Phloem loading of sucrose: involvement of membrane ATPase and proton transport

p-Chloromercuribenzenesulfonic acid markedly inhibited sucrose accumulation into sugar beet source leaves without inhibiting hexose accumulation. The site of inhibition is proposed to be the plasmalemma ATPase, since the ATPase-mediated H⁺ efflux was completely inhibited by p-chloromercuribenzenesulfonic acid under conditions where intracellular metabolism, as measured by photosynthesis and hexose accumulation, was unaffected. Fusicoccin, a potent activator of active H⁺/K⁺ exchange, stimulated both active sucrose accumulation and proton efflux in the sugar beet leaf tissue. These data provide strong evidence for the phloem loading of sucrose being coupled to a proton transport mechanism driven by a vectorial plasmalemma ATPase.     

Changes in the expression pattern of the plasma membrane H<Superscript>+</Superscript>-ATPase in developing<Emphasis Type="Italic"> Ricinus communis</Emphasis> cotyledons undergoing the sink/source transition

The plasma membrane (PM) H⁺-ATPase is thought to play a key role in generating the proton motive force used to drive the uptake and accumulation of solutes in plant cells. Changes in its expression pattern were studied in the Ricinus communis L. cotyledon as it changed from a sink to a source organ. Expression was monitored in 3-, 10- and 14-day-old cotyledons using an antibody to the maize PM H⁺-ATPase. The antibody labelled a 100-kDa protein in membrane fractions prepared from cotyledons and this protein occurred at higher levels in the PM-enriched fractions compared to those enriched in intracellular membranes. Immunostaining of tissue sections of 3-day-old Ricinus cotyledons (sinks) with this antibody demonstrated that the PM H⁺-ATPase was highly expressed in the lower epidermal cells and also in the vascular bundles, particularly the phloem. The high expression in the epidermis suggests that these cells may be important in the initial active uptake of solutes from the endosperm. A similar distribution was observed in the 10-day-old seedlings but, in addition, larger, more spherical cells (idioblasts) had developed in the lower and upper epidermal layers and these were also labelled. In 14-day-old seedlings the cotyledons are no longer reliant on nutrients from the endosperm (which has totally degraded) and they are functioning as source organs. This is reflected in a decrease in PM H⁺-ATPase expression in the lower epidermal cells, apart from idioblasts and stomatal guard cells. The latter were also observed in the upper epidermis. Expression remained high in the vascular bundles of 14-day-old seedlings with strong staining in the phloem.Abbreviation PM Plasma membrane     

Immunofluorescent Localization of Plasma Membrane H-ATPase in Barley Roots and Effects of K Nutrition

The plasma membrane H⁺-ATPase (PM-H⁺-ATPase) of barley (Hordeum vulgare L. cv Klondike) roots was assayed by cross-reaction on western blots and cryosections with an antibody against the PM-H⁺-ATPase from corn roots. Under conditions of reduced K availability, which have previously been shown to increase K influx by greater than 25-fold, there were only minor changes detected in PM-H⁺-ATPase levels. Antibody labeling of cryosections showed the relative distribution of PM-H⁺-ATPase among cell types in root tips and mature roots. Epidermal cells, both protoderm and mature root epidermis, including root hairs, had high levels of antibody binding. In mature roots, the stelar tissue showing the highest antibody binding was the companion cells of the phloem, followed by pericycle, xylem parenchyma, and endodermis.     

Proton Transport Activity of the Purified Vacuolar H-ATPase from Oats : Direct Stimulation by Cl

