Phenotypic changes in the fluidity of the tonoplast membrane of crassulacean-acid-metabolism plants in response to temperature and salinity stress

Electron paramagnetic resonance-spectroscopic studies on spin-labeled purified tonoplast membranes showed that in the obligate crassulacean-acid-metabolism (CAM) plant Kalanchoë daigremontiana Hamet et Perr. the fluidity of the tonoplast decreased during acclimation to higher temperatures. This phenotypic change in tonoplast fluidity was paralleled by a decrease in the mobilization of malic acid from the vacuoles during CAM in the light. The shift from the C₃ to the CAM mode of photosynthesis in the facultative CAM plant Mesembryanthemum crystallinum L. also led to a decrease in the fluidity of the tonoplast membrane. The results are consistent with the hypothesis that the ability to store malic acid during CAM in the vacuoles depends largely on the actual fluidity of the tonoplast membrane.     

Phenotypic Adaptation of Tonoplast Fluidity to Growth Temperature in the CAM Plant Kalanchoë daigremontiana Ham. et Per. is Accompanied by Changes in the Membrane Phospholipid and Protein Composition

The present study deals with the phenotypic adaptation of tonoplast fluidity in the CAM plant Kalancho? daigremontiana to changes in growth temperature. Tonoplast fluidity was characterized by measuring fluorescence depolarization in membranes labeled with fluorescent fatty acid analogues and by following formation of eximeres in membranes labeled by eximere-forming fluorophores. With both techniques it was found that exposure of the plants to higher growth temperature compared with the control decreased the fluidity of the tonoplast while exposure to lower growth temperature caused the opposite. Three hours of high temperature treatment (raised from 25°C to 35°C; ``heat shock') were sufficient to decrease the tonoplast fluidity to roughly the same extent as growth under high temperature for 30 days. The phenotypic response of tonoplast fluidity to changes in growth temperature was found only in the complete membrane, not however in the lipid matrix deprived of the membrane proteins. Heat treatments of the plants decreased the lipid/protein ratio while exposure to low temperature (for 30 days) increased it. Heat treatments led to a decrease in the percentage of linolenic acid (C18:3) and linoleic acid (C18:2), heat shock and low temperature treatments induced an increase in the percentage of linoleic acid (C18:3), with concomitant decrease in the percentage of linoleic acid (C18:2). However, in the case of heat shock, increase in linolenic acid concerned mainly monogalactosyldiacylglycerol, while with low temperature treatment linoleic acid increased in phosphatidylcholine. Both treatment of the plants with high and low temperature led to a slight decrease in the contribution of phosphatidylcholine and phosphoethanolamine to the total phospholipid content of the tonoplast. High-temperature treatment of the plants not only decreased the phospholipid/protein ratio in the tonoplast, but also led to the occurrence of a 35 kDa polypeptide in the tonoplast which cross-reacted with an antiserum against the tonoplast H⁺-ATPase holoenzyme. The important role of membrane proteins in bringing about the phenotypic rigidization of the tonoplast was mimicked by reconstitution experiments showing that incorporation of the proteins isolated from the tonoplast into phosphatidylcholine vesicles decreased the fluidity of this membrane system. As to be expected from the analyses in the natural membrane, the degree of this effect depended on the phospholipid/protein ratio. Received: 4 March 1998/Revised: 28 July 1998     

The effect of high temperatures on leaf cells of Valerianella: relative heat stability of the tonoplast membrane of mesophyll vacuoles

The effect of short-term heat stress on the tonoplast membrane of lamb's lettuce (Valerianella locusta (L.) Betcke) mesophyll vacuoles has been investigated. The maintainance of a proton concentration difference (δpH) across the tonoplast membrane served as a criterion for the integrity of the vacuoles. After heat treatment, δpH was measured at room temperature using the fluorescent amine, 9-aminoacridine. It was found with this method that thermal damage to isolated vacuoles mainly occurred in the temperature range above 50°C. Compared with this results, the photosynthetic functions of isolated lettuce protoplasts proved to be markedly more thermolabile, e.g. photosynthetic CO₂ fixation and light-induced chlorophyll fluorescence were drastically reduced at temperatures between 40° and 50°C. Heating of whole leaves and protoplasts and subsequent isolation of vacuoles showed that tonoplast-membrane integrity is not affected by heat stress in situ up to 45°C. Measurement of 9-aminoacridine fluorescence in protoplasts, which allowed conclusions to be drawn regarding the integrity of the tonoplast membrane in its natural cytoplasmic environment, revealed that heat treatment up to 55°C did not significantly affect vacuolar compartmentation. The data provide evidence that the tonoplast membrane is relatively heat stable compared with photosynthetic membranes.     

