Effect of Temperature and External pH on the Cytoplasmic pH of Chara corallina

Cytoplasmic pH (pH_c) in Chara corallina was measured (from [¹⁴C]stribution)as a function of external pH (pH₀)and temperature. With pH₀near 7, pH_c at 25?C is 7.80; pH_cincreases by 0.005 pH units?C^–1 temperature decrease, i.e. pH_c at 5 ?C is 7.90. WithpH? near 5.5, the increase in pH_c with decreasing temperatureis 0.015 units ?C^–1 between 25 and 15?C, but 0.005 units?C^–1 between 15 and 5?C. This implies a more precise regulationof pH_c with variations in pH_o at 5 or 15 ?C compared with 25?C. The observed dp H_c/dT is generally smaller than the –0.017units ?C^–1 needed to maintain a constant H⁺/OH^–1,or a constant fractional ionization of histidine in protein,with variation in temperature. It is closer to that needed tomaintain the fractional ionization of phosphorylated compoundsor of CO₂–HCO₃^– The value of dpH_c/dT has importantimplications for several regulatory aspects of cell metabolism.These include (all as a function of temperature) the rates ofenzyme reactions, the _H+ at the plasmalemma(and hence the energy available for cotransport processes),and the mechanism for pH_c regulation by the control of bidirectionalH⁺ fluxes at the plasmalemma.     

Effects of Water Stress on the Respiratory and Nitrogen-fixing Activity of Soybean Root Nodules

Seventy-five per cent of the N₂-fixing activity (measured asthe reduction of C₂H₂ to C₂H₄) and 50 per cent of the respiratoryactivity of detached soybean root nodules was lost when thewater potential () of the nodules was lowered from approximately–1 ? 105 Pa (turgid nodules) to –9 ? 105 Pa (moderatelystressed nodules). Severely stressed nodules ( = –1.8? 10⁶ Pa) showed almost total loss of N₂-fixing activity andup to 80 per cent loss of respiratory activity. Increasing theoxygen partial pressure (PO₂) from 10⁴ to 10⁵ Pa completelyrestored both N₂-fixation and respiration in moderately stressednodules, but only partial recovery was possible in severelystressed nodules. The activity of the stressed nodules was verylow at low PO₂ (5 ? 10³ and 10⁴ Pa). The C₂H₂-reducing activityof nodule slices, nodule breis, and bacteroids from turgid andmoderately stressed nodules was almost identical but some activitywas lost in the breis and bacteroids from severely stressednodules. Calculations showed that at low PO₂ (10⁴ and 2 ? 10⁴Pa), the rate of O₂ diffusion into severely stressed noduleswas ten times lower than that for turgid nodules, but only fourtimes lower at a higher PO₂ (4 ? 10⁴ Pa). Carbon monoxide inhibitionof C₂H₂ reduction was slower in stressed nodules than in turgidnodules. The results are discussed in view of the possible developmentof a physical barrier to gaseous diffusion and/or the possiblealtered affinity of the nodule leghaemoglobin for O₂ in thewater-stressed nodules.     

Regulation of the Cytoplasmic pH of Chara corallina in the Absence of External Ca2+: Its Significance in Relation to the Activity and Control of the H+ Pump

Effects of removal of external Ca²⁺ on the cytoplasmic pH (pH_c)of Chara corallina have been measured with the weak acid 5,5-dimethyl-oxazolidine-2,4-dione(DMO) as a function of external pH (pH₀) and of the externalconcentration of K⁺. Removal of Ca²⁺ always decreased pH_c whenpH₀ was below about 6.0; the decrease was about 0.2–0.4units at pH₀ 5.0, increasing to about 0.5 units at pH₀ 4.3.When pH₀ was 6.0 or higher the removal of Ca²⁺ had little orno effect on pH_c. This situation was not altered by changingthe concentration of K⁺, though in some experiments at pH₀ 5.0–5.2there was a slight decrease in pH₀ (about 0.2 units) when K⁺was increased from 0.2 to 2.0 mol m^–3, an effect apparentlyreversed when K⁺ was higher (5.0 or 10.0 mol m^–3). Theresults suggest that H⁺ transport continues in the absence ofexternal Ca²⁺, despite previous suggestions to the contrary,and that the H⁺ pump does not necessarily run near thermodynamicequilibrium with its chemical driving reaction. They indicate,rather, that the H⁺ pump is under kinetic control and providefurther evidence for the inadequacy of present models for theoperation of the H⁺ pump in charophyte cells, especially inrelation to its proposed role in regulating pH_c. Key words: Chara corallina, Cytoplasmic pH, Calcium     

