H+/PPi stoichiometry of a membrane‐bound pyrophosphatase of plant mitochondria

The H⁺/PP_i stoichiometry of the mitochondrial H⁺‐PP_iase from pea ( Pisum sativum L.) stem was determined by two kinetic approaches, and compared with the H⁺/substrate stoichiometries of the mitochondrial H⁺‐ATPase, and the vacuolar H⁺‐PP_iase and H⁺‐ATPase. Using sub‐mitochondrial particles or preparations enriched in vacuolar membranes, the rates of substrate‐dependent H⁺‐transport were evaluated: by a mathematical model, describing the time‐course of H⁺‐gradient (ΔpH) formation; or by determining the rate of H⁺‐leakage following H⁺‐pumping inhibition by EDTA at the steady‐state ΔpH. When the H⁺‐transport rates were divided by those of PP_i or ATP hydrolysis, measured under identical conditions, apparent stoichiometries of ca 2 were determined for the mitochondrial H⁺‐PP_iase and H⁺‐ATPase, and for the vacuolar H⁺‐ATPase. The stoichiometry of the vacuolar H⁺‐PP_iase was found to be ca 1. From these results, it is suggested that the mitochondrial H⁺‐PP_iase may, in theory, function as a primary H⁺‐pump poised towards synthesis of PP_i and, therefore, acting in parallel with the main H⁺‐ATPase.     

Effects of 2-iodobenzanilide on potassium uptake, H+ extrusion and K+-stimulated ATPase of corn roots

The carboxanilide systemic fungicide 2-iodobenzanilide (2-IB) after 2 h pretreatment at 0.25 m M inhibited K⁺ and SO₄^2- uptake by excised corn roots ( Zea mays L., cv. Dekalb 342) up to ca 70 and 40%, respectively. Proton extrusion from corn roots was also reduced by ca 50% after 1 h contact, and the microsomal K⁺-stimulated ATPase activity from corn roots and pea stems ( Pisum sativum L., cv. Alaska) inhibited by 50 and 72%, respectively. In contrast, the Mg²⁺-ATPase activities of microsomes and mitochondria at pH 6.0 and 8.7, respectively, were unaffected. After 2 h of preincubation with 0.25 m M 2-IB, O₂ consumption by corn roots and pea stems was inhibited by 12 and 18%, respectively. ATP content of corn roots was not altered by 2-IB treatment. Therefore, energy availability "in vivo" was unaffected and the primary effect on corn roots is suggested to be at the plasmalemma ATPase which forms the proton gradient.
With isolated pea stem mitochondria, 0.25 m M 2-IB inhibited O₂ consumption by ca 60% when NADH or malate plus pyruvate were added as substrates; when succinate was used O₂ consumption was unaffected. The mode of action on isolated mitochondria was different from that shown for carboxin and also formerly attributed to the whole class of carboxanilide fungicides.     

ATP-dependent H+-pumping of a low-density fraction of pea stem microsomes

A low-density fraction of pea ( Pisum sativum L. cv. Alaska) stem microsomes, obtained from a discontinuous sucrose gradient, possessed an H⁺-ATPase able to generate a proton gradient and an electrical potential. The proton pumping was insensitive to monovalent cations, to vanadate and oligomycin, required a permeant anion and was inhibited by nitrate, N, N'-dicyclohexylcarbodiimide and diethylstilbestrol. The H⁺-ATPase had a pH optimum around 6.0–6.5 and was saturable with respect to the substrate Tris-ATP (K_m≅ 0.4 m M ). Ca²⁺ (0.05–1 m M ) induced a dissipation of the ATP-generated δpH without affecting ATPase activity. At physiological concentrations (1–5 m M ), nitrate caused an initial slight increase of the ATP-generated proton gradient followed by a complete dissipation after 2–3 min. The dissipating effect was not caused by inhibition of ATPase activity, since ATP prevented the nitrate-induced collapse of δpH. On the other hand, ATPase activity, evaluated as release of P_i, was not inhibited by concentrations lower than 20 m M KNO₃. These results indicate that nitrate entered the vesicles in response to an electrical potential and then could exit in symport with protons, while Ca²⁺ entered in exchange for protons (antiport).     

