Modeling of hysteresis in pH pattern formation along the cell membrane of algae Chara corallina

It is known that illumination of the algae Chara corallina results in the formation along the membrane of regions with inhomogeneous distribution of pH. It was shown that, in a particular range of illumination intensities, two states with different pH distribution are realized at one and the same value of light intensity: an entirely homogeneous state and completely formed structures (pattern). The transition from the homogeneous state to the pattern formation takes place at one value of light intensity, and the back transition, at another light intensity, i.e., the hysteresis is observed. This phenomenon was studied by mathematical modeling. The mechanism of hysteresis is discussed.     

Transitions from alkaline spots to regular bands during pH pattern formation at the plasmalemma of<Emphasis Type="Italic"> Chara</Emphasis> cells

A scanning pH-microprobe was used to study pH patterns near the surface of Chara corallina cells at various light intensities and during light-induced transitions from homogeneous pH distribution to alternating pH bands. In the irradiance (PAR) range 4-400 micromol quanta m(-2) s(-1), the sustained pH profiles consisted of alternating acid and alkaline bands with a characteristic length of 7-10 mm and pH shifts as large as 2-3 units. At lower irradiance, the number of alkaline bands decreased while the amplitude of remaining peaks stayed high. On cyclic changes in light intensity, a hysteresis of pH banding was observed: the pH bands tolerated low irradiance in weakening light, but higher irradiance was required for their emergence after dark adaptation of the cell. The pH profiles measured for different paths of electrode scanning suggest that the pH pattern at low light level represents patches coexisting with bands. The exposure of the cell to high-intensity light led to formation of radially symmetrical bands. Transformations of the pH pattern induced by lowering the light intensity were similar to those induced by transcellular electric current (1.5-3 microA). The data suggest that band formation at the plasmalemma of Chara cells proceeds through the initial appearance of multiple patches with a localized H(+)-transporting activity and subsequent spot rearrangements (fusion, deletions, widening), leading to establishment of alternating bands.     

Ion flux interaction with cytoplasmic streaming in branchlets of Chara australis

Both parts of the actin-myosin complex involved in cytoplasmic streaming could be regulated by mineral ions. The main goal of this study was to find a relationship between cyclosis and ion transport across the cell wall and plasma membrane. The transport of K(+) and Ca(2+) along pH bands in Chara branchlet internodal cells was characterized by using the MIFE system for non-invasive microelectrode measurement of ion fluxes. Branchlets formed acidic and alkaline bands with the pH ranging from 5 to 8. Different pH patterns were observed for different sides of the branchlets. Sides with cyclosis streaming acropetally generally showed greater variation in the profiles of pH and H(+) fluxes. Although a high correlation was not found between pH bands and Ca(2+) or K(+) fluxes, there was a positive correlation between Ca(2+) and K(+) fluxes themselves for both sides of the branchlets. Application of cytochalasin D, an inhibitor of cyclosis, had no immediate effect on pH and ion fluxes, however, the time of cyclosis cessation corresponded with a dramatic change in Ca(2+) and K(+) fluxes; pH profiles and H(+) fluxes were affected within 2 h. The evidence suggests that, in Chara branchlets, pH band formation and Gd(3+)-insensitive Ca(2+) transport systems are linked to the cyclosis machinery: (i) the pH band amplitude for the acropetally streaming side was larger than that for the basipetally streaming side; (ii) cessation of cytoplasmic streaming after cytochalasin D application resulted in changed pH banding profiles and H(+), Ca(2+) and K(+) fluxes; and (iii) the application of GdCl(3) or incubation in GdCl(3) solutions did not lead to the cessation of cytoplasmic streaming, although external Ca(2+) fluxes changed.     