Proton Transport and pH Control in Sinapis alba Root Hairs: A Study carried out with Double-Barrelled pH Micro-electrodes

Continuous measurements of cytoplasmic pH (pH_c) in Sinapis roothairs have been carried out with double-barrelled pH-micro-electrodesin order to gain information on translocation of protons acrossthe plasmalemma and cytoplasmic pH control. (i) The cytoplasmicpH of Sinapis (7–33 ? 0–12, standard conditions)changes no more than 0.1 pH_c, per pH_o-unit, regardless of whethercyanide is present or not. (ii) Weak acids rapidly acidify pH_cand hyperpolarize, while weak bases alkalize pH_c and depolarizethe cells, (iii) 1.0 mol M,³ NaCN acidifies the cytoplasm by0.4 to 0.7 pH-units, but alkalizes the vacuole. (iv) 20 mmolm^–3 CCCP has no significant effect on pH_c, if added atpH 9.6 or 7.2, but acidifies pH_c by 1.3 units at pH 4.3. Inthe presence of CCCP, cyanide acidifies the cytoplasm, (v) Chloridetransiently acidifies pH_c, while K⁺, Na⁺, and have no significant effects, (vi) Cytoplasmic buffer capacityforms a bell-shaped curve versus pH_c with an optimum of about50 mol m^–3 H⁺pH_c-unit. The modes of proton re-entry and the effects of active and passiveproton transport on cellular pH control are critically discussed.It is suggested that the proton leak, consisting of H⁺-cotransport(e.g. H⁺/Cl^–) rather than H⁺-uniport, is no threat topH_c. The proton export pump, although itself reacting to changesin pH_c, influences pH_c only to a minor extent. It is concludedthat buffer capacity and membrane transport play moderate rolesin pH_c control in Sinapis, while the interlocked H⁺-producingand -consuming reactions of cellular metabolism are the mainregulating factors. This makes pH control in Sinapis quite differentfrom bacterial and animal cells. Key words: Cytoplasmic pH, double-barrelled pH micro-electrode, pH control, proton transport, Sinapis     

Intracellular pH homeostasis in cultured human placental syncytiotrophoblast cells: recovery from acidification

Resting or basal intracellular pH (pH_i) measured in cultured human syncytiotrophoblast cells was 7.26 ± 0.04 (without HCO₃^–) or 7.24 ± 0.03 (with HCO₃^–). Ion substitution and inhibitor experiments were performed to determine whether common H⁺-transporting species were operating to maintain basal pH_i. Removal of extracellular Na⁺ or Cl^– or addition of amiloride or dihydro-4,4'-diisothiocyanatostilbene-2,2'-disulfonate (H₂DIDS) had no effect. Acidification with the K⁺/H⁺ exchanger nigericin reduced pH_i to 6.25 ± 0.15 (without HCO₃^–) or 6.53 ± 0.10 (with HCO₃^–). In the presence of extracellular Na⁺, recovery to basal pH_i was prompt and occurred at similar rates in the absence and presence of HCO₃^–. Ion substitution and inhibition experiments were also used to identify the species mediating the return to basal pH_i after acidification. Recovery was inhibited by removal of Na⁺ or addition of amiloride, whereas removal of Cl^– and addition of H₂DIDS were ineffective. Addition of the Na⁺/H⁺ exchanger monensin to cells that had returned to basal pH_i elicited a further increase in pH_i to 7.48 ± 0.07. Analysis of recovery data showed that there was a progressive decrease in pH per minute as pH_i approached the basal level, despite the continued presence of a driving force for H⁺ extrusion. These data show that in cultured syncytial cells, in the absence of perturbation, basal pH_i is preserved despite the absence of active, mediated pH maintenance. They also demonstrate that an Na⁺/H⁺ antiporter acts to defend the cells against acidification and that it is the sole transporter necessary for recovery from an intracellular acid load. sodium/hydrogen antiporter; pH regulation; fluorescence; 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein     