To determine whether the detergent-solubilized and purified vacuolar H⁺-ATPase from plants was active in H⁺ transport, we reconstituted the purified vacuolar ATPase from oat roots (Avena sativa var Lang). Triton-solubilized ATPase activity was purified by gel filtration and ion exchange chromatography. Incorporation of the vacuolar ATPase into liposomes formed from Escherichia coli phospholipids was accomplished by removing Triton X-100 with SM-2 Bio-beads. ATP hydrolysis activity of the reconstituted ATPase was stimulated twofold by gramicidin, suggesting that the enzyme was incorporated into sealed proteoliposomes. Acidification of K⁺-loaded proteoliposomes, monitored by the quenching of acridine orange fluorescence, was stimulated by valinomycin. Because the presence of K⁺ and valinomycin dissipates a transmembrane electrical potential, the results indicate that ATP-dependent H⁺ pumping was electrogenic. Both H⁺ pumping and ATP hydrolysis activity of reconstituted preparations were completely inhibited by <50 nanomolar bafilomycin A₁, a specific vacuolar type ATPase inhibitor. The reconstituted H⁺ pump was also inhibited by N,N′-dicyclohexylcarbodiimide or NO₃⁻ but not by azide or vanadate. Chloride stimulated both ATP hydrolysis by the purified ATPase and H⁺ pumping by the reconstituted ATPase in the presence of K⁺ and valinomycin. Hence, our results support the idea that the vacuolar H⁺-pumping ATPase from oat, unlike some animal vacuolar ATPases, could be regulated directly by cytoplasmic Cl⁻ concentration. The purified and reconstituted H⁺-ATPase was composed of 10 polypeptides of 70, 60, 44, 42, 36, 32, 29, 16, 13, and 12 kilodaltons. These results demonstrate conclusively that the purified vacuolar ATPase is a functional electrogenic H⁺ pump and that a set of 10 polypeptides is sufficient for coupled ATP hydrolysis and H⁺ translocation.     

Adaptation of plasma membrane H+ ATPase and H+ pump to P deficiency in rice roots

The plasma membrane (PM) H⁺ ATPase is involved in the plant response to nutrient deficiency. However, adaptation of this enzyme in monocotyledon plants to phosphorus (P) deficiency lacks direct evidence. In this study, we detected that P deficient roots of rice (Oryza Sativa L.) could acidify the rhizosphere. We further isolated the PM from rice roots and analyzed the activity of PM H⁺ ATPase. In vitro, P deficient rice roots showed about 30% higher activity of PM H⁺ ATPase than the P sufficient roots at assay of pH 6.0. The P deficiency resulted in a decrease of the substrate affinity value (K _m ) of PM H⁺ ATPase. The proton pumping activity of membrane vesicles from the P deficient roots was about 70% higher than that from P sufficient roots. Western blotting analysis indicated that higher activity of PM H⁺ ATPase in P deficient roots was related to a slightly increase of PM H⁺ ATPase protein abundance in comparison with that in P sufficient roots. Taken together, our results demonstrate that the P deficiency enhanced activities of both PM H⁺-ATPase and H⁺ pump, which contributed to the rhizosphere acidification in rice roots.     

Seasonal changes in plasma membrane H<Superscript>+</Superscript>-ATPase activity of <Emphasis Type="Italic">Vaccinium myrtillus</Emphasis> (L.) and <Emphasis Type="Italic">Pinus sylvestris</Emphasis> (L.)

Seasonal changes in vanadate sensitive plasma membrane H⁺-ATPase activity of bilberry (Vaccinium myrtillus L.) and Scots pine (Pinus sylvestris L.) were studied in a period from February to August in northern Finland. The plasma membrane isolation was performed by sucrose gradient centrifugation, and the H⁺-ATPase activity was assayed by spectrophotometrical determination of released inorganic phosphate. The studied species showed seasonal changes from high winter to low spring activity, indicating probable physiological changes between hardened and dehardened tissue. ATPase activity of bilberry peaked up at the beginning of the growth period, obviously due to active phloem loading of photosynthates.     