Internode length and anatomical changes in Pisum genotypes crys and cryc in response to extended daylength and applied gibberellin A1

Dwarf pea (Pisum sativum L.) plants with genotypes cry^c and cry^s responded differently when an 8 h photoperiod (8 h daylight, 16 h dark) was extended to 24 h (8 h daylight, 16 h incandescent light). Genotype cry^c showed up to a 4-fold increase in internode length, sustained by increases in both cell length (particularly of epidermal cells) and cell number (particularly of cortical cells) while cry^s plants showed up to a 2-fold increase in internode length sustained mostly by an increase in cell number. Under an 8 h (daylight) photoperiod the two genotypes did not differ in their sensitivity to applied gibberellin A₁ (GA₁) and they showed a similar pattern of response. GA₁ significantly increased internode length, cell length and cell number in both genotypes. Incandescent light did not increase the size of the response to GA₁ except for cry^s plants at high dose rates of GA₁ (29–58 nmol). At saturating doses of GA₁ the two genotypes attained a similar peak internode length; incandescent light increased the peak by about 40%. GA₁ increased the rate of leaf appearance by up to 33% while incandescent light reduced the rate by 4–7%. The elongation response of the more mature internodes of cry^c plants to GA₁ or incandescent light was due primarily to an increase in cell length whereas increased cell number made a significant contribution in the case of internodes which were relatively immature at the time the stimulus was applied. The progressive increase in internode length of both genotypes during ontogeny was due primarily to an increase in cell number. In conclusion, alleles cry^c and cry^s (background le La) do not confer a difference in sensitivity to GA₁ and the increase in internode length in response to incandescent light is probably not the result of a real or perceived increase in GA₁ level. Allele cry^s may partially block a phytochrome mediated response to light and the key difference between genotypes cry^s and cry^c may lie in the greater elongation (extensibility?) of cry^c epidermal cells in incandescent light.     

Interaction of 4-chloroindole-3-acetic acid and gibberellins in early pea fruit development

In pea, normal pod (pericarp) growth requires the presence of seeds; and in the absence of seeds, gibberellins (GAs) and/or auxins can stimulate pericarp growth. To further characterize the function of naturally occurring pea GAs and the auxin, 4-chloroindole-3-acetic acid (4-Cl-IAA), on pea fruit development, profiles of the biological activities of GA3, GA1, and 4-Cl-IAA on pericarp growth were determined separately and in combination on pollinated deseeded ovaries (split-pericarp assay) and nonpollinated ovaries. Nonpollinated ovaries (pericarps) responded differently to exogenous GAs and 4-Cl-IAA than pollinated deseeded pericarps. In nonpollinated pericarps, both GA3 and 4-Cl-IAA stimulated pericarp growth, but GA3 was significantly more active in stimulating all measured parameters of pericarp growth than 4-Cl-IAA. 4-Cl-IAA, GA1, and GA3 were observed to stimulate pericarp growth similarly in pollinated deseeded pericarps. In addition, the synergistic effect of simultaneous application of 4-Cl-IAA and GAs on pollinated deseeded pericarp growth supports the hypothesis that GAs and 4-Cl-IAA are involved in the growth and development of pollinated ovaries.     

The putative Na+/H+ antiporter (NapA) of Enterococcus hirae is homologous to the putative K+/H+ antiporter (KefC) of Escherichia coli

Two monovalent ion porters, the putative Na+/H+ antiporter (NapA) of Enterococcus hirae and the putative K+/H+ antiporter (KefC) of Escherichia coli, are similar in sequence throughout their hydrophobic domains. These two proteins, which comprise a novel family of transporters unrelated to the previously characterized Na+/H+ exchangers of E. coli (NhaA and NhaB) are proposed to function by essentially the same mechanism.     