Hydrogen Effect on Nitrogenase (C2H2 Reduction) Response to Oxygen in Bradyrhizobium japonicum-Phaseoleae Symbioses

The influence of hydrogenase in Bradyrizobum-Phaseoleae symbioseswas studied ex-planta and in-planra in soybean (Glycine max)and cowpea (Vigna unguiculata). The hydrogenase was activatedby the addition of hydrogen in the incubation gas phase whichmodified the response of nitrogenase activity of Hup⁺ (hydrogenuptake positive) symbiosis to the external oxygen partial pressure.For bacteroids the hydrogenase expression increased nitrogenaseactivity at supraoptimal pO₂, acting possibly as a respiratoryprotection of nitrogenase. However, at suboptimal pO₂, nitrogenaseactivity of Hup⁺ bacteroids decreased with hydrogen, a phenomenonattributed to the lower efficiency of ATP synthesis from hydrogenthan from carbon substrates oxidation. For undisturbed nodules,the hydrogenase expression in soybean increased the optimalpO₂ for ARA (COP), from 35.3 to 40.3 kPa O₂, and the ARA atsupraoptimal pO₂; at suboptimal PO₂ there was a negative effectof hydrogenase on ARA, although this inhibition was less thanon bacteroids and was not detected if plants were grown at 15°C rather than 20 °C root temperature. No H₂ effectwas detected on cowpea nodules. The results on soybean nodulesare consistent with the concept that symbiotic nitrogen fixationis oxygen-limited and that hydrogenase activity has no beneficialeffect on nitrogen fixation in O₂ limitation. Key words: Glycine max, hydrogenase, nitrogenase, nitrogen fixation, nodules, Vigna unguiculata     

Dormancy in Seeds of Charlock: IV. INTERRELATIONSHIPS OF GROWTH, OXYGEN SUPPLY AND CONCENTRATION OF INHIBITOR

Respiration measurements were made over a period of 24 h at25 °C on seeds and excised embryos maintained in Warburgflasks with partial pressures of oxygen ranging from 0 to 1atm. In the initial phase (0 to 4 h), the rate of oxygen uptake(Q_O2 of excised embryos increased linearly with external oxygenconcentration (C_O from 0 to 0.1 atm O₂ from 0.1 to 0.2 atm O₂the relation was curvilinear, and from 0.2 to 1.0 atm O₂ uptakewas independent of concentration. In later stages the relationbetween Q_O2 and C_o changed, and from 20 to 24 h the rate ofoxygen uptake increased with concentration to 1.0 atm O₂. Thechanges with time were associated with increase in rate of respiration,increase in cell size and cell number, and the oxidation offats. The decline in concentration of oxygen from the surfaceto the centre of embryos was calculated to be relatively smallat each external oxygen concentration. Althugh the rate of diffusionfailed to keep pace with consumption, the main parameters whichdetermined the internal oxygen status of the embryos were thesurface concentrations and the permeability of the seed coat.The resistance of the seed coat to diffusion of oxygen was foundto be very high, the coefficient of diffusion being about 10^–7mm² s^–1. The concentration of oxygen and in air were estimatedto be approximately 0.04 and 0.02 atm O₂, respectively. Sincea smaller concentration of oxygen (0.012 atm O₂) in the tissueswas found to be sufficient for growth, the dormancy of the seedswas not due to lack of oxygen. Dormancy appeared to be due tothe activity of growth-inhibiting substances, the concentrationof which increased with decrease in oxygen supply; below 0.1atm O₂ their rate of production increased with decrease in theoxygen concentration of the tissues. They accumulated withinthe testas of dormant seeds and prevented cell elongation. Extractsof the inhibitory substances were partially purifield by partitioningthe aqueous fraction with ether and separating chromatographically.The active principle(s) was not abscisic acid ((+)—AbscisinII, ‘Dormin’) or the mustard oil, allylisothiocyanate.     

