Effect of External pH on the Internal pH of Chlorella saccharophila

The overall internal pH of the acid-tolerant green alga, Chlorella saccharophila, was determined in the light and in the dark by the distribution of 5,5-dimethyl-2-[¹⁴C]oxazolidine-2,4-dione ([¹⁴C]DMO) or [¹⁴C]benzoic acid ([¹⁴C]BA) between the cells and the surrounding medium. [¹⁴C]DMO was used at external pH of 5.0 to 7.5 while [¹⁴C]BA was used in the range pH 3.0 to pH 5.5. Neither compound was metabolized by the algal cells and intracellular binding was minimal. The internal pH of the algae obtained with the two compounds at external pH values of 5.0 and 5.5 were in good agreement. The internal pH of C. saccharophila remained relatively constant at pH 7.3 over the external pH range of pH 5.0 to 7.5. Below pH 5.0, however, there was a gradual decrease in the internal pH to 6.4 at an external pH of 3.0. The maintenance of a constant internal pH requires energy and the downward drift of internal pH with a drop in external pH may be a mechanism to conserve energy and allow growth at acid pH.     

Extent of intracellular pH changes during H+ extrusion by maize root-tip cells

³¹P-Nuclear-magnetic-resonance spectra of maize (Zea mays L.) root tips, that had been induced to extrude large amounts of H⁺ in response to fusicoccin (FC) in the presence of potassium salts, indicate that the cytoplasmic pH does not become higher than that of controls. In fact, the cytoplasmic pH may become slightly (approx. 0.1 pH unit) lower in cells extruding H⁺. Estimations of the buffer capacity of the cells show that without active intracellular pH regulation, H⁺ extrusion caused by FC would cause the intracellular pH to rise by at least 0.6 pH unit h^-1. Our results indicate that intracellular pH is tightly regulated even during extreme rates of acid extrusion, and that a rise in cytoplasmic pH is not the signal linking H⁺ extrusion with enhanced organic-acid synthesis or other intracellular responses to H⁺ pumping.Abbreviations FC fusicoccin - P_i inorganic phosphate - NMR nuclear magnetic resonance - chemical shift - MDP methylene diphosphonic acid     

Manipulating cytoplasmic pH under anoxia: A critical test of the role of pH in the switch from aerobic to anaerobic metabolism

Ethanol production by maize (Zea mays L.) root tips, measured by an enzymic assay of the suspending medium, was correlated with changes in the cytoplasmic pH, determined by in-vivo ³¹P nuclear magnetic resonance (NMR) spectroscopy, following the onset of anoxia. Strong evidence for the role of the cytoplasmic pH in triggering the switch to ethanol production under anoxia was obtained by: (i) varying the pH of the suspending medium between pH 4 and pH 10; and (ii) using the permeant weak base methylamine to combat the acidification of the cytoplasm induced by the anoxic conditions. Experimentally, it proved to be much easier to manipulate the cytoplasmic pH under anoxia after the pH had stabilised, rather than during the initial rapid acidification that occurred following the onset of anoxia, and in the presence of methylamine, it was possible to impose a normal aerobic cytoplasmic pH value on tissue that was metabolising anaerobically. By this means it was possible to demonstrate the reversibility of the pH effect on ethanol production under anoxia and thus to provide good evidence in support of the biochemical pH-stat model of the anoxic response. The NMR measurement of the cytoplasmic pH in the presence of methylamine was achieved by using a manganese pretreatment technique to eliminate interference between the cytoplasmic and vacuolar P_i signals, and it seems likely that the experimental approach used here will have further applications in studies of the metabolic response to anoxia.Abbreviations Caps 3-(cyclohexylamino)-1-propane sulphonic acid - Mes 2-(N-morpholino)-ethane sulphonic acid - NMR nuclear magnetic resonance - Pi inorganic phosphate We acknowledge the financial support of the Agricultural and Food Research Council and G.G.F. acknowledges the receipt of a Research Fellowship from the Royal Commission for the Exhibition of 1851.     