Carbon and nitrogen partitioning in young nodulated pea (wild type and nitrate reductase-deficient mutant) plants exposed to NH4NO3

Carbon and nitrogen partitioning was examined in a wild-type and a nitrate reductase-deficient mutant (A317) of Pisum sativum L. (ev. Juneau), effectively inoculated with two strains of Rhizobium leguminosarum (128C23 and 128C54) and grown hydroponically in medium without nitrogen for 21 days, followed by a further 7 days in medium without and with 5 mM NH₄NO₃. In wild-type symbioses the application of NH₄NO₃ significantly reduced nodule growth, nitrogenase (EC 1.7.99.2) activity, nodule carbohydrates (soluble sugars and starch) and allocation of [¹⁴C]-labelled (NO₃⁻, NH₄⁺, amino acids) in roots. In nodules, there was a decline in amino acids together with an increase in inorganic nitrogen concentration. In contrast, symbioses involving A317 exhibited no change in nitrogenase activity or nodule carbohydrates, and the concentrations of all nitrogenous solutes measured (including asparagine) in roots and nodules were enhanced. Photosynthate allocation to the nodule was reduced in the 128C23 symbiosis. Nitrite accumulation was not detected in any case. These data cannot be wholly explained by either the carbohydrate deprivation hypothesis or the nitrite hypothesis for the inhibition of symbiotic nitrogen fixation by combined nitrogen. Our result with A317 also provided evidence against the hypothesis that NO₃⁻ and NH₄⁺ or its assimilation products exert a direct effect on nitrogenase activity. It is concluded that more than one legume host and Rhizobium strain must be studied before generalizations about Rhizobium /legume interactions are made.     

The role of electrogenic xylem pumps in K+ absorption from the zylem of Vigna unguiculata: the effects of auxin and fusicoccin

Abstract We tested the hypothesis that electrogenic ion pumps, working at the parenchyma symplast/xylem interface of pea hypocotyls, provide the driving force for K⁺ uptake from the xylem. Solutions of known composition were perfused through a hypocotyl segment. The K⁺ activity of the solution flowing out of the xylem (K⁺_out) increased (i.e. K⁺ uptake decreased) when aerobic respiration was inhibited by lack of O₂, and this was preceded by a decrease in V_px (electrical potential difference between parenchyma symplast and xylem). Perfusion with auxin (1AA) and fusicoccin (FC) stimulated the electrogenic activity of the ‘xylem pumps’ (111 and 205% respectively) and stimulated uptake of K ⁺ from the xylem (with 71% and 29% respectively). The close correlation between xylem pump activity and K⁺ uptake corroborated the aforementioned hypothesis. Interestingly, inhibition of pump activity by anoxia was incomplete in the presence of FC. It is thought that FC increases the affinity of the ATP-requiring xylem pump for ATP, thus ensuring that ATP production during fermentation is sufficient to fuel the pump in the absence of O₂.     

Promoting effect of fusicoccin on Na+ efflux in barley roots: evidence for a Na+−H+ antiport

Abstract. The effect of fusicoccin (FC) on the K⁺stimulated Na⁺ efflux in root cells of Na⁺ loaded barley roots was studied. FC (0.02 mM) stimulated Na⁺ efflux in the presence of K⁺ and its effect was synergistic with that of K⁺, in a similar way as its effect on proton extrusion. Decreasing the pH of the elution medium promoted Na⁺ efflux and partially replaced the effect of FC. As FC is known to increase the electrochemical proton gradient at the plasmalemma level, these results are consistent with the hypothesis that Na⁺ is extruded in exchange for H⁺. A further support to this view came from the finding that Na⁺ efflux was also promoted by a lipophilic cation, tributylbenzylammonium (TBBA ⁺), which stimulates H ⁺ extrusion and is generally accepted not to enter the cells by means of the same carrier as K ⁺.     

Effect of K+ and H+ stress and role of Ca2+ in the regulation of intracellular K+ concentration in mung bean roots

The effects of external K⁺, H⁺ and Ca2⁺ concentrations on the intracellular K+ concentration, [K⁺]i, and the K⁺-ATPase activity in 2-day-old mung bean roots [ Vigna mungo (L.) Hepper] were investigated. [K⁺]i, in mung bean roots was markedly decreased by external K⁺ or H⁺ stress and did not recover the initial value even after the stress was removed. This decrease in [K⁺]i, gradually disappeared with the addition of (Ca2⁺. Ca2⁺ may offset the harmful effects of ion stress. Ca2⁺ seems to have two effects on K+ transport; control of K⁺ permeability and activation of K⁺ uptake, although K⁺-ATPase activity was inhibited by Ca2⁺ concentrations higher than 10–4 M. We suggest that Ca2⁺ activates K⁺ uptake indirectly through the acidification of the cytoplasm.     