Phosphate Uptake in the Cyanobacterium Synechococcus R-2 PCC 7942

Phosphate uptake rates in Synechococcus R-2 in BG-11 media (anitrate-based medium, not phosphate limited) were measured usingcells grown semi-continuously and in continuous culture. Netuptake of phosphate is proportional to external concentration.Growing cells at pH_o 10 have a net uptake rate of about 600pmol m^–2 s^–1 phosphate, but the isotopic flux for³²P phosphate was about 4 nmol m^–2 s^–1. There appearsto be a constitutive over-capacity for phosphate uptake. TheK_m and V_max, of the saturable component were not significantlydifferent at pH_o 7.5 and 10, hence the transport system probablyrecognizes both H₂PO^–₄and HPO^2–₄. The intracellularinorganic phosphate concentration is about 3 to 10 mol m^–3,but there is an intracellular polyphosphate store of about 400mol m^–3. Intracellular inorganic phosphate is 25 to 50kJ mol^–1 from electrochemical equilibrium in both thelight and dark and at pH_o 7.5 and 10. Phosphate uptake is veryslow in the dark ( 100 pmol m^–2 s^–1) and is light-activated(pH_o 7.51.3 nmol m^–2 s^–1, pH_o 10600 pmol m^–2s^–1). Uptake has an irreversible requirement for Mg²⁺in the medium. Uptake in the light is strongly Na⁺-dependent.Phosphate uptake was negatively electrogenic (net negative chargetaken up when transporting phosphate) at pH_o 7.5, but positivelyelectrogenic at pH_o 10. This seems to exclude a sodium motiveforce driven mechanism. An ATP-driven phosphate uptake mechanismneeds to have a stoichiometry of one phosphate taken up perATP (1 PO_{4 in}/ATP) to be thermodynamically possible under allthe conditions tested in the present study. (Received June 16, 1997; Accepted September 4, 1997)     

Transmembrane domain histidines contribute to regulation of AE2-mediated anion exchange by pH

Activity of the AE2/SLC4A2 anion exchanger is modulated acutely by pH, influencing the transporter's role in regulation of intracellular pH (pH_i) and epithelial solute transport. In Xenopus oocytes, heterologous AE2-mediated Cl^–/Cl^– and Cl^–/HCO₃^– exchange are inhibited by acid pH_i or extracellular pH (pH_o). We have investigated the importance to pH sensitivity of the eight histidine (His) residues within the AE2 COOH-terminal transmembrane domain (TMD). Wild-type mouse AE2-mediated Cl^–/Cl^– exchange, measured as DIDS-sensitive ³⁶Cl^– efflux from Xenopus oocytes, was experimentally altered by varying pH_i at constant pH_o or varying pH_o. Pretreatment of oocytes with the His modifier diethylpyrocarbonate (DEPC) reduced basal ³⁶Cl^– efflux at pH_o 7.4 and acid shifted the pH_o vs. activity profile of wild-type AE2, suggesting that His residues might be involved in pH sensing. Single His mutants of AE2 were generated and expressed in oocytes. Although mutation of H1029 to Ala severely reduced transport and surface expression, other individual His mutants exhibited wild-type or near-wild-type levels of Cl^– transport activity with retention of pH_o sensitivity. In contrast to the effects of DEPC on wild-type AE2, pH_o sensitivity was significantly alkaline shifted for mutants H1144Y and H1145A and the triple mutants H846/H849/H1145A and H846/H849/H1160A. Although all functional mutants retained sensitivity to pH_i, pH_i sensitivity was enhanced for AE2 H1145A. The simultaneous mutation of five or more His residues, however, greatly decreased basal AE2 activity, consistent with the inhibitory effects of DEPC modification. The results show that multiple TMD His residues contribute to basal AE2 activity and its sensitivity to pH_i and pH_o. pH regulation; histidine residues; Cl^–/HCO₃^– exchange     

N2 Fixation and the Respiratory Costs of Nodules, Nitrogenase Activity, and Nodule Growth and Maintenance in Fiskeby Soyabean

