Seed Dormancy in Red Rice : VI. Monocarboxylic Acids: A New Class of pH-Dependent Germination Stimulants

The addition of an elicitor (glucan) to Phaseolus vulgaris cell suspension cultures increased the formation of the phytoalexin phaseollin. Intracellular pH and phosphate concentrations were studied with ³¹P nuclear magnetic resonance spectroscopy on elicitor-treated cells which were aerated during the nuclear magnetic resonance measurement. The pH of the vacuole and to a lesser extent the pH of the cytoplasm were affected at 10 minutes after elicitor addition; a decrease in pH from 5.3 to 4.8 was noted in the vacuole and from 7.46 to 7.28 in the cytoplasm. The ratio between the amount of Pi in the vacuole to that in the cytoplasm also changed within 10 minutes after elicitor addition. The signal for ATP (β-ATP) was low after elicitor addition and was high again 23 hours after elicitation. Forty-eight hours after elicitor addition, vacuolar and cytoplasmic pH had almost returned to their initial values. The rapid change in vacuolar and cytoplasmic pH may cause the change of metabolism that occurs in elicitor-treated P. vulgaris cells.     

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.     

Longitudinal profiles of the vacuolar pH in internally perfused cells of characean alga

Activities of ion pumps and H⁺-conducting channels in the plasmalemma of illuminated characean algae are distributed inhomogeneously along the internode, which accounts for the shifts of surface pH up to 3.5 units between various cells regions. Spatial variations in cytoplasmic properties provide the basis for uneven distribution of photosynthetic activity along the cell length and might affect the operation of H⁺-transporting systems at the tonoplast. In order to visualize the longitudinal distribution of the vacuolar pH in Chara corallina internodal cells, the pH microelectrode was inserted into the vacuole and the cell sap was gradually displaced along the cell during intracellular perfusion with an artificial medium. Fluorescein was added to the perfusion medium as a fluorescent marker to detect the arrival of the replacing medium into the area of pH and fluorescence measurements. In light-adapted cells, nonuniform longitudinal pH profiles were observed, with pH shifts as large as 2–2.5 units. In dark-adapted cells, the pH shifts in longitudinal profiles did not exceed 0.5 pH units. The occurrence of large pH changes within the vacuole of individual internodes indicates the possibility of nonuniform distribution of the tonoplast H⁺-transporting systems in different regions of the illuminated cell.     

Measurement of the Cytoplasmic and Vacuolar Buffer Capacities in Chara corallina

The cytoplasm and the vacuole were isolated from internodal cells of Chara corallina by using the intracellular perfusion technique, and their buffer capacities (β_i) were determined from the titration curves. The pH of the isolated vacuolar sap was 5.19 ± 0.029 (mean ± standard error). At this pH, β_i was minimal and amounted to 0.933 ± 0.11 millimoles H⁺/pH unit/liter vacuolar sap. The pH of isolated cytoplasm was 7.22 ± 0.028. β_i was minimal in this pH region and amounted to 14.2 ± 0.80 millimoles H⁺/pH unit/liter cytoplasm. When 1% (volume/volume) Triton X-100 was added to the cytoplasmic solution to permeabilize the subcellular organelles, the cytoplasmic pH increased to 7.32 ± 0.026, where β_i was 20.35 ± 2.66 millimoles H⁺/pH unit/liter cytoplasm. This shows that alkaline subcellular compartments exist in the cytoplasm and also that the cytoplasmic pH before adding Triton X-100 may represent the cytosolic pH. These data indicate that the pH values of the cytoplasm and the vacuole are regulated at the values where the β_i values are minimal. This suggests that ATP- and inorganic pyrophosphate-dependent H⁺ pumps in the plasma membrane and the tonoplast could efficiently regulate the pH of both cytoplasm and vacuole in Chara internodal cells.     

Salt Stress-Induced Cytoplasmic Acidification and Vacuolar Alkalization in Nitellopsis obtusa Cells : In VivoP-Nuclear Magnetic Resonance Study

Time courses of cytoplasmic and vacuolar pH changes under salt stress were monitored by in vivo³¹P-nuclear magnetic resonance spectroscopy in intact cells of Nitellopsis obtusa. When cells were treated with 100 millimolar NaCl for 2 hours, the cytoplasmic pH deceased from 7.2 to 7.0, while the vacuolar pH increased from 4.9 to 5.2. This salt-induced breakdown of the pH gradient between the cytoplasm and the vacuole was also confirmed through direct measurements of change in vacuolar pH with a micro-pH electrode. We speculate that the intracellular pH changes induced by the salt stress mainly results from the inhibition of the H⁺-translocating pyrophosphatase in the vacuolar membrane, since this H⁺-translocating system is sensitive to salt-induced increase in the cytoplasmic [Na⁺] and a simultaneous decrease in the cytoplasmic [K⁺]. Since disturbance of the cytoplasmic pH value should have serious consequences on the homeostasis of living cells, we propose that the salt-induced intracellular pH changes are one of initial and important steps that lead to cell death.     