The dependence of the cytoplasmic pH in aerobic and anaerobic cells of the green algae Chlorella fusca and Chlorella vulgaris on the pH of the medium as determined by 31P in vivo NMR spectroscopy

The pH in the cytoplasm of aerobic and anaerobic cells of the green algae Chlorella fusca and Chlorella vulgaris was determined in dependence on the pH of the external medium, which was varied between pH 3 and pH 10. In aerobic cells of both species the cytoplasmic pH is maintained at a value above 7.2 even at an external pH of 3 and below 7.8 at an external pH of 10. In anaerobic cells the cytoplasmic pH shows linear dependence on external pH in the range of pH 6 to 9 (cytoplasmic pH 6.9 to 7.2), while below an external pH of 6 cytoplasmic pH is maintained at about 6.5.Abbreviations CCCP Carbonylcyanide-m-chlorophenyl-hydrazone - EDTA Ethylendiaminetetraacetic acid - MES 2-(N-Morpholino)-ethanesulfonic acid - MOPSO 3-(N-Morpholino)-2-hydroxy-propanesulfonic acid - NMR Nuclear Magnetic Resonance - pH cyt cytoplasmic pH - pH ex external pH - PIPES Piperazine-N,N-bis(2-ethanesulfonic acid) - PP_i Pyrophosphate - PP₁, PP₂, PP₃ 1st, 2nd, 3rd phosphate group of polyphosphates - PP₄ core phosphate groups of polyphosphates - TRIS Tris-hydroxymethyl-aminomethane     

Regulation of Vacuolar pH of Plant Cells: II. A P NMR Study of the Modifications of Vacuolar pH in Isolated Vacuoles Induced by Proton Pumping and Cation/H Exchanges

The vacuolar pH and the trans-tonoplast ΔpH modifications induced by the activity of the two proton pumps H⁺-ATPase and H⁺-PPase and by the proton exchanges catalyzed by the Na⁺/H⁺ and Ca²⁺/H⁺ antiports at the tonoplast of isolated intact vacuoles prepared from Catharanthus roseus cells enriched in inorganic phosphate (Y Mathieu et al 1988 Plant Physiol [in press]) were measured using the ³¹P NMR technique. The H⁺-ATPase induced an intravacuolar acidification as large as 0.8 pH unit, building a trans-tonoplast ΔpH up to 2.2 pH units. The hydrolysis of the phosphorylated substrate and the vacuolar acidification were monitored simultaneously to estimate kinetically the apparent stoichiometry between the vectorial proton pumping and the hydrolytic activity of the H⁺-ATPase. A ratio of H⁺ translocated/ATP hydrolyzed of 1.97 ± 0.06 (mean ± standard error) was calculated. Pyrophosphate-treated vacuoles were also acidified to a significant extent. The H⁺-PPase at 2 millimolar PPi displayed hydrolytic and vectorial activities comparable to those of the H⁺-ATPase, building a steady state ΔpH of 2.1 pH units. Vacuoles incubated in the presence of 10 millimolar Na⁺ were alkalinized by 0.4 to 0.8 pH unit. It has been shown by using ²³Na NMR that sodium uptake was coupled to the H⁺ efflux and occurred against rather large concentration gradients. For the first time, the activity of the Ca²⁺/H⁺ antiport has been measured on isolated intact vacuoles. Ca²⁺ uptake was strongly inhibited by NH₄Cl or gramicidin. Vacuoles incubated with 1 millimolar Ca²⁺ were alkalinized by about 0.6 pH unit and this H⁺ efflux was associated to a Ca²⁺ uptake as demonstrated by measuring the external Ca²⁺ concentration with a calcium specific electrode. Steady state accumulation ratios of Ca²⁺ as high as 100 were reached for steady state external concentrations about 200 micromolar. The rate of Ca²⁺ uptake appeared markedly amplified in intact vacuoles when compared to tonoplast vesicles but the antiport displayed a much lower affinity for calcium. The different behavior of intact vacuoles compared to vesicles appears mainly to be due to differences in the surface to volume ratio and in the rates of dissipation of the pH gradient. Despite its low affinity, the Ca²⁺/H⁺ antiport has a high potential capacity to regulate cytoplasmic concentration of calcium.     

Effects of Environmental pH on the Internal pH of Chlorella pyrenoidosa, Scenedesmus quadricauda, and Euglena mutabilis

The effect of external pH on two laboratory-cultured acid-intolerant species (Chlorella pyrenoidosa Chick and Scenedesmus quadricauda Turp. Bréb.) and one acid-tolerant species from a natural population (Euglena mutabilis Schmitz) was examined by measuring internal pH. These measurements were made with the weak acid ¹⁴C-dimethyloxazolidine-2,4-dione after cells had been incubated for 2 and 6 hours at external pH levels from 3.0 to 8.0. Photosynthetic and respiration rates of the three species were also measured over the range of external pH levels.     