Plasma membrane domains participate in pH banding of Chara internodal cells

We investigated the identity and distribution of cortical domains, stained by the endocytic marker FM 1-43, in branchlet internodal cells of the characean green algae Chara corallina and Chara braunii. Co-labeling with NBD C(6)-sphingomyelin, a plasma membrane dye, which is not internalized, confirmed their location in the plasma membrane, and co-labelling with the fluorescent pH indicator Lysotracker red indicated an acidic environment. The plasma membrane domains co-localized with the distribution of an antibody against a proton-translocating ATPase, and electron microscopic data confirmed their identity with elaborate plasma membrane invaginations known as charasomes. The average size and the distribution pattern of charasomes correlated with the pH banding pattern of the cell. Charasomes were larger and more frequent at the acidic regions than at the alkaline bands, indicating that they are involved in outward-directed proton transport. Inhibition of photosynthesis by DCMU prevented charasome formation, and incubation in pH buffers resulted in smaller, homogenously distributed charasomes irrespective of whether the pH was clamped at 5.5 or 8.5. These data indicate that the differential size and distribution of charasomes is not due to differences in external pH but reflects active, photosynthesis-dependent pH banding. The fact that pH banding recovered within several minutes in unbuffered medium, however, confirms that pH banding is also possible in cells with evenly distributed charasomes or without charasomes. Cortical mitochondria were also larger and more abundant at the acid bands, and their intimate association with charasomes and chloroplasts suggests an involvement in carbon uptake and photorespiration.     

Effect of cytoplasmic streaming on photosynthetic activity of chloroplasts in internodes of <Emphasis Type="Italic">Chara corallina</Emphasis>

Cytoplasmic streaming plays an important role in cell processes since it promotes solute exchange between the cytoplasm and organelles and enables lateral transport for extensive distances. The role of cyclosis in chloroplast functioning should be most conspicuous under conditions mimicking natural mosaic illumination and consequent alternation of cell regions with dominant dark and photosynthetic metabolism. Based on this assumption, we examined the light response curves and the induction kinetics of fluorescence-based parameters of chloroplast photosynthetic activity on small regions (d ∼ 100 μm) of Chara corallina Klein ex Willd. internodal cells exposed to local and overall illumination under conditions of normal cytoplasmic streaming and after suppression of cyclosis by cytochalasin B, an inhibitor of actin microfilaments. Under control conditions, the whole cell illumination caused non-photochemical quenching (NPQ) of chlorophyll fluorescence, which approached the saturation at a photon flux density of about 40 μmol/(m² s). By contrast, illumination of a small (2 mm wide) cell part did not cause significant NPQ at light intensities up to 100 μmol/(m² s), indicating that the chloroplast photosynthetic activity was substantially higher under conditions of localized illumination. After the inhibition of cyclosis by cytochalasin B, the light response curves were represented by nearly identical sigmoid curves, irrespective of the illumination pattern. When the cyclosis was restored in the cells washed from the inhibitor, the light response curves measured under overall and localized illumination returned to their original divergent shapes. These and other data indicate that different photosynthetic activities of chloroplasts in cells exposed to entire and partial illumination are directly related to the flow of compositionally nonuniform cytoplasm between the cell parts with prevalent photosynthetic and respiratory metabolism.     

Distribution of Acid and Alkaline Zones on the Cell Surface of Chara corallina under Stationary and Local Illumination

A scanning microprobe technique was used to study pH distribution near the cell surface of Chara corallina Klein ex Willd. under variations of light intensity, dark–light transitions, and local illumination of various cell parts. In darkness, the H⁺-transporting activity of plasmalemma was distributed homogeneously over the cell surface. However, after exposing the cell to weak light (irradiance 0.2–0.5 W/m²), individual alkaline peaks with pH of 1–2 units were observed in the longitudinal pH profile. The peaks in the longitudinal pH profile became more numerous with the increase in light intensity. The plot of pH as a function of light intensity included a steep transition from zero to its maximum amplitude. In strong light (100 W/m²), the pH bands alternated along the cell length with a periodic length of about 7 mm. It is shown that the light-induced formation of ring-shaped bands with H⁺-exporting and H⁺ sink activities is preceded by the appearance of irregularly located spots (patches). When small cell parts were illuminated and the light spot was suddenly shifted along the cell to another position, the alkaline bands reorganized in two ways. In some cases, this treatment was followed by a gradual shift in the band position (without attenuation in the peak height) toward the illuminated area. In other cases, the initial band disappeared after such treatment, and a new alkaline band emerged in the vicinity of the illuminated area. Despite the apparent similarity of regular bands in the longitudinal pH profiles, the properties of individual bands (variable sensitivity to light intensity changes, the ability of bands to move along the cell under external treatment) differ substantially. It is supposed that the light-induced formation of the pH profile is based on primary fluctuations of photosynthetic and transport activities in the chloroplast layer and the plasmalemma, as well as on further rearrangements of membrane domains that stabilize band locations.     