Cytoplasmic Acidification Induced by Inorganic Phosphate Uptake in Suspension Cultured Catharanthus roseus Cells: Measurement with Fluorescent pH Indicator and P-Nuclear Magnetic Resonance

Cytoplasmic acidification during inorganic phosphate (Pi) absorption by Catharanthus roseus cells were studied by means of a fluorescent pH indicator, 2′,7′-bis-(2-carboxyethyl)-5 carboxyfluorescein (acetomethylester) (BCECF), and ³¹P-nuclear magnetic resonance spectroscopy. Cytoplasmic acidification measured by decrease in the fluorescence intensity started immediately after Pi application. Within a minute or so, a stable state was attained and no further acidification occurred, whereas Pi absorption was still proceeding. As soon as Pi in the medium was exhausted, cytoplasmic pH started to recover. Coincidentally, the medium pH started to recover toward the original acidic pH. The Pi-induced changes in the cytoplasmic pH were confirmed by ³¹P-nuclear magnetic resonance study. Maximum acidification of the cytoplasm induced by 1.7 millimolar Pi was 0.2 pH units. Vacuolar pH was also affected by Pi. In some experiments, but not all, pH decreased reversibly by 0.2 to 0.3 pH units during Pi absorption. Results suggest that the cytoplasmic pH is regulated by proton pumps in the plasma membrane and in the tonoplast. In addition, other mechanisms that could consume extra protons in the cytoplasm are suggested.     

A P Nuclear Magnetic Resonance Study of Intracellular pH of Plant Cells Cultivated in Liquid Medium

³¹P nuclear magnetic resonance has been used to study the vacuolar and cytoplasmic pH of Acer pseudoplatanus, Catharanthus roseus, and Glycine max cells grown as cell suspensions. The adaptation of this technique to plant cells grown in liquid medium is described with emphasis on the removal of Mn²⁺ and phosphate from the extracellular medium and on providing the O₂ supply of the cells in the nuclear magnetic resonance tube and the various problems of calibration. Aerobic and anaerobic cells show large differences in their glucose-6-phosphate, their cytoplasmic inorganic phosphate pools, and their cytoplasmic pH. Differences in the relative sizes of the cytoplasmic and vacuolar inorganic phosphate pools have been observed for the three cell strains studied.     

Potassium Transport and Regulation of Intracellular pH in Elodea densa Leaves

The effects of extracellular K⁺ concentration ([K⁺]_o) on the pH of cell sap, “bulk cytoplasm” and vacuole have been investigated in Elodea densa leaves under conditions of either low or high activity of the plasmalemma electrogenic H⁺ pump. Cell sap pH was evaluated directly in the cell sap expressed after freezing and thawing. Cytoplasmic and vacuolar pH were calculated by the weak base and weak acid distribution method, DMO and benzylamine appearing to be a suitable acid and base, respectively, for this purpose in this material. When added to the basal medium (no rapidly permeating ions present), 5 mM K⁺ induced an increase in intracellular pH, larger for the cell sap and the vacuole (about 0.2 units), and smaller but still significant for the cytoplasm (0.07 units). This alkalinizing effect of K⁺ was thus associated with a significant decrease in the pH difference across the tonoplast. The alkalinizing effect of K⁺ was markedly and synergistically enhanced by the presence of fusicoccin, a condition inducing a marked activation of H⁺ extrusion and of K⁺ uptake. The correlation between these effects of [K⁺]_o on intracellular pH and those on H⁺ extrusion indicates that changes in extracellular K⁺ concentration, and thus in K⁺ influx, can influence cytoplasmic and vacuolar pH by modulating the rate of H⁺ extrusion by the plasmalemma H⁺ pump.     