Proton transport by gastric membrane vesicles

A highly purified membrane fraction was derived from hog gastric mucosa by a combination of differential and density gradient centrifugation and free flow electrophoresis. This final fraction was 35-fold enriched with respect to cation activated ouabain-insensitive ATPase. Antibody against this fraction was shown to be bound to the luminal surface of the gastric glands. The addition of ATP to this fraction or the density gradient fraction resulted in H⁺ uptake into an osmotically sensitive space. The apparent K_m for ATP was 1.7 · 10^?4 M in the absence of a K⁺ gradient similar to that found for ATPase activity. The reaction is specific for ATP and requires cation in the sequence K⁺ > Rb⁺ > Cs⁺ > Na⁺ > Li⁺ and is inhibited by ATPase inhibitors such as N,N′-dicylclohexylcarbodiimide. Maximal H⁺ uptake occurs with an outward K⁺ gradient but the minimal apparent K_A is found in the absence of a K⁺ gradient. The pH optimum for H⁺ uptake is between 5.8 and 6.2 which corresponds to the pH range for phosphorylation of the enzyme, but is considerably less than the pH maximum of the K⁺ dependent dephosphorylation. In the presence of an inward K^? gradient, protonophores such as tetrachlorsalicylanilide only partially abolish the H⁺ gradient but valinomycin dissipates 75% of the gradient, and nigericin abolishes the gradient. The vesicles therefore have a low K⁺ conductance but a measurable H⁺ conductance, hence a K⁺ gradient can produce an H⁺ gradient in the presence of valinomycin. The uptake and spontaneous leak of H⁺ are temperature sensitive skin with a similar transition temperature. Ultraviolet irradiation inactivates ATPase and proton transport at the same rate, approximately at twice the rate of p-nitrophenylphosphatase inactivation. It is concluded that H⁺ uptake by these vesicles is probably due to a dimeric (H⁺ + K⁺)-ATPase and is probably non-electrogenic.     

Effect of potassium deficiency on the plasma membrane H+-ATPase of the wood ray parenchyma in poplar

The effect of K⁺ deficiency on the plasma membrane (PM) H⁺‐ATPase was studied in young stems of poplar plants (Populus tremula × tremuloides) grown with low or full‐strength K⁺ supply. Immunological assays using different antibodies were applied to test if K⁺ deficiency affects the amount of immunodetectable PM H⁺‐ATPases in the stem tissue. The monoclonal antibody clone 46 E5 B11 revealed an increased abundance of PM H⁺‐ATPases under conditions of low K⁺ supply, and immunolabelling experiments showed that this increase was restricted to vessel‐associated cells (VACs) of the wood ray parenchyma. Replacement of the monoclonal antibody by a polyclonal antibody against PM H⁺‐ATPase gave a specific immunoreactivity on blots as well as tissue sections too, but the labelling intensity showed no difference between plants with low or full‐strength K⁺ supply. Measurements of extracellular H⁺ concentrations using non‐invasive, H⁺‐selective microelectrodes revealed a lowering of the pH at the surface of VACs and an enhancement of net efflux of H⁺ in plants grown with low K⁺ supply. The present results indicate an up‐regulation of specific isoforms of the PM H⁺‐ATPase in VACs under K⁺‐deficient conditions and suggest a key role for these PM H⁺‐ATPases in unloading K⁺ from the xylem stream.     

H-ATPase Activity from Storage Tissue of Beta vulgaris: IV. N,N'-Dicyclohexylcarbodiimide Binding and Inhibition of the Plasma Membrane H-ATPase

The molecular weight and isoelectric point of the plasma membrane H⁺-ATPase from red beet storage tissue were determined using N,N′-dicyclohexylcarbodiimide (DCCD) and a H⁺-ATPase antibody. When plasma membrane vesicles were incubated with 20 micromolar [¹⁴C]-DCCD at 0°C, a single 97,000 dalton protein was visualized on a fluorograph of a sodium dodecyl sulfate polyacrylamide gel. A close correlation between [¹⁴C]DCCD labeling of the 97,000 dalton protein and the extent of ATPase inhibition over a range of DCCD concentration suggests that this 97,000 dalton protein is a component of the plasma membrane H⁺-ATPase. An antibody raised against the plasma membrane H⁺-ATPase of Neurospora crassa cross-reacted with the 97,000 dalton DCCD-binding protein, further supporting the identity of this protein. Immunoblots of two-dimensional gels of red beet plasma membrane vesicles indicated the isoelectric point of the H⁺-ATPase to be 6.5.     

Identification and biochemical characterization of the plasma-membrane H+-ATPase in guard cells of Vicia faba L.