The respiratory effluxes of nodules and of roots of FiskebyV soyabean (Glycine max (L.) Merr.), grown in a controlled environment,were measured at intervals in air and 3% O₂ from shortly afterthe onset of N₂ fixation until plant senescence. The respiratoryburdens linked with nitrogenase plus ammonia metabolism, andnodule growth and maintenance, were calculated from gas exchangedata and related to the concurrent rates of N₂ fixation. The specific respiration rates of nodules increased to a maximumof 21 mg CO₂ g^–1 h^–1 at the time pods began development:the equivalent maximum for roots was c. 4.5 mg CO₂ g^–1h^–1. Maximum nodule and root respiration rates per plantwere attained about 25 d later at the time N₂ fixation peakedat 15 mg N d^–1 plant^–1. The relationship between nodule respiration and N₂ fixationindicated an average respiratory cost of 13.2 mg CO₂ mg^–1N until the last few days of plant development Separation ofnodule respiration into the two components: nitrogenase (+ NH₃metabolism) respiration and nodule growth and maintenance respiration,indicated that the latter efflux accounted for c. 20% of nodulerespiration while N₂ fixation was increasing and new noduletissue was being formed. When nodule growth ceased and N₂ fixationdeclined, this component of respiration also declined. The respiratorycost of nitrogenase activity plus the associated metabolismof NH₃ varied between 11 mg CO₂ mg^–1 N during vegetativeand early reproductive growth, to 12.5 mg CO₂ mg^–1 N duringthe later stages of pod development. Key words: N2 fixation, Respiration, Nodules, Nitrogenase     

Light-Induced H+ Accumulation in the Vacuole of Nitellopsis obtusa

The effects of light on the pH in the vacuole and the electricpotential difference across the plasmalemma and the tonoplastof Nitellopsis obtusa were investigated by means of conventionaland H⁺-specific glass or antimony microelectrodes. Illuminationis found to bring about a decrease in the pH of the vacuolarsap by 0.1–0.5 units concomitant with a depolarizationof the cell. The light-induced changes of the potential differenceand the vacuolar pH depend in different ways on the pH of theexternal medium (pH_o). At pH_o 9.0 cells exhibit great light-inducedpotential changes (up to 100 mV), but only small pH changesof the vacuolar sap. At neutral or slightly acidic pH_o valuesthe amplitude of the light-induced pH changes in the vacuoleincreases up to 0.3–0.5 pH units, but the amplitudes ofthe potential changes at the plasmalemma are relatively small.At pH_o 9.0 a transient acidification of the medium is observedupon illumination whereas at lower pH values light-induced alkalinizationwas only seen. Transfer of the cells from pH_o 9.0 to pH_o 7.5results in a cell hyperpolarization by 60–80 mV and adecrease of the vacuolar pH by 0.4–0.5 units under lightconditions but has no significant effect on the potential andthe vacuolar pH in the darkness. It is proposed that mechanismsof active H⁺ extrusion from the cytoplasm are located both inthe plasmalemma and the tonoplast. The observed acidificationin the vacuole appears to be determined by a light-induced increaseof the concentration of H⁺ in the cytoplasm. The H⁺ conductionof the plasmalemma seems to increase on illumination. The patternof the light-induced H⁺ fluxes across the tonoplast and theplasmalemma depends crucially on the extent of the light-inducedchanges in the H⁺ conductance and on the electrochemical gradientfor H⁺ at the plasmalemma.     

Chloride Transport in Chara corallina and the Electrochemical Potential Difference for Hydrogen Ions

The pH of the cytoplasm of Chara corallina cells has been measuredwith the weak acid 5,5-dimethyloxazolidine-2,4-dione (DM0).Over an external pH range 4·5–9·5 the resultsfit the regression equation pH_cytoplasm=6·28+0·22pH_out. Using measured values of the electric potential difference acrossthe plasmalemma we have calculated the electrochemical potentialdifference across this membrane for H⁺ and Cl^–. Thesedata are used to test the hypothesis that the inward transportof Cl^– is coupled to the inthix of H⁺ or, which comesto the same thing, efflux of OH^–. One-for-one couplingwill not give net Cl^– uptake from solutions with pH greaterthan about 7·2, unless the cytoplasmic Cl^– concentrationis lower than 10 mM, or the pH just outside the membrane islower than that in the bulk solution. It is shown that net Cl^–uptake proceeds from solutions with pH up to 9. The alternative possibility is that Cl^– transport is broughtabout by co-transport of two H⁺ for each Cl^–; this isnot ruled out by the results reported. Such a mechanism mightbe detectable by its electrogenic effect: although such effectshave not been detected, it is shown that they would be smallunder most conditions. Other possible mechanisms are discussed.     