The use of reconstitution and inhibitor/ion interaction assays to distinguish between Ca2+/H+and Cd2+/H+ antiporter activities of oat and tobacco tonoplast vesicles

Tonoplast, ion antiport activities are critical to ion homeostasis and sequestration in plants. The biochemical properties of these activities, and the enzymes that catalyse them, are little characterized. Here we applied biochemical approaches to study some characteristics and to distinguish between Ca²⁺/H⁺ and Cd²⁺/H⁺ antiporter activities of tonoplast vesicles from non‐transformed, wild‐type plants. Solubilization and reconstitution of oat‐seedling (Avena sativa L.) root tonoplast vesicles resulted in about a 6‐fold loss of protein, about a 6‐fold enhancement of Cd²⁺/H⁺ antiport specific activity (at 10 µM Cd²⁺), and almost complete loss of Ca²⁺/H⁺ antiport activity. Similar results were found for vesicles from mature tobacco (Nicotiana tabacum) roots. Cd²⁺ concentration‐dependent proton efflux was similar and linear with both oat vesicles and proteoliposomes. In contrast, Ca²⁺ concentration‐dependent proton efflux of oat vesicles was easily observed while that with proteoliposomes was minimal and non‐linear. Cd²⁺ pre‐treatment of oat vesicles reduced verapamil inhibition of Cd²⁺/H⁺ activity and verapamil binding to vesicles, while Ca²⁺ pre‐treatment was much less protective of Ca^2+/H⁺ activity and verapamil binding. Results show the usefulness of reconstitution, and also inhibitor/ion interaction assays for distinguishing between transporter activities in vitro, but they do not resolve the question of whether there are separate enzymes for Cd²⁺/H⁺ and Ca²⁺/H⁺. Our observation that solubilization and reconstitution have similar effects on both Cd²⁺/H⁺ and Ca²⁺/H⁺ activities of root tonoplast vesicles from immature oat and mature tobacco roots suggests that the transporters involved are similar in young and mature roots, and in roots of different species.     

Role of K+ in leaf growth: K+ uptake is required for light-stimulated H+ efflux but not solute accumulation

The stimulation of dicotyledonous leaf growth by light depends on increased H⁺ efflux, to acidify and loosen the cell walls, and is enhanced by K⁺ uptake. The role of K⁺ is generally considered to be osmotic for turgor maintenance. In coleoptiles, auxin‐induced cell elongation and wall acidification depend on K⁺ uptake through tetraethylammonium (TEA)‐sensitive channels (Claussen et al., Planta 201, 227–234, 1997), and auxin stimulates the expression of inward‐rectifying K⁺ channels ( Philippar et al. 1999) . The role of K⁺ in growing, leaf mesophyll cells has been investigated in the present study by measuring the consequences of blocking K⁺ uptake on several growth‐related processes, including solute accumulation, apoplast acidification, and membrane polarization. The results show that light‐stimulated growth and wall acidification of young tobacco leaves is dependent on K⁺ uptake. Light‐stimulated growth is enhanced three‐fold over dark levels with increasing external K⁺, and this effect is blocked by the K⁺ channel blockers, TEA, Ba⁺⁺ and Cs⁺. Incubation in 10 mm TEA reduced light‐stimulated growth and K⁺ uptake by 85%, and completely inhibited light‐stimulated wall acidification and membrane polarization. Although K⁺ uptake is significantly reduced in the presence of TEA, solute accumulation is increased. We suggest that the primary role of K⁺ in light‐stimulated leaf growth is to provide electrical counterbalance to H⁺ efflux, rather than to contribute to solute accumulation and turgor maintenance.     