A 31P-NMR study of the cross-membrane pH gradient induced by ATP hydrolysis in mitochondria

³¹P-NMR has been used to study the increase of ΔpH in mitochondria by externally added ATP. Freshly prepared mitochondria was treated with N-ethylmaleimide to inhibit the exchange between internal and external P_i. Upon addition of ATP, phosphocreatine (30 mM) and creatine kinase to a NMR sample of mitochondria suspension (approx. 120 mg protein/ml) at 0°C, an increase of ΔpH by approx. 0.5 pH unit was observed. However the increased ΔpH could not be maintained, but slowly decayed along with the increase of external ADP/ATP ratio. Further addition of valinomycin to the suspension induced a larger ΔpH (approx. 1) which was maintained by the increased rate of internal ATP hydrolysis as seen in the growth of the internal P_i peak intensity in NMR spectra and the concomitant decrease of the external phosphocreatine peak. The external P_i and ATP peaks stayed virtually constant. When carboxyatractyloside was added to inhibit the ATP/ADP translocase, the internal P_i increase was stopped and the ΔpH decayed. These observations in conjunction with those made earlier in respiring mitochondria clearly show the reversible nature of the ATPase function in which the internal ATP hydrolysis is associated with outward pumping of protons.     

Effect of Elicitation and Changes in Extracellular pH on the Cytoplasmic and Vacuolar pH of Suspension-Cultured Soybean Cells

We have employed both ³¹P nuclear magnetic resonance spectroscopy and two intracellular fluorescent pH indicator dyes to monitor the pH of the vacuole and cytoplasm of suspension-cultured soybean cells (Glycine max Merr cv Kent). For the ³¹P nuclear magnetic resonance studies, a flow cell was constructed that allowed perfusion of the cells in oxygenated growth medium throughout the experiment. When the perfusion medium was transiently adjusted to a pH higher than that of the ambient growth medium, a rapid elevation of vacuolar pH was observed followed by a slow (approximately 30 minute) return to near resting pH. In contrast, the concurrent pH changes in the cytoplasm were usually fourfold smaller. These data indicate that extracellular pH changes are rapidly communicated to the vacuole in soybean cells without significantly perturbing cytoplasmic pH. When elicitors were dissolved in a medium of altered pH and introduced into the cell suspension, the pH of the vacuole, as above, quickly reflected the pH of the added elicitor solution. In contrast, when the pH of either a polygalacturonic acid or Verticillium dahliae elicitor preparation was adjusted to the same pH as the ambient medium, no significant change in either vacuolar or cytoplasmic pH was observed during the 35 minute experiment. These results were confirmed in experiments with pH-sensitive fluorescent dyes. We conclude that suspension-cultured soybean cells do not respond to elicitation by significantly changing the pH of their vacuolar or cytoplasmic compartments.     

Regulation of Cytoplasmic and Vacuolar pH in Maize Root Tips under Different Experimental Conditions

³¹P-Nuclear magnetic resonance spectra of perfused maize (Zea mays L., hybrid WW x Br 38) root tips, obtained at 10-minute intervals over 12 hours or longer, indicate that no cytoplasmic or vacuolar pH changes occur in these cells in the presence of 25 millimolar K₂SO₄, which induces extrusion of 4 to 5 microequivalents H⁺ per gram per hour. In contrast, hypoxia causes cytoplasmic acidification (0.3-0.6 pH unit) without a detectable change in vacuolar pH. The cytoplasm quickly returns to its original pH on reoxygenation. Dilute NH₄OH increases the vacuolar pH more than it does the cytoplasmic pH; after NH₄OH is removed, the vacuole recovers its original pH more slowly than does the cytoplasm. The results indicate that regulation of cytoplasmic pH and that of vacuolar pH in plant cells are separate processes.     

