering capacity is different and decreases from the intracellular to extracellular to arterial blood compartments. Separation of the extracellular space from the vascular space may be a function of the blood-brain barrier, which contributes to the buffering capability of the extracellular compartment. A marked decrease in the pH gradient between the extracellular and intracellular space occurs during hypercarbia and may influence mechanisms of central respiratory control.     

Changes in Cytoplasmic pH Measured by 31P-NMR in Cells of Nitellopsis obtusa

The cytoplasmic pH of Nitellopsis obtusa measured by the ³¹P-nuclearmagnetic resonance method was about 7.3. Since normal cell havea large vacuole, a long period of time is needed to accumulatesignals for cytoplasmic phosphate. To measure the cytoplasmicpH in a shorter period, cytoplasm-rich cells were prepared bycentrifugation. The cytoplasmic pH of these cells was also about7.3. Illumination reversibly increased the cytoplasmic pH from7.3 to 7.8. When the cytoplasm-rich cell was illuminated, themembrane potential hyperpolarized concomitant with the alkalificationof the cytoplasm. (Received December 5, 1983; Accepted May 12, 1984)     

Phosphorus metabolism and intracellular pH in the halotolerant alga Dunaliella parva studied by 31P-NMR

The metabolism of the green unicellular halotolerant alga Dunaliella parva was studied by means of ³¹P nuclear magnetic resonance spectroscopy. The major soluble phosphate compounds were found to be similar to those in other organisms but two phosphodiesters, glycerophosphorylglycerol and glycerophosphorylcholine, were identified in algal tissue for the first time. Only a single pool of intracellular orthophosphate was observed and the chemical shift of the corresponding resonance was used to monitor the intracellular pH. The cell pH and the orthophosphate content were sensitive both to the oxygenation of the cells and to the illumination of the cell suspension. The intracellular pH was controlled over an external pH range of 6–9, but at pH 5 the cell contents became acidic. Carbonyl cyanide p-trifluoromethoxyphenylhydrazone was observed to uncouple oxidative phosphorylation but it did not equilibrate the pH difference across the cell membrane in experiments conducted at an external pH of 7.8.     

Intracellular pH control in Dictyostelium discoideum: A P-NMR analysis

Phosphorus metabolites and intracellular pH have been examined in the slime mold Dictyostelium discoideum by non-destructive ³¹P-NMR measurements. In a spectrum from a suspension of aerobic amoebae, the major peaks are inorganic phosphate, nucleotide di- and triphosphates. In the corresponding perchloric acid extract, resonances originating from purine and pyrimidine nucleotides are resolved. Adenine nucleotides are the most abundant components, but the other nucleotides are present in significant amounts. In a spectrum from intact spores in a dormant state, only inorganic phosphate and polyphosphates are detected and nucleotides are no longer present in large amounts.Of particular importance is the ability to observe separately in aerobic amoebae the resonance of inorganic phosphate localized in two different cell compartments: the cytosol and the mitochondria. The cytosolic pH and mitochondrial pH have been measured as 6.7 and 7.7, respectively, on the basis of intracellular inorganic phosphate chemical shifts. They are essentially unaffected over a large range of external pH and they are not modified transiently or permanently during the initiation of the developmental program of the organism. A weak acid, such as propionate, which modifies the progression of differentiation by favoring prestalk cells, perturbs intracellular pH gradients by selectively decreasing mitochondrial pH without any effect on cytosolic pH.     

Polyphosphoinositides undergo charge neutralization in the physiological pH range: a 31P-NMR study

The charge state of phosphatidylinositol 4-phosphate and phosphatidylinositol 4,5-bisphosphate was determined as a function of pH by way of 31P-NMR spectroscopy. The pK values for the first protonation of the phosphomonoester residues in phosphatidylinositol 4-phosphate and phosphatidylinositol 4,5-bisphosphate were found to be 6.2 and 6.6, respectively, for the 4-phosphate moiety, and 7.7 for the 5-phosphate moiety.     

Possibility of the evaluation of the functional activity of human erythrocytes using the 31P-NMR method

Intact human erythrocytes from venous blood were investigated. It has been found that the width and form of signals of 2.3 DFG vary strongly, but for the given person these characteristics of the signals are stable parameters. These variations were shown to correspond to the degree of inhomogeneity of erythrocytes population in venous blood as regards their relative concentrations of Hb and HbO2. The width of the signals of 2.3 DFG, so far reflects functional activity of the human red blood cells in oxygen transport.     

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.     

31P-NMR study of high-energy phosphorylated compounds metabolism and intracellular pH in the perfused rat heart

Using 31P-NMR and haemodynamical measurements, this work assesses different aspects of myocardial preservation improvement during a global ischaemia, based on a simultaneous and correlated study of high-energy phosphorylated compounds, intracellular pH and left ventricular function. Isolated perfused working rat hearts were subjected to 2 or 3 h of hypothermic ischaemia followed by 30 or 45 min of reperfusion. A study of the influence of pH and buffer used in cardioplegic solutions has demonstrated a better preservation of high-energy phosphates and an improved functional recovery when using a pH 7.0, glutamate - containing solution. Protection provided by cardioplegia can be enhanced by the appropriate use of a fluorocarbon-oxygenated cardioplegic reperfusate. The use of nifedipine, a calcium antagonist, in the cardioplegic solutions, does not provide any additional protection under hypothermic conditions.     

31P-NMR study of kinetics of 2,3-diphosphoglycerate degradation in human erythrocytes during their depletion

2.3-Diphosphoglycerate degradation kinetics was studied under conditions of human erythrocyte depletion, using the method of 31P-NMR of high performance. The kinetic curve was shown to have a plateau during the first 1.5-2 hours after the beginning of depletion. Possible mechanisms providing for the appearance of such a plateau are discussed.     

Measurement of an intracellular pH rise after fertilization in crab eggs using 31P-NMR

The effect of fertilization upon the intracellular pH, pH_i, in crab ovulated eggs was examined by ³¹P-NMR. The pH_i values were obtained from the chemical shift differences between the phosphoarginine PA resonance and the inorganic phosphate P_i resonance. The detection of the P_i peak was accomplished by Hahn spin-echo experiments in order to cancel the broad signal arising from phosphoproteins which overlaps the P_i signal. The average pH_i of the unfertilized unactivated eggs was 6.55 and a rise of 0.12 pH unit occurred after fertilization.