Tonoplast energization: Two H+ pumps, one membrane

The vacuolar membrane (tonoplast) of plant cells contains two functionally and physically distinct phosphohydrolases, which catalyse electrogenic H⁺ -translocation: An ATPase (tp-ATPase; EC 3.6.1.3) and an inorganic pyrophosphatase (tp-PPase; 3.6.1.1). Neither enzyme belongs to the F₀F₁– or E₁E₂-categories of primary cation pumps, but instead belong to a third and fourth category of enzyme, respectively. Research priorities for the tp-ATPase are studies directed at understanding the roles of the 70 and 60 kDa subunits in catalysis and regulation; the involvement of the 16 kDa subunit in transmembrane H⁺ conduction; and investigations of F₀F₁- like structure/function partitioning. In the longer term, comparisons of sequence homology between the N,N'- dicyclohexylcarbodiimide -binding (16 kDa) proteins from different sources may enable elucidation of the evolutionary relationship of the tp-ATPase with other putative third-category H⁺– translocases. The tp-PPase, on the other hand, represents an exciting but largely unexplored biochemical entity, which necessitates a reconsideration of accepted views concerning the involvement of inorganic pyrophosphate (PPi) in transmembrane energy conservation. Just why the tonoplast should be endowed with two H⁺-translocases is a problem that can only be approached once consideration is given to the paramount question of H⁺/PPi stoichiometry. Once the stoichiometry is known, it should be possible to establish the physiological poise of the tp-PPase, and hence to speculate on its role in the metabolism of plant cells.     

Evidence for a Na+ / H+ electrogenic antiporter in an alkaliphilic cyanobacterium Synechocystis

Abstract An alkaliphilic cyanobacterium characterized as a Synechocystis species was purified from a soil sample taken from a village in Java, Indonesia, by its preferential growth at elevated pH; it grew optimally at pH 9.5. Phosphorus nuclear magnetic resonance studies showed that the organism can maintain a ΔpH of over 2 pH units at an external pH of 10. It was observed that the viability of the organism in the dark was dependent on sodium ions. Evidence from experiments in which the extrusion of Na⁺ was measured from cells subjected to an alkali shock suggests that the organism possesses a Na⁺ / H⁺ electrogenic antiporter which is used for the maintenance of pH homeostasis.     

The dynamics of H+ efflux from the trap lobes of Dionaea muscipula Ellis (Venus's flytrap)

Abstract. H⁺ efflux from the trap lobes of Dionaea muscipula Ellis (Venus's flytrap) was measured in vitro. FC, IAA, and 2,4-D markedly increase the rate of H⁺ efflux within minutes of their addition to the incubation medium whereas ABA and DES cause the rate to decrease. Consequently, the H⁺ efflux mechanism of Dionaea is considered to be similar to the H⁺ extrusion pumps of other higher plants in this respect. However, the H⁺ extrusion mechanism of Dionaea may be unusual in that long-term exposure of the trap lobes to known secretion elicitors— bactopeptone, NH₄⁺, Na ⁺, urea, thiourea, glycine or xanthine—also causes a large increase in the steady-state rate of H⁺ efflux from the trap lobes. Since the observed H⁺ effluxes primarily correspond to the adaxial surface of the trap lobes and show similar time- and secretion elicitor-dependencies to the responses seen in situ, it appears that the H⁺ effluxes measured in vitro bear a direct relationship to those observed in the intact, actively secreting plant. Three of the secretion elicitors that were tested— K⁺, NH₄⁺, and urea—have rapid effects on the rate of H⁺ extrusion in addition to their long-term effects. K⁺ and NH₄⁺ cause a rapid acceleration of H⁺ efflux whereas urea causes a rapid deceleration or, at high external concentrations, reversal of the net flux. The effect of K⁺ is inferred to result from K⁺ -H⁺ exchange between the tissue and bathing medium. Studies with structural analogues of NH₄⁺ and urea and inhibitors of the assimilation of reduced nitrogen suggest that the effects of NH₄⁺ and urea result from the pH-perturbing consequences of their metabolism subsequent to their absorption. These effects are considered to be auxiliary to the elicitation of secretion. It is proposed that H⁺ efflux from the trap lobes is mediated by a K⁺-H⁺ exchange mechanism, the activity of which is modified by long-term exposure to secretion elicitors and/or short-term exposure to factors which alter the availability of endogenous H⁺ ions.     