Cyclosis-related asymmetry of chloroplast–plasma membrane interactions at the margins of illuminated area in <Emphasis Type="Italic">Chara corallina</Emphasis> cells

Cytoplasmic streaming in plant cells is an effective means of intracellular transport. The cycling of ions and metabolites between the cytosol and chloroplasts in illuminated cell regions may alter the cytoplasm composition, while directional flow of this modified cytoplasm may affect the plasma membrane and chloroplast activities in cell regions residing downstream of the illumination area. The impact of local illumination is predicted to be asymmetric because the cell regions located downstream and upstream in the cytoplasmic flow with respect to illumination area would be exposed to flowing cytoplasm whose solute composition was influenced by photosynthetic or dark metabolism. This hypothesis was checked by measuring H⁺-transporting activity of plasmalemma and chlorophyll fluorescence of chloroplasts in shaded regions of Chara corallina internodal cells near opposite borders of illuminated region (white light, beam width 2 mm). Both the apoplastic pH and chlorophyll fluorescence, recorded in shade regions at equal distances from illuminated area, exhibited asymmetric light-on responses depending on orientation of cytoplasmic streaming at the light–shade boundary. In the region where the cytoplasm flowed from illuminated area to the measurement area, the alkaline zone (a zone with high plasma membrane conductance) was formed within 4-min illumination, whereas no alkaline zone was observed in the area where cytoplasm approached the boundary from darkened regions. The results emphasize significance of cyclosis in lateral distribution of a functionally active intermediate capable of affecting the membrane transport across the plasmalemma, the functional activity of chloroplasts, and pattern formation in the plant cell.     

The Influence of Light Intensity on the Activation and Operation of the Hydroxyl Efflux System of Chara corallina

The interrelationships between light intensity and the activationof OH^– bands was investigated. The lag period prior toOH^– efflux activation was longer than the photosyntheticinduction period. It was found that this lag period dependedupon the light regime employed as well as the photosyntheticcapacity of the cell. The response of the cell to low light intensities revealed thatall OH^– bands were not of equal status. Below a criticallight intensity the cell did not develop any bands even afterprolonged illumination. An hypothesis is presented to accountfor these results, interms of total cell OH^– band activationand the regulation of the HCO₃^– and OH^– transportsystems. It is proposed that the electrical properties of theChara corallina plasmalemma, observed at high pH values, canbe explained on the basis of the hypothesis presented in thispaper     

Cyclosis-mediated transfer of H2O2 elicited by localized illumination of Chara cells and its relevance to the formation of pH bands

Cytoplasmic streaming occurs in most plant cells and is vitally important for large cells as a means of long-distance intracellular transport of metabolites and messengers. In internodal cells of characean algae, cyclosis participates in formation of light-dependent patterns of surface pH and photosynthetic activity, but lateral transport of regulatory metabolites has not been visualized yet. Hydrogen peroxide, being a signaling molecule and a stress factor, is known to accumulate under excessive irradiance. This study was aimed to examine whether H₂O₂ produced in chloroplasts under high light conditions is released into streaming fluid and transported downstream by cytoplasmic flow. To this end, internodes of Chara corallina were loaded with the fluorogenic probe dihydrodichlorofluorescein diacetate and illuminated locally by a narrow light beam through a thin optic fiber. Fluorescence of dihydrodichlorofluorescein (DCF), produced upon oxidation of the probe by H₂O₂, was measured within and around the illuminated cell region. In cells exhibiting active streaming, H₂O₂ first accumulated in the illuminated region and then entered into the streaming cytoplasm, giving rise to the expansion of DCF fluorescence downstream of the illuminated area. Inhibition of cyclosis by cytochalasin B prevented the spreading of DCF fluorescence along the internode. The results suggest that H₂O₂ released from chloroplasts under high light is transported along the cell with the cytoplasmic flow. It is proposed that the shift of cytoplasmic redox poise and light-induced elevation of cytoplasmic pH facilitate the opening of H⁺/OH^?-permeable channels in the plasma membrane.     