Oxidative stress decreases pHi and Na(+)/H(+) exchange and increases excitability of solitary complex neurons from rat brain slices

Putative chemoreceptors in the solitary complex (SC) are sensitive to hypercapnia and oxidative stress. We tested the hypothesis that oxidative stress stimulates SC neurons by a mechanism independent of intracellular pH (pH_i). pH_i was measured by using ratiometric fluorescence imaging microscopy, utilizing either the pH-sensitive fluorescent dye BCECF or, during whole cell recordings, pyranine in SC neurons in brain stem slices from rat pups. Oxidative stress decreased pH_i in 270 of 436 (62%) SC neurons tested. Chloramine-T (CT), N-chlorosuccinimide (NCS), dihydroxyfumaric acid, and H₂O₂ decreased pH_i by 0.19 ± 0.007, 0.20 ± 0.015, 0.15 ± 0.013, and 0.08 ± 0.002 pH unit, respectively. Hypercapnia decreased pH_i by 0.26 ± 0.006 pH unit (n = 95). The combination of hypercapnia and CT or NCS had an additive effect on pH_i, causing a 0.42 ± 0.03 (n = 21) pH unit acidification. CT slowed pH_i recovery mediated by Na⁺/H⁺ exchange (NHE) from NH₄Cl-induced acidification by 53% (n = 20) in -buffered medium and by 58% (n = 10) in HEPES-buffered medium. CT increased firing rate in 14 of 16 SC neurons, and there was no difference in the firing rate response to CT with or without a corresponding change in pH_i. These results indicate that oxidative stress 1) decreases pH_i in some SC neurons, 2) together with hypercapnia has an additive effect on pH_i, 3) partially inhibits NHE, and 4) directly affects excitability of CO₂/H⁺-chemosensitive SC neurons independently of pH_i changes. These findings suggest that oxidative stress acidifies SC neurons in part by inhibiting NHE, and this acidification may contribute ultimately to respiratory control dysfunction. hyperoxic hyperventilation; O₂ toxicity; pH regulation; brain stem; reactive oxygen species     

Requirement of Manganese for Electron Donation of Hydrogen Peroxide in Photosystem II Reaction Center Complex

Mn²⁺ was required for the electron donating reaction from H₂O₂,but not for that from diphenylcarbazide (DPC), in the PS IIreaction center complex which was prepared from spinach chloroplastsby Triton X-100 extraction. The reaction center complex showeda high activity of 2,6-dichloroindophenol (DCIP) photoreductionin the presence of DPC, but a low activity with H₂O₂. The H₂O₂-supportedDCIP photoreduction was suppressed by EDTA and enhanced by asmall amount of Mn²⁺. Ca²⁺ and Mg²⁺ could not replace Mn²⁺.The activation by Mn²⁺ and its binding showed two binding sitesof Mn²⁺ in the reaction center complex, with high (1.5?10⁷ M^–1)and low (1 ? 10⁶ M^–1) binding constants. (Received November 8, 1986; Accepted April 10, 1987)     

pH of TGN and recycling endosomes of H+/K+-ATPase-transfected HEK-293 cells: implications for pH regulation in the secretory pathway

The influences of the gastric H⁺/K⁺ pump on organelle pH during trafficking to and from the plasma membrane were investigated using HEK-293 cells stably expressing the - and -subunits of human H⁺/K⁺-ATPase (H⁺/K⁺-, cells). The pH values of trans-Golgi network (pH_TGN) and recycling endosomes (pH_RE) were measured by transfecting H⁺/K⁺-, cells with the pH-sensitive GFP pHluorin fused to targeting sequences of either TGN38 or synaptobrevin, respectively. Immunofluorescence showed that H⁺/K⁺-ATPase was present in the plasma membrane, TGN, and RE. The pH_TGN was similar in both H⁺/K⁺-, cells (pH_TGN 6.36) and vector-transfected ("mock") cells (pH_TGN 6.34); pH_RE was also similar in H⁺/K⁺-, (pH_RE 6.40) and mock cells (pH_RE 6.37). SCH28080 (inhibits H⁺/K⁺-ATPase) caused TGN to alkalinize by 0.12 pH units; subsequent addition of bafilomycin (inhibits H⁺ v-ATPase) caused TGN to alkalinize from pH 6.4 up to a new steady-state pH_TGN of 7.0–7.5, close to pH_cytosol. Similar results were observed in RE. Thus H⁺/K⁺-ATPases that trafficked to the plasma membrane were active but had small effects to acidify the TGN and RE compared with H⁺ v-ATPase. Mathematical modeling predicted a large number of H⁺ v-ATPases (8,000) active in the TGN to balance a large, passive H⁺ leak (with P_H 10^–3 cm/s) via unidentified pathways out of the TGN. We propose that in the presence of this effective, though inefficient, buffer system in the Golgi and TGN, H⁺/K⁺-ATPases (estimated to be 4,000 active in the TGN) and other transporters have little effect on luminal pH as they traffic to the plasma membrane. pHluorin; H⁺ v-ATPase; trans-Golgi network; organelle pH; H⁺ permeability     