Internode length in Pisum. Estimation of GA1 levels in genotypes Le, le and led

The levels of GA₁, 3-epiGA₁ and GA₈ in genotypes Le, le and le^d of Pisum sativum L. were determined by gas chromatography-selected ion monitoring (GC-SIM) after feeds of [³H, ¹³C]-GA₂₀ to each genotype. The levels of endogenous and [¹³C]-labelled metabolites were determined by reverse isotope dilution with unlabelled GA₁, 3-epiGA₁ and GA₈. The results demonstrate a quantitative relationship between the level of GA₁ and the extent of elongation both on a per plant and a per g fresh weight basis. These results are consistent with previous findings in peas and other species possessing a predominant early 13-hydroxylation pathway for GA biosynthesis.
The levels of 3-epiGA₁ also decreased in the genotypic sequence Le, le, le^d although not as rapidly as for the level of GA₁. This may suggest that the alleles at the le locus also influence the formation of 3-epiGA₁.     

Cation-stimulated H+ efflux by intact roots of barley

Abstract. Rates of proton extrusion and potassium (⁸⁶Rb) influx by intact roots of barley ( Hordeum vulgare cvs . Fergus, Conquest and Betzes) plants were simultaneously measured in short-term (15min) experiments. The nature and extent of apparent coupling between these ion fluxes was explored by manipulating conditions of temperature, pH and cation composition and concentration during flux determinations. In addition, the influence of salt status upon these fluxes was examined. At low K⁺ concentrations (0.01 to 1 mol m⁻³), H⁺ efflux and K⁺ influx were strongly correlated in both low- and high-K⁺ roots, although K⁺: H⁺ exchange stoichiometries were almost consistently greater than 2:1. At higher concentrations (1 to 5 mol m⁻³), H⁺ efflux was either reduced or remained unchanged while K⁺ influxes increased. In the presence of Na₂SO₄, rates of H⁺ extrusion demonstrated similar cation dependence, although below 10 mol m⁻³ Na₂SO₄, H⁺ fluxes were generally 50% lower than in equivalent concentrations of K₂SO₄. These observations are considered in the context of current hypotheses regarding the mechanisms of k⁺/H⁺ exchange.     

Buffering capacity and H+ membrane conductance of Gram-negative bacteria

Abstract Buffering capacity and membrane H⁺ conductance were examined in seven Gram-negative species: Aquaspirillum serpens, Pseudomonas aeruginosa, Alcaligenes faecalis, Escherichia coli, Salmonella typhimurium, Proteus mirabilis and Aeromonas hydrophila . All strains of Enterobacteriaceae studied here showed a decrease in both parameters as the external pH increased, over the pH range studied. The other four species presented an increase in buffering capacity and membrane conductance to protons as the external pH increased from 5.5 to 7.0.     

Na+/H+ exchange subtype 1 inhibition during extracellular acidification and hypoxia in glioma cells

Lactacidosis is a common feature of ischaemic brain tissue, but its role in ischaemic neuropathology is still not fully understood. Na(+)/H(+) exchange, a mechanism involved in the regulation of intracellular pH (pH(i)), is activated by low pH(i). The role of Na(+)/H(+) exchange subtype 1 was investigated during extracellular acidification and subsequent pH recovery in the absence and presence of (4-isopropyl-3-methylsulphonyl-benzoyl)-guanidine methanesulfonate (HOE642, Cariporid), a new selective and powerful inhibitor of the Na(+)/H(+) exchanger subtype 1 (NHE-1). It was compared for normoxia and hypoxia in two glioma cell lines (C6 and F98). pH(i) was monitored by fluorescence spectroscopy using the intracellularly trapped pH-sensitive dye 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF). Alterations in glial cell metabolism were characterized using high-resolution (1)H, (13)C and (31)P NMR spectroscopy of perchloric acid extracts. NHE-1 contributed to glial pH regulation, especially at pathologically low pH(i) values. NHE-1 inhibition with HOE642 during acidification caused exacerbated metabolic disorders which were prolonged during extracellular pH recovery. However, NHE-1 inhibition during hypoxia protected the energy state of glial cells.