Phenotypic Adaptation to Elevated Temperatures of Tonoplast Fluidity in the CAM Plant Kalanchoë daigremontiana is Caused by Membrane Proteins*

Comparative electron paramagnetic resonance spectroscopic studies on spin-labeled native and protein-free purified tonoplast membranes in the CAM plant Kalanchoë daigremontiana showed that the phenotypic decrease in tonoplast fluidity occurring upon acclimation to elevated temperature is brought about by specific protein-lipid interaction. However, there are indications that, to some extent, the properties of the bulk tonoplast lipids may also be affected by acclimation to high temperature. In contrast to heat acclimated individuals and for still unknown reasons, in plants grown at normal temperature depletion of the tonoplast membrane of its proteins had no effect on membrane fluidity. The results are considered as evidence for the occurrence of homeoviscous adaptation in the tonoplast of CAM plants towards changes in the temperature climate during growth.     

Vacuolar malate uptake is mediated by an anion-selective inward rectifier

Electrophysiological studies using the patch‐clamp technique were performed on isolated vacuoles from leaf mesophyll cells of the crassulacean acid metabolism (CAM) plant Kalanchoë daigremontiana to characterize the malate transport system responsible for nocturnal malic acid accumulation. In the presence of malate on both sides of the membrane, the current–voltage relations of the tonoplast were dominated by a strongly inward‐rectifying anion‐selective channel that was active at cytoplasmic‐side negative voltages. Rectification of the macroscopic conductance was reflected in the voltage‐dependent gating of a 3‐pS malate‐selective ion channel, which showed a half‐maximal open probability at ?43 mV. Also, the time‐averaged unitary currents following a step to a negative voltage corresponded to the time‐dependent kinetics of the macroscopic currents, suggesting that the activity of this channel underlies the anion‐selective inward rectifier. The inward rectifier showed saturation kinetics with respect to malate (apparent K_m of 2.5 mm malate^2? activity), a selectivity sequence of fumarate^2? > malate^2? > Cl^? > maleate^2– ≈ citrate^3–, and greater activity at higher pH values (with an apparent pK of 7.1 and maximum activity at around pH 8.0). All these properties were in close agreement with the characteristics of malate transport observed in isolated tonoplast vesicles. Further, 100 µm niflumate reversibly blocked the activity of the 3‐pS channel and inhibited both macroscopic currents and malate transport into tonoplast vesicles to the same extent. The macroscopic current densities recorded at physiological voltages and the estimated channel density of 0.2 µm^?2 are sufficient to account for the observed rates of nocturnal malic acid accumulation in this CAM plant, suggesting that the 3‐pS, inward‐rectifying, anion‐selective channel represents the principal pathway for malate influx into the vacuole.     

Cell death in seedlings of the interspecific hybrid of <Emphasis Type="Italic">Nicotiana gossei</Emphasis> and <Emphasis Type="Italic">N. tabacum</Emphasis>; possible role of knob-like bodies formed on tonoplast in vacuolar-collapse-mediated cell death

Vacuolar collapse plays a direct role in the cell death of the interspecific hybrid of Nicotiana gossei Domin ×N. tabacum L. which exhibits hybrid lethality at the seedling stage. We have previously reported that cell death in these seedlings began at the base of hypocotyls and spread throughout the plant (Mino et al. 2002). A light microscopic analysis revealed that the process involved disruption of the intra-cellular membranes, plasmolysis, and retraction of the wall of the cell in hypocotyls. A transmission electron microscopic analysis showed that there were several abnormal structures, i.e. knob-like bodies on the tonoplast and small vesicles in the cytoplasm, and the disintegration of the tonoplast, in the cells of seedlings grown at 26°C. However, no such cytological defects were observed in the seedlings grown at 37°C, at which temperature the expression of lethality was suppressed. The activity levels of vacuolar processing enzyme (VPE), which might be involved in the vacuolar collapse of plant cells, temporarily increased in the seedlings grown at 26°C before apparent cell death proceeded, but it remained unchanged in the seedlings grown at 37°C. Applications of acetyl-l-tyrosyl-l-valyl-l-alanyl-l-aspart-1-aldehyde, an inhibitor for VPE, and cycloheximide to the seedlings suppressed VPE's activities, the formation of knob-like bodies on the tonoplast, and cell death. VPE might be involved in the structural anomalies on the tonoplast which lead to cell death triggered by vacuolar collapse in hybrid seedlings.     