Excitation-induced dynamics of external pH pattern in Chara corallina cells and its dependence on external calcium concentration.

The influence of cell excitation and external calcium level on the dynamics of light-induced pH bands along the length of Chara corallina cells is studied in the present paper. Generation of an action potential (AP) transiently quenched these pH patterns, which was more pronounced at 0.05-0.1 mM Ca2+ than at higher concentrations of Ca2+ (0.6-2 mM) in the medium. After transient smoothing of the pH bands, some alkaline peaks reemerged at slightly shifted positions in media with low Ca2+ concentrations, while at high Ca2+ concentrations, the alkaline spots reappeared exactly at their initial positions. This Ca2+ dependency has been revealed by both digital imaging and pH microelectrodes. The stabilizing effect of external Ca2+ on the locations of recovering alkaline peaks is supposedly due to formation of a physically heterogeneous environment around the cell owing to precipitation of CaCO3 in the alkaline zones at high Ca2+ during illumination. The elevation of local pH by dissolving CaCO3 facilitates the reappearance of alkaline spots at their initial locations after temporal suppression caused by cell excitation. At low Ca2+ concentrations, when the solubility product of CaCO3 is not attained, the alkaline peaks are not stabilized by CaCO3 dissolution and may appear at random locations.     

Fluorescence and Photosynthetic Activity of Chloroplasts in Acid and Alkaline Zones of Chara corallina

Continuous profiles of local pH near the cell surface of Chara corallinawere recorded during uniform longitudinal movement of an internodal cell relative to a stationary pH microelectrode. Under illumination, the pH profile consisted of alternating acid and alkaline bands with a pH difference of up to 3 pH units. After darkening, the bands disappeared and pH became uniformly distributed along the cell length. Chlorophyll fluorescence of chloroplasts was measured by microfluorometry at different locations within one cell, and significant differences were observed in close relation to light-dependent pH banding. The chlorophyll fluorescence yield was lower in zones of low external pH than in alkaline zones both under actinic and saturating light. The fluorescence parameters Fand F" _m and the quantum yield of photosystem II (PSII) displayed variations along the cell length in accordance with pH changes in unstirred layers of the medium. The results show that PSII photochemical efficiency and the rate of noncyclic electron transport are higher in the chloroplasts of acid zones (zones of H⁺extrusion from the cell) than in alkaline zones. The dependence of photosynthetic electron transport on local pH near the cell surface may result from different contents of CO₂in acid and alkaline regions. The acid zones are enriched with CO₂that readily permeates through the membrane providing the substrate for the Calvin cycle. Conversely, a poorly permeating form, HCO^– ₃is predominant in alkaline zones, which may restrict the dark reactions and photosynthetic electron flow.     

Role of cyclosis in asymmetric formation of alkaline zones at the boundaries of illuminated region in <Emphasis Type="Italic">Chara</Emphasis> cells