Phosphorus-31 and Nitrogen- 14 NMR Studies of the Uptake of Phosphorus and Nitrogen Compounds in the Marine Macroalgae Ulva lactuca

Cytoplasmic phosphomonoesters and inorganic phosphate, as well as vacuolar inorganic phosphate and polyphosphates, gave rise to the major peaks in ³¹P nuclear magnetic resonance (NMR) spectra of the marine macroalgae Enteromorpha sp., Ceramium sp., and Ulva lactuca which were collected from the sea. In contrast, NMR-visible polyphosphates were lacking in Pylaiella sp. and intracellular vacuolar phosphate seemed to act as the main phosphorus store in this organism. In laboratory experiments, polyphosphates decreased in growing U. lactuca which was cultivated in continuous light under phosphate-deficient conditions. In contrast, the same organism cultivated in seawater with added phosphate and ammonium, accumulated phosphate mainly in the form of polyphosphates. When nitrate was provided as the only nitrogen source, accumulation of polyphosphates in the algae decreased with increasing external nitrate concentration. From the chemical shift of the cytoplasmic Pi peak, the cytoplasmic pH of superfused preparations of Ulva was estimated at 7.2. The vacuolar pH, determined from the chemical shifts of the vacuolar Pi and the terminal polyphosphate peaks, was between 5.5 and 6.0. The intracellular nitrate and ammonium levels in U. lactuca were determined by ¹⁴N NMR. Both nitrogen sources were taken up and stored intracellularly; however, the uptake of ammonium was much faster than that of nitrate.     

Relationship between intracellular pH and N metabolism in maize (Zea mays L.) roots

In vivo ³¹P nuclear magnetic resonance (NMR) was used to characterize the effect of the N form (NO₃ vs. NH₄) and the external pH (4, 6, and 8), on the intracellular pH of root tips (0–5 mm) and root segments (5–30 mm). Ammonium-grown root tips were the most sensitive to changes in the external pH. In vivo ¹⁵N NMR was used to characterize the pathway of primary ammonium assimilation in the ammonium-grown roots and to compare the activity of the apical and more-basal root parts. The kinetics of ¹⁵NH₄ ⁺ incorporation showed that primary assimilation in both root tips and root segments followed the glutamine synthetase (GS) pathway. In agreement with the reported gradient of GS along the seminal root of maize, incorporation of label into glutamine amide was more rapid in tips than in segments. It is suggested that this higher GS activity increases the endogenous proton production and thus contributes to the greater dependence of the cytoplasmic pH on the external pH in the ammonium-treated root tips.     

Effect of External pH on the Cytoplasmic and Vacuolar pHs in Mung Bean Root-Tip Cells: A 31P Nuclear Magnetic Resonance Study

The effect of the external pH on the intracellular pH in mungbean (Vigna mungo (L.) Hepper) root-tip cells was investigatedwith the ³¹P nuclear magnetic resonance (NMR) method. The ³¹PNMR spectra showed three peaks caused by cytoplasmic G-6-P,cytoplasmic P_i and vacuolar P_i. The cytoplasmic and vacuolarpHs could be determined by comparing the P_i chemical shiftswith the titration curve. When the external pH was changed overa range from pH 3 to 10, the cytoplasmic pH showed smaller changesthan the vacuolar pH, suggesting that the former is regulatedmore strictly than the latter. The H⁺-ATPase inhibitor, DCCD,caused the breakdown of the mechanism that regulates the intracellularpH. H⁺-ATPase appears to have an important part in the regulationof the intracellular pH. (Received January 4, 1984; Accepted August 27, 1984)     

Effects of external pH,fusicoccin and butyrate on the cytoplasmic pH in barley root tips measured by 31P-nuclear magnetic resonance spectroscopy

³¹P-Nuclear magnetic resonance spectroscopy was used to measure the cytoplasmic pH (pH_c) in barley (Hordeum vulgare L.) root tips. As the external pH was raised from 4–10, pH_c was found to increase from 7.44 to 7.75. The sensitivity of pH_c to changes in external pH decreased with increasing external pH. Metabolic inhibition by sodium azide caused pH_c to fall by 0.3 units. Addition of 10 mM butyrate resulted in a gradual decline in pH_c, by approx. 0.3 units over 90 min. At a concentration of 1 mM, butyrate had no effect on pH_c even after 2 h. Fusicoccin caused pH_c to rise by 0.1–0.2 units. In maize (Zea mays L.) root tips, pH_c was shown to have a similar sensitivity to fusicoccin. The results are discussed in relation to the regulation of pH_c and the possible role of pH_c in determining transmembrane electrical potential differences.Abbreviations and symbols FC Fusicoccin - NMR nuclear magnetic resonance - p.d. membrane electrical potential difference - pH_c cytoplasmic pH - P1 inorganic phosphate - chemical shift     