Control of phosphate transport across the plasma membrane of Chara corallina

This paper examines the control of phosphate uptake into Chara corallina. Influxes of inorganic phosphate (Pi) into isolated single internodal cells were measured with ³²Pi. Pretreatment of cells without Pi for up to 10 d increased Pi influx. However, during this starvation the concentrations of Pi in both the cytoplasm and the vacuole remained quite constant. When cells were pre-treated with 0.1 mM Pi, the subsequent influx of Pi was low. Under these conditions the Pi concentrations in the cytoplasm was almost the same as that of Pi-starved cells, but vacuolar Pi increased with time. Transfer of cells from medium containing 0.1 mM Pi to Pi-free medium induced an increase of Pi influx within 3 d irrespective of the concentration of Pi in the vacuole.During Pi starvation, neither the membrane potential nor the cytoplasmic pH changed. Manipulation of the cytoplasmic pH by weak acids or ammonium decreased the Pi influx slightly.Pi efflux was also measured, using cells loaded with ³²Pi. Addition of a low concentration of Pi in the rinsing medium rapidly and temporarily induced an increase in the efflux.The results show that Pi influx is controlled by factors other than simple feedback from cytoplasmic or vacuolar Pi concentrations or thermodynamic driving forces for H⁺-coupled Pi uptake. It is suggested that uptake of Pi is controlled via the concentration of Pi in the external medium through induction or repression of two types of plasma membrane Pi transporters.Key words: Chara corallina, membrane transport, phosphate influx, phosphate starvation      

Observation of Cytoplasmic and Vacuolar Malate in Maize Root Tips by C-NMR Spectroscopy

The accumulation of malate by maize (Zea mays L.) root tips perfused with KH¹³CO₃ was followed by ¹³C nuclear magnetic resonance spectroscopy. In vivo nuclear magnetic resonance spectra contained distinct signals from two pools of malate in maize root tips, one at a pH ~5.3 (assigned to the vacuole) and one at a pH > 6.5 (assigned to the cytoplasm). The ratio of cytoplasmic to vacuolar malate was lower in 12 millimeter long root tips than in 2 millimeter root tips. The relatively broad width of the signals from C1- and C4-labeled vacuolar malate indicated heterogeneity in vacuolar pH. During the 3 hour KH¹³CO₃ treatment, ¹³C-malate accumulated first primarily in the cytoplasm, increasing to a fairly constant level of ~6 millimolar by 1 hour. After a lag, vacuolar malate increased throughout the experiment.     

The NADPH oxidase of professional phagocytes—prototype of the NOX electron transport chain systems

The NADPH oxidase is an electron transport chain in “professional” phagocytic cells that transfers electrons from NADPH in the cytoplasm, across the wall of the phagocytic vacuole, to form superoxide. The electron transporting flavocytochrome b is activated by the integrated function of four cytoplasmic proteins. The antimicrobial function of this system involves pumping K⁺ into the vacuole through BK_Ca channels, the effect of which is to elevate the vacuolar pH and activate neutral proteases. A number of homologous systems have been discovered in plants and lower animals as well as in man. Their function remains to be established.     

H Uptake and Extrusion by Nitella clavata

Very high rates of H⁺ extrusion by internodal cells of Nitella clavata Kutz were measured after acid loading at pH 4.6. The highest rate observed, 160 picomoles per square centimeter per second, was more than twice the rate of photosynthetic bicarbonate utilization under saturating light. These results are consistent with the recently proposed hypothesis that bicarbonate is not taken in directly but is protonated at the exterior surface; the CO₂ thereby formed diffuses preferentially into the cell because of the asymmetric concentration gradient.

The H⁺ taken up, about 150 nanomoles per square centimeter in 2 hours, was distributed in three fractions: 30% in the cell wall, 40% in the cytoplasm, and 30% in the vacuole. This was concluded from the kinetics of the H⁺ release by intact cells and isolated walls, and from the pH decrease of the vacuolar sap.

The cytoplasmic H⁺ was extruded rapidly, with a half-time of about 2 minutes when the external pH was 5.7 or higher. The extrusion of the vacuolar H⁺ only proceeded at a measurable rate when the [K⁺] in the medium was raised to 20 millimolar; the half-time was about 100 minutes. There was little H⁺ extruded when the external pH was 5.0.

     

Dynamics of Nitrogenous Assimilate Partitioning between Cytoplasmic and Vacuolar Fractions in Carrot Cell Suspension Cultures

Bulk vacuole isolation, gas chromatography-mass spectrometry,, and high-performance liquid chromatography have been used to investigate the accumulation and partitioning of assimilated nitrogen supplied as ¹⁵NH₄Cl between vacuolar and extravacuolar (cytoplasmic) fractions of protoplasts from suspension cultures of carrot (Daucus carota L. cv Chantenay). Glutamine was the most abundant amino acid in the vacuole of protoplasts from late-exponential phase cells, whereas alanine, glutamate, and γ-aminobutyric acid were located primarily in the cytoplasmic fraction. In ¹⁵N-feeding studies, newly synthesized glutamine partitioned strongly to the vacuole, whereas glutamate partitioned strongly to the cytoplasm, γ-aminobutyric acid was totally excluded from the vacuole, and alanine was distributed in both compartments. Comparison of the ¹⁵N-enrichment patterns suggests that initial assimilation to glutamine occurs within a subcompartment of the cytoplasmic fraction. The protoplast-feeding technique may be extended to investigate cytoplasmic compartmentation further.     