The role of cytoplasmic streaming in pattern formation at the plasma membrane and chloroplast layer was examined with Chara corallina Klein ex Willd. cells exposed to nonuniform illumination. Our hypothesis was that the exchange of ions and metabolites between the chloroplasts and the cytoplasm in the illuminated cell area alters the composition of the cytosol while the flow of modified cytoplasm induces asymmetrical changes in the plasmalemmal transport and fluorescence of chloroplasts in the adjacent shaded areas. The hypothesis was tested by measuring the H⁺-transporting activity of plasmalemma and non-photochemical quenching (NPQ) in shaded areas of Chara cells at distances of 1–5 mm on either side of the illuminated region (white light, 1000 μmol/(m² s), beam width 2 mm). When measured at equal distances on opposite sides from the illuminated region, both pH and NPQ changes differed considerably depending on the direction of cytoplasmic movement at the light-shade boundary. In the region where the cytoplasm flowed out of irradiated area, the formation of alkaline zone (the plasma membrane domain with a high H⁺-conductance) and NPQ in chloroplasts was observed. In the vicinity of light-shade boundary where the flow was directed from the shade to the illuminated area, neither alkaline zone nor NPQ were formed. The results demonstrate the significance of cyclosis in the transfer of physiologically active intermediate that affects the membrane transport, the functional activity of chloroplasts, and the pattern formation in the plant cell.     

Effects of cyclosis on chloroplast-cytoplasm interactions revealed with localized lighting in Characean cells at rest and after electrical excitation

Cytoplasmic streaming in Characean internodes enables rapid intracellular transport and facilitates interactions between spatially remote cell regions. Cyclosis-mediated distant interactions might be particularly noticeable under nonuniform illumination, in the vicinity of light-shade borders where metabolites are transported between functionally distinct cell regions. In support of this notion, chlorophyll fluorescence parameters assessed on a microscopic area of Chara corallina internodal cells (area of inspection, AOI) responded to illumination of nearby regions in asymmetric manner depending on the vector of cytoplasmic streaming. When a beam of white light was applied through a 400-μm optic fiber upstream of AOI with regard to the direction of cytoplasmic streaming, non-photochemical quenching (NPQ) developed after a lag period in AOI exposed to moderate intensity light. Conversely, no NPQ was induced in the same cell area when the beam position was shifted to an equal distance downstream of AOI. Light-response curves for the efficiency of photosystem II electron transport in chloroplasts differed markedly depending on the illumination pattern (whole-cell versus small area illumination) but these differences were eliminated after the inhibition of cytoplasmic streaming with cytochalasin B. Localized illumination promoted chloroplast fluorescence responses to electrical plasmalemma excitation at high light intensities, which contrasts to the requirement of low to moderate irradiances for observation of the stimulus-response coupling under whole-cell illumination. The results indicate that different photosynthetic capacities of chloroplasts under general and localized illumination are related to lateral transport of nonevenly distributed cytoplasmic components between the cell parts with dominant photosynthetic and respiratory metabolism.     

Ca2+ and phosphate releases from calcified Chara cell walls in concentrated KCl solution

Ca2+ and P(i) (inorganic phosphate) releases from isolated calcified and uncalcified Chara cell walls were measured with a Ca(2+)-selective electrode and colorimetry, and their ionic relations were analysed on the basis of the electroneutrality rule. The results showed that (1) not only Ca2+ but also P(i) can be released from isolated calcified Chara cell walls into pure deionized water and 100 mM KCl solution, and (2) the positive charge due to the Ca2+ released cannot be neutralized only by the negative charge from the simultaneously released P(i). These findings suggest that calcium bands of calcified Chara cell walls are composed of mainly CaCO(3) and CaHPO(4) and some anions other than P(i) should be released simultaneously with the Ca2+ and P(i). More Ca2+ and P(i) can be solubilized from isolated Chara cell walls in 100 mM KCl solution than in pure deionized water. The pH value of 100 mM KCl solution in which isolated uncalcified young Chara cell walls have been immersed is a little lower than that of pure deionized water in which the same isolated uncalcified young Chara cell walls have been immersed, suggesting that some acidic substances are solubilized by 100 mM KCl. To explain this from the viewpoint of solution chemistry, the solubilities of pure CaCO(3) and pure CaHPO(4) in water and 100 mM KCl solution were measured with a Ca2+ -selective electrode and their pH values with a glass pH electrode. The conclusion reached was that the Ca2+ release from isolated Chara cell walls is accompanied by the release of P(i), CO(2-)(3) and acidic substances. This suggests that the so-called calcium bands and/or ionic relations, including ion exchange, in Chara cell walls are chemically or physicochemically more complex than they are currently considered to be.     