Temperature Sensitivity of the Tonoplast Ca2+-Activated K+ Channel in Chara: The Influence of Reversing the Sign of Membrane Potential

A detailed temperature dependence study of a well-defined plant ion channel, the Ca²⁺-activated K⁺ channel of Chara corallina, was performed over the temperature range of their habitats, 5–36°C, at 1°C resolution. The temperature dependence of the channel unitary conductance at 50 mV shows discontinuities at 15 and 30°C. These temperatures limit the range within which ion diffusion is characterized by the lowest activation energy (E _a = 8.0 ± 1.6 kJ/mol) as compared to the regions below 15°C and above 30°C. Upon reversing membrane voltage polarity from 50 to −50 mV the pattern of temperature dependence switched from discontinuous to linear with E _a = 13.6 ± 0.5 kJ/mol. The temperature dependence of the effective number of open channels at 50 mV showed a decrease with increasing temperature, with a local minimum at 28°C. The mean open time exhibited a similar behavior. Changing the sign of membrane potential from 50 to −50 mV abolished the minima in both temperature dependencies. These data are discussed in the light of higher order phase transitions of the Characean membrane lipids and corresponding change in the lipid-protein interaction, and their modulation by transmembrane voltage. Received: 14 June 2000/Revised: 20 September 2000     

Physiological responses of Opuntia ficus-indica to growth temperature

The influences of various day/night air temperatures on net CO₂ uptake and nocturnal acid accumulation were determined for Opuntia ficus-indica, complementing previous studies on the water relations and responses to photosynthetically active radiation (PAR) for this widely cultivated cactus. As for other Crassulacean acid metabolism (CAM) plants, net nocturnal CO₂ uptake had a relatively low optimal temperature, ranging from 11°C for plants grown at day/night air temperatures of 10°C/0°C to 23°C at 45°C/35°C. Stomatal opening, which occurred essentially only at night and was measured by changes in water vapor conductance, progressively decreased as the measurement temperature was raised. The CO₂ residual conductance, which describes chlorenchyma properties, had a temperature optimum a few degrees higher than the optimum for net CO₂ uptake at all growth temperatures. Nocturnal CO₂ uptake and acid accumulation summed over the whole night were maximal for growth temperatures near 25°C/15°C, CO₂ uptake decreasing more rapidly than acid accumulation as the growth temperature was raised. At day/night air temperatures that led to substantial nocturnal acid accumulation (25°C/15°C.). 90% saturation of acid accumulation required a higher total daily PAR than at non-optimal growth temperatures (10°C/0°C and 35°C/25°C). Also, the optimal temperature of net CO₂ uptake shifted downward when the plants were under drought conditions at all three growth temperatures tested, possibly reflecting an increased fractional importance of respiration at the higher temperatures during drought. Thus, water status, ambient PAR, and growth temperatures must all be considered when predicting the temperature response of gas exchange for O. ficus-indica and presumably for other CAM plants.     

Selective Reconstitution of the Tonoplast H+-ATPase of the Crassulacean-Acid Metabolism Plant Kalanchoë daigremontiana

IA detergent removal technique was used to reconstitute solubilized tonoplast proteins of mesophyll cells of the CAM plant Kalanchoë daigremontiana into phosphatidylcholine liposomes. The proteoliposomes were able to hydrolyse ATP and to pump protons across the vesicle membrane. Both activities were inhibited by nitrate, an inhibitor of V-type ATPases. Freeze-fracture micrographs confirmed the incorporation of membrane proteins into liposomes. Increase of specific ATP-hydrolysis activity compared to solubilized tonoplast proteins and SDS-PAGE analysis of reconstituted proteins in comparison with the polypeptide pattern of the purified tonoplast H⁺-ATPase from the same plant source indicated a highly selective reconstitution of the tonoplast H⁺-ATPase.     