Presence of the distinct systems responsible for superoxide anion and hydrogen peroxide generation in red tide phytoplankton Chattonella marina and Chattonella ovata

Raphidophycean flagellates, Chattonella marina and C. ovata,are harmful red tide phytoplankters; blooms of these phytoplanktersoften cause severe damage to fish farming. Previous studieshave demonstrated that C. marina and C. ovata continuously producereactive oxygen species (ROS) such as superoxide anion (O₂^–)hydrogen peroxide (H₂O₂) under normal growth conditions, andan ROS-mediated toxic mechanism against fish and other marineorganisms has been proposed. Although the exact mechanism ofROS generation in these phytoplankters still remains to be clarified,our previous study suggested that NADPH oxidase-like enzymelocated on the cell surface of C. marina may be involved inO₂^– generation. To investigate the localization of O₂^–and H₂O₂ generation in C. marina and C. ovata, we employed 2-methyl-6(p-methoxyphenyl)-3,7-dihydroimidazo[1,2-a]pyrazin-3-oneand 5-(and-6)-carboxy-2',7'-dichlorodihydrodihydrofluoresceindictate, acetyl ester, which are specific fluorescent probefor detecting O₂^– and H₂O₂, respectively. Observationby fluorescence microscopy of live phytoplankters incubatedwith each probe revealed that O₂^– is mainly generatedon the cell surface, whereas H₂O₂ is generated in the intracellularcompartment in these phytoplankters. When the cells were rupturedby ultrasonic treatment, O₂^– levels of C. marina and C.ovata decreased significantly, whereas a few times higher levelsof H₂O₂ were detected in the ruptured cell suspensions whencompared with the levels of the live cell suspension. In immunoblottinganalysis, the protein recognized by anti-human gp91 phox wasdetected in both species. These results suggest that, in bothphytoplankters, the underlying mechanisms of O₂^– and H₂O₂generation may be distinct and such systems are independentlyoperating in the cells.     

Transient Cytoplasmic pH Changes in Correlation with Opening of Potassium Channels in Eremosphaera

Steigner, W. Khler, K., Simonis, W. and Urbach, W. 1988. Transientcytoplasmic pH changes in correlation with opening of potassiumchannels in Eremosphaera.—J. exp. Bot. 39: 23–36. The role of the cytoplasmic pH (pH_c) of Eremosphaera viridisin the signal transduction chain after light-off from the chloroplaststo the K⁺ channels in the plasmalemma of this unicellular algawas investigated. The temporary opening of K⁺ channels is indicatedby a transient hypcrpolarization (TP). To record rapid changesof pH_c, continuous measurements with pH sensitive micro-electrodeswere carried out. (i) Under normal conditions pH_c in the light(7·56 ±0·2) did not differ from pHc inthe dark (7·62 ±0·2). (ii) The vacuolepH ranged between 4·8 and 5·2. (iii) After light-offa rapid transient acidification of pHc O19±0·07occurred and a TP was released, (iv) In every case, the startof the transient acidification after light-off preceded thehyperpolarization by about 3s. (v) Light-on caused a rapid transientalkalinization but never a TP. (vi) Change to acid externalmedium (3.2) transiently acidified the cytoplasm and was ableto release a TP. (vii) After addition of NH₄Cl, pH_c again showeda rapid transient acidification and the release of a TP. The origin of the protons appearing in the cytoplasm after light-offis discussed critically with respect to the buffer capacity.Either direct or indirect translocation is a possible mechanismfor the movement of H⁺ from the chloroplasts into the cytoplasm.The intracellular acidification and its relation to the openingof potassium channels in the plasmalemma leads us to suggestthat a sudden change of pH_c is a potent internal signal factorin Eremosphaera viridis. Key words: Cytoplasmic pH, transient potential, K⁺–channels, Eremosphaera viridis     