Effect of Indoleacetic Acid- and Fusicoccin-Stimulated Proton Extrusion on Internal pH of Pea Internode Cells

Using ³¹P nuclear magnetic resonance spectroscopy, we followed cytoplasmic and vacuolar pH in pea (Pisum sativum cv Alaska) internode segments during treatment with indoleacetic acid (IAA) or fusicoccin (FC) in continuously perfused, oxygenated buffer. Although IAA and FC induced normal H⁺ extrusion, elongation, and glucan synthase activity responses during the measurements, neither the cytoplasmic nor the vacuolar pH showed significant change at any time between 5 minutes and 1 to 3 hours of treatment. Changes in cytoplasmic pH as small as about 0.04 pH unit were detected after treatment with 1-naphthyl acetate. Therefore, cytoplasmic pH changes do not appear to mediate IAA or FC stimulation of H⁺ extrusion or other metabolic responses to these effectors.     

Regulation of Vacuolar pH of Plant Cells: I. Isolation and Properties of Vacuoles Suitable for P NMR Studies

For the first time, the ³¹P nuclear magnetic resonance technique has been used to study the properties of isolated vacuoles of plant cells, namely the vacuolar pH and the inorganic phosphate content. Catharanthus roseus cells incubated for 15 hours on a culture medium enriched with 10 millimolar inorganic phosphate accumulated large amounts of inorganic phosphate in their vacuoles. Vacuolar phosphate ions were largely retained in the vacuoles when protoplasts were prepared from the cells and vacuoles isolated from the protoplasts. Vacuolar inorganic phosphate concentrations up to 150 millimolar were routinely obtained. Suspensions prepared with 2 to 3 × 10⁶ vacuoles per milliliter from the enriched C. roseus cells have an internal pH value of 5.50 ± 0.06 and a mean trans-tonoplast ΔpH of 1.56 ± 0.07. Reliable determinations of vacuolar and external pH could be made by using accumulation times as low as 2 minutes. These conditions are suitable to follow the kinetics of H⁺ exchanges at the tonoplast. The ³¹P nuclear magnetic resonance technique also offered the possibility of monitoring simultaneously the stability of the trans-tonoplast pH and phosphate gradients. Both appeared to be reasonably stable over several hours. The buffering capacity of the vacuolar sap around pH 5.5 has been estimated by several procedures to be 36 ± 2 microequivalents per milliliter per pH unit. The increase of the buffering capacity due to the accumulation of phosphate in the vacuoles is, in large part, compensated by a decrease of the intravacuolar malate content.     

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     

Osmolytes Contribute to pH Homeostasis of Escherichia coli

Background

Cytoplasmic pH homeostasis in Escherichia coli includes numerous mechanisms involving pH-dependent catabolism and ion fluxes. An important contributor is transmembrane K⁺ flux, but the actual basis of K⁺ compensation for pH stress remains unclear. Osmoprotection could mediate the pH protection afforded by K⁺ and other osmolytes.

Methods and Principal Findings

The cytoplasmic pH of E. coli K-12 strains was measured by GFPmut3 fluorimetry. The wild-type strain Frag1 was exposed to rapid external acidification by HCl addition. Recovery of cytoplasmic pH was enhanced equally by supplementation with NaCl, KCl, proline, or sucrose. A triple mutant strain TK2420 defective for the Kdp, Trk and Kup K⁺ uptake systems requires exogenous K⁺ for steady-state pH homeostasis and for recovery from sudden acid shift. The K⁺ requirement however was partly compensated by supplementation with NaCl, choline chloride, proline, or sucrose. Thus, the K⁺ requirement was mediated in part by osmolarity, possibly by relieving osmotic stress which interacts with pH stress. The rapid addition of KCl to strain TK2420 suspended at external pH 5.6 caused a transient decrease in cytoplasmic pH, followed by slow recovery to an elevated steady-state pH. In the presence of 150 mM KCl, however, rapid addition of another 150 mM KCl caused a transient increase in cytoplasmic pH. These transient effects may arise from secondary K⁺ fluxes occurring through other transport processes in the TK2420 strain.