Plasticity of crassulacean acid metabolism at subtropical latitudes: a pineapple case study

Plants with the crassulacean acid metabolism (CAM) express high‐metabolic plasticity, to adjust to environmental stresses. This article hypothesizes that irradiance and nocturnal temperatures are the major limitations for CAM at higher latitudes such as the Azores (37°45'N). Circadian CAM expression in Ananas comosus L. Merr. (pineapple) was assessed by the diurnal pattern of leaf carbon fixation into l ‐malate at the solstices and equinoxes, and confirmed by determining maximal phosphoenolpyruvate carboxylase (PEPC) activity in plant material. Metabolic adjustments to environmental conditions were confirmed by gas exchange measurements, and integrated with environmental data to determine CAM's limiting factors: light and temperature. CAM plasticity was observed at the equinoxes, under similar photoperiods, but different environmental conditions. In spring, CAM expression was similar between vegetative and flowering plants, while in autumn, flowering (before anthesis) and fructifying (with fully developed fruit before ripening) plants accumulated more l ‐malate. Below 100 µmol m^?2 s^?1, CAM phase I was extended, reducing CAM phase III during the day. Carbon fixation inhibition may occur by two major pathways: nocturnal temperature (<15°C) inhibiting PEPC activity and l ‐malate accumulation; and low irradiance influencing the interplay between CAM phase I and III, affecting carboxylation and decarboxylation. Both have important consequences for plant development in autumn and winter. Observations were confirmed by flowering time prediction using environmental data, emphasizing that CAM expression had a strong seasonal regulation due to a complex network response to light and temperature, allowing pineapple to survive in environments not suitable for high productivity.     

Low Temperature-Induced Changes in the Thermotropic Properties and Fatty Acid Composition of the Plasma Membrane and Tonoplast of Cultured Rice (Oryza sativa L.) Cells

The thermotropic transitions of the plasma membrane and tonoplastfrom cultured cells of chilling-sensitive (CS) and chilling-insensitive(CI) strains of rice (Oryza sativa L.) were analyzed by monitoringthe fluorescence polarization of an embedded fluorophore, 1,6-diphenyl-1,3,5-hexatriene(DPH), and their relationship to the degree of unsaturationof fatty acids in phospholipids was examined. Polarization values (P) for the tonoplast from cultured cellsof CI rice, in contrast to those from CS rice, exceeded thosefor the plasma membrane. The values for the tonoplast and plasmamembrane from CI cells were somewhat higher than those fromCS cell. Thus, the tonoplast of CI cells has the lowest fluidity,while the fluidity of the tonoplast and plasma membrane of CIcells shows greater dependence on temperature. Arrhenius plotsof the fluorescence anisotropy parameter {(r_o/r)–1}–1of DPH in the plasma membrane and tonoplast from CI cells gavea slope that was virtually linear throughout the entire rangeof temperatures from 50°C to 10°C. However, in the caseof CS cells, a discontinuity was sometimes noted in the curvebetween 35°C and 30°C for tonoplast membranes. The activationenergy (E_a) of the anisotropy parameter of DPH in both the plasmamembrane and tonoplast from CI cells was greater than that fromCS cells. E_a in both cases for CS cells increased with increasingduration of exposure to low tempera ture (5°C), becomingnearly the same as that for CI cells. The proportion of unsaturated fatty acids, such as linoleicacid (18:2) and linolenic acid (18:3), in the total phospholipidsof the plasma membrane and tonoplast from CI cells was muchhigher than that from CS cells. In membranes from CS cells,this proportion also increased with increasing duration of exposureto low temperature and reached the value for membranes fromCI cells. In particular, in CS cells, the most dramatic changewas the change in PE and PC that in volved a sharp decreasein levels of 18:1, accompanied by an increase in 18:3. The proportionof unsaturated fatty acids was increased by exposure to lowtemperature, with an accompanying in crease in values of E_a. (Received April 10, 1991; Accepted May 9, 1992)     

Membrane alterations in winter rye and Brassica napus cells during lethal freezing and plasmolysis

Abstract Cells fixed during freezing or plasmolysis were used to study membrane alterations in hardened and non-hardened Brassica napus suspension-cultured cells and rye leaf mesophyll cells. The plasmalemma in non-hardened rye mesophyll cells formed multilamellar vesicles during lethal freezing at high subzero temperatures (–5°C). These vesicles became highly condensed at lower subzero temperatures (–10°C). Conversely, cold-hardened rye mesophyll cells did not undergo membrane alterations at these temperatures. The results from plasmolysis of B. napus and rye mesophyll cells hardened by ABA at 25 °C and low temperature (2°C), respectively, verify the cell response to lethal freezing. Again there was a continuum of responses with 1 kmol m^?3 balanced salt causing multilamellar protrusions. Appression of the plasmalemma against the tonoplast to form multilamellar vesicles and the invagination of these vesicles into the tonoplast were also observed in rye cells undergoing lethal plasmolysis. Increasing the plasmolysing solution to 3 kmol m^?3 occasionally caused the formation of multilamellar vesicles on the cell surface of hardened rye mesophyll cells.     