The Relationship Between Growth and Oxygen Uptake in Hypoxic Rice Seedlings

Atwell, B. J. and Green way, H. 1987. The relationship betweengrowth and oxygen uptake in hypoxic rice seedlings.—J.exp. Bot. 38: 454–465. Rice seedlings (Oryza saliva L.) were grown in the dark forup to 4 d in solutions containing various concentrations ofO₂. Compared with seedlings grown at 0·250 mol O₂ m^–3,the dry weight of the growing seedling was 14% lower at 0·110mol O₂ m^–3 and 60% lower at 0 mol O₂ m^–3. Decreasesin fresh weight were similar but not identical to decreasesin dry weight, possibly because leaf growth was suppressed evenabove 0·110 mol O₂ m^–3. Oxygen deficiency inhibitedroot growth more severely than coleoptile growth. Coleoptiles from seedlings grown in aerated solution were exposedto an atmosphere of pure N₂ for 30 min. Anoxia caused a declinein ATP content and energy charge, suggestive of decreased oxidativephosphorylation. It is not clear whether the decline in oxidativephosphorylation was solely responsible for impaired growth inhypoxia. In seedlings growing at O₂ concentrations less than 0·110mol O₂ m^–3, significant amounts of ethanol were synthesized.The rate of O₂ uptake decreased markedly below 0·06 molO₂ m^–3; this was presumably near the external O₂ concentrationat which oxidative phosphorylation became limited by the supplyof O₂. The stage of development of the seedlings appeared toinfluence O₂ uptake, possibly through changes in conductanceof the tissue to O₂. Uncouplers were used to confirm that thecritical O₂ concentration was dependent on O₂ diffusion ratherthan enzyme kinetics. Impaired growth above 0·110 molO₂ m^–3 may have been due to a decreased activity of oxygenasesof relatively low affinity for O₂, which in turn altered cellmetabolism. Key words: Growth, oxygen uptake, rice seedlings, hypoxia     

Possible physiological mechanisms for production of hydrogen peroxide by the ichthyotoxic flagellate Heterosigma akashiwo

Blooms of the toxic red tide phytoplankton Heterosigma akashiwo(Raphidophyceae) are responsible for substantial losses withinthe aquaculture industry. The toxicological mechanisms of H.akashiwoblooms are complex and to date, heavily debated. One putativetype of ichthyotoxin includes the production of reactive oxygenspecies (ROS) that could alter gill structure and function,resulting in asphyxiation. In this study, we investigated thepotential of H.akashiwo to produce extracellular hydrogen peroxide,and have investigated which cellular processes are responsiblefor this production. Within all experiments, H.akashiwo producedsubstantial amounts of hydrogen peroxide (up to 7.6 pmol min^–110⁴ cells^–1), resulting in extracellular concentrationsof ~0.5 µmol l^–1 H₂O₂. Measured rates of hydrogenperoxide production were directly proportional to cell density,but at higher cell densities, accuracy of H₂O₂ detection wasreduced. Whereas light intensity did not alter H₂O₂ production,rates of production were stimulated when temperature was elevated.Hydrogen peroxide production was not only dependent on growthphase, but also was regulated by the availability of iron inthe medium. Reduction of total iron to 1 nmol l^–1 enhancedthe production of H₂O₂ relative to iron replete conditions (10µmol l^–1 iron). From this, we collectively concludethat production of extracellular H₂O₂ by H.akashiwo occurs througha metabolic pathway that is not directly linked to photosynthesis.     

Control of Passive Permeability in the Chara Plasmalemma

Conductance to K⁺ alters as a function of membrane potential(_m). Conductance to H⁺ (or OH^–) changes with externalpH (pH^o) This conductance change can be modulated by alteringcytoplasmic pH or external K⁺ concentration, both of which alsoalter _m. We suggest a role for H⁺ conductance in regulatingcytoplasmic pH above pH^o 7.0.