Microtubule orientation and dynamics in elongating characean internodal cells following cytosolic acidification, induction of pH bands, or premature growth arrest

Summary Cortical microtubules (MTs) at indifferent zones in immatureNitella internodes were investigated by injection of fluorescently tagged sheep brain tubulin into living cells and by immunofluorescence on fixed material. Nearly identical MT patterns and numbers were detected with the two techniques, indicating that sheep brain tubulin incorporated into all cortical MTs. MTs were aligned transversely to the long axis of the cell and approximately one MT was present every micrometer of longitudinal cell distance. Treatment of internodes with propionic acid to acidify cytosolic pH caused depolymerization of MTs and an increase in the unpolymerized tubulin pool. Transfer of young, vigorously elongating cells to media inducing premature growth cessation resulted in a slight decrease in microtubule numbers but did not significantly alter microtubule orientation patterns or microtubule lifespans. MTs remained transverse for days following growth cessation before finally assuming a more random alignment characteristic of mature, non-growing internodes. No differences in MT numbers, orientation, or dynamics were detected between acid and alkaline bands in internodes incubated in a band-inducing medium. Thus, properties of cortical MT arrays were not closely coupled to growth status or to regional differences in cellular physiology associated with pH banding.Abbrevations BIM band-inducing medium - CCM Chara culture medium - CF carboxyfluorescein - FRAP fluorescence redistribution after photobleaching - MT microtubule     

Action potential in Chara cells intensifies spatial patterns of photosynthetic electron flow and non-photochemical quenching in parallel with inhibition of pH banding

Characean cells exposed to illumination arrange plasma-membrane H(+) fluxes and photosynthesis in coordinated spatial patterns. The limited availability of CO(2) in alkaline bands accounts for the lower effective quantum yield of photosystem II (DeltaF/F(m)') in chloroplasts of these bands compared to acidic zones. The effect of electrically triggered action potential on the spatial distribution of photosynthetic parameters (DeltaF/F(m)' and non-photochemical quenching, NPQ) and extracellular pH was studied with fluorescence imaging and pH microelectrodes. In the resting cell at a range of light intensities, the periodic profile of extracellular pH is parallel to the profile of NPQ and antiparallel to that of DeltaF/F(m)'. After triggering the action potential, the pH banding temporarily disappeared, but in contrast, the differences in effective quantum yield and NPQ patterns became more apparent. The transient changes in pH-banding, effective quantum yield and non-photochemical quenching are discussed in relation to alterations in intracellular Ca(2+) and H(+) concentrations during and after the action potential.     

Microtubule organization differs between acid and alkaline bands in internodal cells ofChara but bands can develop in the absence of microtubules

We have studied the relationship between pH banding and the organization of cortical microtubules in the alga Chara corallina Klein ex Willd. Microtubules were visualized by immunofluorescence and also by imunogold-silver enhancement to allow immediate comparison of microtubule arrangement with visible structural cell features. In cells that are nearing growth completion, microtubule number and alignment change between acidic and alkaline bands over a distance of a few micrometres. Thus, it appears that the still unknown mechanisms for microtubule organization respond to the localized differences in membrane properties. Band formation was not prevented when microtubules were depolymerized with the herbicide oryzalin, demonstrating that microtubules are not necessary for pH bands to develop in these cells.Abbreviations DMSO dimethylsulfoxide - MT microtubule We thank Frank Gubler for helpful advice on immunogold-silver enhancement procedures, Brian Gunning for tuition in confocal microscopy, Ann Cork for assistance with photography and Dean Price for helpful discussions. G.O.W. gratefully acknowledges the receipt of a National Research Fellowship and a Queen Elizabeth II Fellowship from the Australian Research Council.     