Plasmalemma- and tonoplast-ATPase activity in mesophyll protoplasts,vacuoles and microsomes of the Crassulacean-acid-metabolism plant Kalanchoe daigremontiana

Adenosine-triphosphatase activity on the plasmalemma and tonoplast of isolated mesophyll protoplasts, isolated vacuoles and tonoplast-derived microsomes of the Crassulacean-acid-metabolism plant Kalanchoe daigremontiana Hamet et Perr., was localized by a cytochemical procedure using lead citrate. Enzyme activity was detected on the cytoplasmic surfaces of the plasmalemma and tonoplast. The identity of the enzymes was confirmed by various treatments differentiating the enzymes by their sensitivity to inhibitors of plasmalemma and tonoplast H⁺-ATPase. Isolated vacuoles and microsomes prepared from isolated vacuoles clearly exhibited single-sided deposition on membrane surfaces.Abbveviations CAM Crassulacean acid metabolism - H⁺-ATPase proton-translocating ATPase     

The Effect of Temperature and Light on Gas Exchange and Acid Accumulation in the C3-CAM Plant Clusia minor L

Gas exchange and organic acid accumulation of the C₃-CAM intermediateClusia minor L. were investigated in response to various day/nighttemperatures and two light regimes (low and high PAR). For bothlight levels equal day/night temperatures between 20°C and30°C caused a typical C₃ gas exchange pattern with all CO₂uptake occurring during daylight hours. A day/ night temperatureof 15°C caused a negative CO₂ balance over a 24 h periodfor low-PAR-grown plants while high-PAR-grown plants showeda CAM gas exchange pattern with most CO₂ uptake taking placeduring the dark period. However, there was always a considerablenight-time accumulation of malic acid which increased when thenight-time temperature was lowered and had its maximum (54 mmolm^–2) at day/night temperature of 30/15°C. A significantamount of malic acid accumulation (23 mmol m^–2) in low-PAR-grownplants was observed only at 30/15°C. Recycling of respiratoryCO₂ in terms of malic acid accumulation reached between 2·0and 21·5 mmol m_–2 for high-PAR-grown plants whilethere was no significant recycling for low-PAR-grown plants.Both low and high-PAR-grown plants showed considerable night-timeaccumulation of citric acid. Indeed under several temperatureregimes low-PAR-grown plants showed day/night changes in citricacid levels whereas malic acid levels remained approximatelyconstant or slightly decreased. It is hypothesized that lowand high-PAR-grown plants have different requirements for citrate.In high-PAR-grown plants, the breakdown of citrate preventsphotoinhibition by increasing internal CO₂ levels, whereas inlow-PAR-grown plants the night-time accumulation of citric acidmay function as an energy and carbon saving mechanism. Key words: C. minor, C₃, CAM, citric acid, light intensity     

Membrane Particles,Proteins and ATPase Activity of Tonoplast Vesicles of Mesembryanthemum crystallinum in the C-3 and CAM State*

Dimensions and area densities of membrane particles were studied by electron microscopy of replicas of freeze-fractured suspensions of tonoplast vesicles of Mesembryanthemum crystallinum L. in the C-3 state and after induction of crassulacean acid metabolism (CAM) by salinity. The results are compared with the relative contribution of tonoplast-ATPase protein to total membrane protein obtained from integration of elution profiles in size-exclusion chromatography. Coverage of tonoplast area by globular membrane particles was 20% and 36 % and ATPase in relation to total membrane protein was 33 % and 35 % in C-3 and CAM M. crystallinum, respectively. Thus, by order of magnitude, it is most likely that the particles represent the ATPase. In Kalanchoë daigremontiana Hamet et Perrier de la Bâthie the ATPase also constituted 36% of total tonoplast protein. Induction of CAM in M. crystallinum was associated with an increase in specific ATPase activity of the tonoplast and an increase of the size and area coverage of tonoplast particles, whereas the relative contribution of ATPase protein to total tonoplast protein and the molecular mass of the ATPase holoenzyme, as seen in size-exclusion chromatography, remained almost unchanged.     