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     

Differential pH restoration after ammonia-elicited vacuolar alkalisation in rice and maize root hairs as measured by fluorescence ratio

Changes of vacuolar pH in hair cells of young rice (Oryza sativa L.) and maize (Zea mays L.) roots were measured after ammonia application at various levels of external pH. After loading the pH-sensitive, fluorescent dye Oregon green 488 carboxylic acid 6-isomer into the vacuoles of root hairs, ratiometric pH data of high statistical significance were obtained from root hair populations comprising hundreds of cells. The pH of the vacuole at external pH 5.0 was 5.32 ± 0.08 (±SD, n= 15) and 5.41 ± 0.13 (±SD, n= 15) in rice and maize, respectively. A moderate external ammonia concentration of 2 mM led to vacuolar alkalisation at both, low (pH 5.0) and high (pH 7.0–9.0) external pH, presumably due to NH₃ permeation into the vacuole. With increasing external pH, ammonia application did not cumulatively increase vacuolar pH. In rice, the increase in vacuolar pH ranged from 0.1–0.8 pH units; in maize a more constant increase of 0.5 pH units was observed. The vacuolar pH increase was efficiently depressed in rice (especially at high external pH), but not in maize. Inhibition of the tonoplast H⁺-ATPase by concanamycin A raised vacuolar pH and increased the ammonia-elicited vacuolar alkalisation in both species, proving that vacuolar H⁺-ATPase activity counters the ammonia-elicited alkalisation effect. However, even under conditions of vacuolar H⁺-ATPase inhibition, rice was still able to restore an ammonia-elicited pH increase. High vacuolar pH levels as found in maize under conditions of high NH₃ influx may derive from inefficient cytosolic ammonia assimilation and tonoplast proton pumping. Thus, in maize, prolonged reduction of the proton gradient between the cytosol and the vacuole may play an important role in NH₃ toxicity. Received: 12 September 1997 / Accepted: 19 January 1998     

Bafilomycin Inhibits Vacuolar pH Regulation in a Fresh Water Charophyte,Chora corallina

Bafilomycin A₁, known as an inhibitor of vacuolar type H⁺-ATPase, was used to study involvement of the vacuolar ATP-dependent H⁺-pump in the vacuolar pH regulation in a fresh water charophyte, Chara corallina. When bafilomycin A₁ (100 nM) was externally given to intact cells, the vacuolar pH (about 5) was not affected. Internodal cells were then pretreated with 100 nM bafilomycin for 1 ? 2 h and the vacuolar sap was replaced with a weakly buffered solution of pH 7.4. The readjustment of the modified vacuolar pH in bafilomycin-treated cells was significantly retarded compared with that in untreated cells. Next, bafilomycin A₁ was directly introduced into the vacuole by vacuolar perfusion with the artificial cell sap of pH 7.4. At 100 nM bafilomycin A₁, the decrease in the vacuolar pH was significantly inhibited. When cell sap was replaced with the artificial cell sap containing no buffer (pH 5.2 ? 5.5), the vacuolar pH increased in the presence of vacuolar bafilomycin, suggesting that the PP₁- dependent H⁺ pumping alone was not sufficient for the pH regulation of Chara vacuoles. Intracellular bafilomycin A₁ had no effect on the plasma membrane potential of tonoplast-free cells, which is evidence that it does not affect the electrogenic H⁺-pump in the plasma membrane. Bafilomycin A₁ inhibited the ATP-dependent H⁺ transport of tonoplast vesicles but not the PP₁-dependent H⁺ transport. The ATPase activity of tonoplast vesicles was also inhibited by bafilomycin A₁.     