Effect of a Single Excitation Stimulus on Photosynthetic Activity and Light-dependent pH Banding in <Emphasis Type="Italic">Chara</Emphasis> Cells

Using pH microelectrodes and a Micro-scopy PAM (pulse-amplitude modulated) chlorophyll fluorometer, it is shown that a propagation of an action potential in Chara corallina leads to transient suppression of spatially periodic pH profiles along the illuminated cell. The suppression was manifested as a large pH decrease in the alkaline zones and a slight pH increase in the acid zones. The propagating action potential diminished the maximum yield of chlorophyll fluorescence (F_m′) in the alkaline cell regions, as well as the quantum yield of photosystem II photochemistry, without affecting F_m′ in the acid cell regions. The results indicate an interference of membrane excitation in the mechanisms responsible for pH banding patterns in Characean algae. Apparently, the electrical excitation of the plasma membrane in the alkaline cell regions initiates a pathway that can modulate membrane events at the thylakoid membrane.     

Spatial coordination of chloroplast and plasma membrane activities in <Emphasis Type="Italic">chara</Emphasis> cells and its disruption through inactivation of 14-3-3 proteins

In Chara corallina cells exposed to continuous light, external pH (pH(o)) and photosystem II (PSII) photochemical yield show correlated banding patterns. Photosynthetic activity is low in cell regions producing alkaline zones and high in the acid regions. We addressed the question whether (and how) photosynthetic activity and plasma membrane (PM) H+-pumping and H+-conductance are coupled in the different bands. First, PM H+-pump activity was stimulated with fusicoccin. This resulted in a more acidic pH in the acid bands without disturbing the correlation of photosynthetic electron transport and H+ fluxes across the PM. Next, H+-pump activity was reduced through microinjection of a phosphorylated peptide matching the canonical 14-3-3 binding motif RSTpSTP in the acid cell region. Microinjection induced a rapid (~5 min) rise in pH(o) by ca. 1.0 unit near the injection site, whereas the injection of the non-phosphorylated peptide had no effect. This pH rise confirms the supposed inhibition of the H+-pump upon the detachment of 14-3-3 proteins from the H+-ATPase. However, the PSII yield in the cell regions corresponding to the new alkaline peak remained high, which violated the normal inverse relations between the pH(o) and PSII photochemical yield. We conclude that the injection of the competitive inhibitor of the H+-ATPase disrupts the balanced operation of PM H+-transport and photosynthetic electron flow and promotes electron flow through alternative pathways.     

The internal pH of synaptic-like microvesicles in rat pinealocytes in culture

Synaptic-like microvesicles (SLMVs) are morphological and functional equivalents of neuronal synaptic vesicles, and are responsible for the storage and secretion of classical neurotransmitters in various endocrine cells. Vacuolar H+-ATPase acidifies the internal space of these organelles and provides a driving force for the uptake of neurotransmitters. Thus, the luminal pH is an important determinant of the function of SLMVs, although its value in living cells is unknown. Here, we determined the luminal pH of SLMVs in living rat pinealocytes by means of an immunoelectronmicroscopic procedure basedon the distribution of an amphipathic amine, 3-(2,4-dinitroanilino)-3'-amino-N-methyldipropylamine (DAMP). Use of double-labeling techniques with antibodies against 2,4-dinitrophenol for DAMP and synaptophysin for SLMVs, and of frozen ultrathin sections enabled us to determine the number of immunogold particles for DAMP per microm2 of SLMVs. Using the density of gold particles, the luminal pH of SLMVs was calculated to be 5.11 +/- 0.01. Treatment with either 1 microm bafilomycin A1, a specific inhibitor of vacuolar H+-ATPase, or 50 mm ammonium chloride, a dissipater of the transmembrane pH gradient, increased the luminal pH to 6.04 +/- 0.07 and 6.05 +/- 0.11, respectively. Simultaneously, the lysosomal pH was found to be 5.14 +/- 0.07, which increased to 5.77 +/- 0.09 and 5.93 +/- 0.13 with bafilomycin A1 and ammonium chloride, respectively. It is concluded that the luminal pH of SLMVs is comparable to that of lysosomes in vivo.