Stomatal responses to changes in air humidity are not necessarily linked to nocturnal CO2 uptake in the CAM plant Plectranthus marrubioides Benth. (Lamiaceae)

Plants of the crassulacean acid metabolism (CAM) species Plectranthus marrubioides (Lamiaceae) were subjected to short- and long-term changes in air humidity in controlled-environment experiments. Stomata of well-watered individuals of this all-cell leaf-succulent taxon responded directly, quickly and reversibly to variations of the water vapour gradient between leaf and air (Δw). Mean night-time leaf conductance to water vapour decreased curvilinearly with increasing Δw but linearly with lowered relative air humidity. Stomatal response was generally independent of the prevailing temperature and was not linked to CO₂ uptake rates. Therefore, net night-time carbon gain, nocturnal malic acid accumulation and, thus, relative carbon recycling were not influenced by changes in air humidity in the temperature range tested. Mean nocturnal molar water use efficiency, however, decreased with decreasing air humidity because of the increased transpirational water loss. If watering was repeatedly withheld for several days during the experiments, employing a temperature regime of 35/30°C day and night, stomatal conductance became low enough to inhibit CO₂ uptake, but only at the highest Δw. The results suggest that drought stress was necessary to increase responsiveness of plants to the point where CAM was also inhibited by decreases in air humidity.     

Crassulacean acid metabolism in the epiphytic ferns Drymoglossum piloselloides and Pyrrosia longifolia: studies on responses to environmental signals

Abstract The paper reports the results of the comprehensive study of crassulacean acid metabolism in two epiphytic tropical ferns, Drymoglossum piloselloides and Pyrrosia longifolia. The plants were investigated under different light, temperature and water status. It was found that both species are obligate CAM plants. The diurnal acidity rhythm is due to the fluctuation in malic acid concentration, which accounts for the change in titratable acidity. Besides malic acid, shikimate and oxalate are found to be present, but not contributing to the CAM acid rhythm. The diurnal rhythm of malic acid content results in a corresponding rhythm in leaf water relations. Both Φ_Φ and Φ_total, were lowest at the end of the night, i.e. when the level of malic acid was highest. The effects of temperature on CO₂ exchange were inverse to those observed in other CAM plants. In both ferns studied, dark CO₂ fixation increased when the night temperature was increased. Increase in day temperature reduced CO₂ uptake during phase IV and during the following night. The observed responses of the ferns to temperature changes suggest that the in situ environmental conditions are optimal for their CAM performance. In weak light, the plants showed net CO₂ output during the midday deacidification period. Increases in light intensity reduced such CO₂ output. Under drought conditions, the CO₂ exchange in the ferns was reduced to zero within 5–6 d, indicating that the ferns studied are more susceptible to water deficiency than other CAM plants. This could be due to a higher cuticular conductance for water. The results are discussed, in particular, in relation to CAM performance of epiphytes growing in the wet tropics.     

Day-to-night variations of cytoplasmic pH in a crassulacean acid metabolism plant

Summary In crassulacean acid metabolism (CAM) large amounts of malic acid are redistributed between vacuole and cytoplasm in the course of night-to-day transitions. The corresponding changes of the cytoplasmic pH (pH_cyt) were monitored in mesophyll protoplasts from the CAM plantKalanchoe daigremontiana Hamet et Perrier by ratiometric fluorimetry with the fluorescent dye 2′,7′-bis-(2-carboxyethyl)-5-(and-6-)carboxyfluorescein as a pH_cyt indicator. At the beginning of the light phase, pH_cyt was slightly alkaline (about 7.5). It dropped during midday by about 0.3 pH units before recovering again in the late-day-to-early-dark phase. In the physiological context the variation in pH_cyt may be a component of CAM regulation. Due to its pH sensitivity, phosphoenolpyruvate carboxylase appears as a likely target enzyme. From monitoring ΔpH_cyt in response to loading the cytoplasm with the weak acid salt K-acetate a cytoplasmic H⁺-buffer capacity in the order of 65 mM H+ per pH unit was estimated at a pH_cyt of about 7.5. With this value, an acid load of the cytoplasm by about 10 mM malic acid can be estimated as the cause of the observed drop in pH_cyt. A diurnal oscillation in pH_cyt and a quantitatively similar cytoplasmic malic acid is predicted from an established mathematical model which allows simulation of the CAM dynamics. The similarity of model predictions and experimental data supports the view put forward in this model that a phase transition of the tonoplast is an essential functional element in CAM dynamics.