P NMR Observations on the Effect of the External pH on the Intracellular pH Values in Plant Cell Suspension Cultures

³¹P nuclear magnetic resonance (NMR) spectroscopy was used to monitor the response of oil palm (Elaeis guineensis) and carrot (Daucus carota) cell suspensions to changes in the external pH. An airlift system was used to oxygenate the cells during the NMR measurements and a protocol was developed to enable a constant external pH to be maintained in the suspension when required. Phosphonoacetic acid was used as an external pH marker and the intracellular pH values were measured from the chemical shifts of the cytoplasmic and vacuolar orthophosphate resonances. In contrast to earlier studies the cytoplasmic pH was independent of the external pH over the range 5.5 to 8.0 and it was only below pH 5.5 that the cytoplasmic pH varied, falling at a rate of 0.12 pH unit per external unit. Loss of pH control was observed in response to sudden increases in external pH with the response of the cells depending on the conditions imposed. A notable feature of the recovery from these treatments was the transient acidification of the cytoplasm that occurred in a fraction of the cells and overshoot phenomena of this kind provided direct evidence for the time dependence of the regulatory mechanisms.     

Membrane perforations inhibit lysosome fusion by altering pH and calcium in Listeria monocytogenes vacuoles

Listeria monocytogenes (Lm) evade microbicidal defences inside macrophages by secreting a pore-forming cytolysin listeriolysin O (LLO), which allows Lm to escape vacuoles. LLO also inhibits Lm vacuole fusion with lysosomes, which indicates LLO alters vacuole chemistry prior to release of Lm into cytoplasm. Using fluorescent probes to measure membrane permeability, calcium and pH, we identified small membrane perforations in vacuoles containing wild-type but not LLO-deficient (hly-) Lm. The small membrane perforations released small fluorescent molecules and persisted for several minutes before expanding to allow exchange of larger fluorescent molecules. Macropinosomes and hly- Lm vacuoles acidified and increased their calcium content ([Ca2+]vac) within minutes of formation; however, the small perforations made by LLO-expressing bacteria increased vacuolar pH and decreased [Ca2+]vac shortly after infection. Experimental increases in vacuolar pH inhibited Lm vacuole fusion with lysosomes. The timing of perforation indicated that LLO-dependent delays of Lm vacuole maturation result from disruption of ion gradients across vacuolar membranes.     

Functional Specialization of Vacuoles in Sugarcane Leaf and Stem

Plant vacuoles are frequently targeted as a storage site for novel products. We have used environment-sensitive fluorescent dyes and the expression of vacuolar marker proteins to characterize the vacuoles in different organs and cell types of sugarcane. The results demonstrated that the lumen of the vacuole in the parenchyma cells of the stem is acidic (<pH 5) and contains active proteases, characteristic of lytic vacuoles. Western blots and tissue labelling with antibodies to vacuolar H⁺-ATPase suggest that this proton pump is involved in acidification of the vacuolar lumen. Quantitative real-time PCR was used to show that the expression of vacuolar proteases and a vacuolar sorting receptor is also coordinately regulated. In contrast to the stem parenchyma cells, the cells of sugarcane leaves contain diverse types of vacuoles. The pH of these vacuoles and their capacity to hydrolyze protease substrates varies according to cell type and developmental stage. Sugarcane suspension-cultures contain cells with vacuoles that resemble those of stem parenchyma cells and are thus a useful model system for investigating the properties of the vacuole. Understanding the growth and development of storage capacity will be useful in designing strategies to maximize the production of sucrose or alternative bioproducts.     

Relationship between the cytoplasm and the vacuole phosphate pool in Acer pseudoplatanus cells

The Pi concentration of Acer pseudoplatanus cells in the two major intracellular compartments, the cytoplasm and the vacuole, has been studied using 31P NMR. For sycamore cells containing approximately 2 mM of total Pi, the cytoplasmic Pi and the vacuolar Pi concentrations were approximately 6 and 1.5 mM, respectively. When the cells were transferred to a phosphate-deficient medium, the vacuolar Pi decreased rapidly while the cytoplasmic Pi decreased slowly during the first 48 h, indicating that Pi in the cytoplasm was maintained at the expense of the vacuolar Pi. When the Pi-starved cells (i.e., those containing less than 0.5 mumol of total Pi/g wet wt) were transferred to a medium containing 300 microM Pi, Pi entered the cells rapidly and accumulated in the cytoplasm. Once the cytoplasmic Pi pool was filled, Pi was taken up in the vacuole until the vacuole Pi pool was filled. On the contrary when the non-Pi-starved cells were transferred to a phosphate-rich medium (i.e., containing 45 mM Pi), Pi entered the cells slowly by diffusion and accumulated in the vacuole but not in the cytoplasm. These results demonstrate that the Pi content of the cytoplasm is maintained at the expense of the vacuolar Pi pool when sycamore cells are transferred to either a phosphate-deficient or a phosphate-rich medium.