Conclusions

Diverse osmolytes including NaCl, KCl, proline, or sucrose contribute to cytoplasmic pH homeostasis in E. coli, and increase the recovery from rapid acid shift. Osmolytes other than K⁺ restore partial pH homeostasis in a strain deleted for K⁺ transport.     

On the measurement of pH in Escherichia coli by 31P nuclear magnetic resonance

The ³¹P high resolution NMR spectra of concentrated suspensions of Escherichia coli cells have been measured at 145.8 MHz. The position of the orthophosphate resonance is used as a measure of internal and external pH. In accord with Paddan, Zilberstein and Rottenberg ((1976) Eur. J. Biochem. 63, 533–541) it is shown that when properly energized the internal pH is 7.5 ± 0.1. By synchronizing the NMR data acquisition with 3-s bursts of O₂ it is possible to measure the internal pH with a time resolution of about 1 s. It is shown that at 20°C the pH remains constant for times longer than 15 s after the oxygen is discontinued and it decays in several minutes.     

Amine Transport in Riccia fluitans: Cytoplasmic and Vacuolar pH Recorded by a pH-Sensitive Microelectrode

The cytoplasmic and vacuolar pH and changes thereof in the presence of ammonia (NH₄Cl) and methylamine (CH₃NH₃Cl) have been measured in rhizoid cells of Riccia fluitans by means of a pH-sensitive microelectrode.

On addition of 1 micromolar NH₄Cl, the cytoplasmic pH of 7.2 to 7.4 drops by 0.1 to 0.2 pH units, but shifts to pH 7.8 in the presence of 50 micromolar NH₄Cl or 500 micromolar CH₃NH₃Cl. The pH of the vacuole increases drastically from 4.5 to 5.7 with these latter concentrations. Since a NH₄⁺/CH₃NH₃⁺ uniporter has been demonstrated in the plasmalemma of R. fluitans previously (Felle 1983 Biochim Biophys Acta 602:181-195), the concentration-dependent shifts of cytoplasmic pH are interpreted as results of two processes: first, acidification through deprotonation of the actively transported NH₄⁺; and second, alkalinization through protonation of NH₃ which is taken up to a significant extent from high external concentrations. Furthermore, it is concluded that the determination of intracellular pH by means of methylamine distribution is not a reliable method for eucaryotic systems.

     

Phosphorus-31 nuclear magnetic resonance studies of intracellular pH,phosphate compartmentation and phosphate transport in yeasts

³¹P NMR spectra were obtained from suspensions of Candida utilis, Saccharomyces cerevisiae and Zygosaccharomyces bailii grown aerobically on glucose. Direct introduction of substrate into the cell suspension, without interruption of the measurements, revealed rapid changes in pH upon addition of the energy source. All ³¹P NMR spectra of the yeasts studied indicated the presence of two major intracellular inorganic phosphate pools at different pH environments. The pool at the higher pH was assigned to cytoplasmic phosphate from its response to glucose addition and iodoacetate inhibition of glycolysis. After addition of substrate the pH in the compartment containing the second phosphate pool decreased. A parallel response was observed for a significant fraction of the terminal and penultimate phosphates of the polyphosphate observed by ³¹P NMR. This suggested that the inorganic phosphate fraction at the lower pH and the polyphosphates originated from the same intracellular compartment, most probably the vacuole. In this vacuolar compartment, pH is sensitive to metabolic conditions. In the presence of energy source a pH gradient as large as 0.8 to 1.5 units could be generated across the vacuolar membrane. Under certain conditions net transport of inorganic phosphate across the vacuolar membrane was observed during glycolysis: to the cytoplasm when the cytoplasmic phosphate concentration had become very low due to sugar phosphorylation, and into the vacuole when the former concentration had become high again after glucose exhaustion.Non-Standard Abbreviations NMR nuclear magnetic resonance - ppm parts per million - PP polyphosphate - P_i,c cytoplasmic inorganic phosphate - P_i,v vacuolar inorganic phosphate - pH_in,c cytoplasmic pH - pH_in,v vacuolar pH - FCCP carbonyl p-trifluoromethoxyphenylhydrazone