The plasma-membrane H⁺-pump in guard cells generates the driving force for the rapid ion fluxes required for stomatal opening. Since our electrophysio-logical studies revealed a two fold higher pump-current density in guard cells than in mesophyll cells of Vicia faba L. we elucidated the biochemical properties of this proton-translocating ATPase in plasma-membrane vesicles isolated from both cell types. The capability of the H⁺ —ATPase to create an H⁺ gradient is maintained in plasma-membrane vesicles derived from purified guard cells via blender maceration, high-pressure homogenization and polymer separation. The H⁺-pumping activity of these vesicles coincides with the presence of two polypeptides of approx. 100 and 92 kDa which are recognized by a monoclonal antibody raised against the plasma-membrane H⁺-ATPase from Zea mays L. coleoptiles. Comparison of H⁺-pumping activities of isolated membranes revealed an approximately two fold higher activity in guard cells than in mesophyll cells with respect to the total membrane protein content. Furthermore, we demonstrated by western blotting that the difference in pump activities resulted from a higher abundance of the electroenzyme per unit membrane protein in guard-cell plasma membranes. We suggest that the high H⁺-pump capacity is necessary to enable guard cells to respond to sudden changes in the environment by a change in stomatal aperture.     

Proton pumping by tomato roots. Effect of Fe deficiency and hormones on the activity and distribution of plasma membrane H+-ATPase in rhizodermal cells

The immunocytochemical localization of the plasma membrane H⁺‐ATPase in epidermal cells of tomato roots was studied using a monoclonal antibody raised against purified maize P‐type H⁺‐ATPase. Plants subjected to iron starvation exhibited increased proton extrusion that was confined to the root elongation zones. Immunogold labelling of the H⁺‐ATPase on the plasma membrane was considerably higher in rhizodermal cells within zones with intense proton extrusion than in non‐acidifying areas of the roots. Transfer cells were formed in rhizodermal cells of Fe‐deficient plants. Quantitative determination of immunolabelling revealed that the density of PM H⁺‐ATPase in transfer cells was about twice that of ordinary epidermal cells. In transfer cells, H⁺‐ATPase was most abundant on the plasma membrane lining the labyrinthine invaginations of the peripheral cell wall. While the number of immunologically detectable ATPase molecules in transfer cells was not spatially correlated with proton extrusion activity, the frequency of transfer cells was considerably higher in acidifying root areas relative to non‐active segments. Split‐root experiments indicated that both the steady‐state level of plasma membrane H⁺‐ATPase and proton extrusion activity are systemically regulated, indicating inter‐organ regulation of rhizosphere acidification. Exogenous application of the auxin analog 2,4‐dichlorophenoxyacetic acid and the ethylene precursor 1‐aminocyclopropane‐1‐carboxlic acid caused the formation of transfer cells at a frequency similar to that observed in Fe‐deficient roots. However, the number of proton pumps was not affected by the hormone treatment, suggesting that both responses are regulated independently. It is concluded that transfer cells in the rhizodermis may be important but not crucial for rhizosphere acidification.     

Sodium or potassium efflux ATPase: A fungal, bryophyte, and protozoal ATPase

The K⁺ and Na⁺ concentrations in living cells are strictly regulated at almost constant concentrations, high for K⁺ and low for Na⁺. Because these concentrations correspond to influx-efflux steady states, K⁺ and Na⁺ effluxes and the transporters involved play a central role in the physiology of cells, especially in environments with high Na⁺ concentrations where a high Na⁺ influx may be the rule. In eukaryotic cells two P-type ATPases are crucial in these homeostatic processes, the Na,K-ATPase of animal cells and the H⁺-ATPase of fungi and plants. In fungi, a third P-type ATPase, the ENA ATPase, was discovered nineteen years ago. Although for many years it was considered to be exclusively a fungal enzyme, it is now known to be present in bryophytes and protozoa. Structurally, the ENA (from exitus natru: exit of sodium) ATPase is very similar to the sarco/endoplasmic reticulum Ca²⁺ (SERCA) ATPase, and it probably exchanges Na⁺ (or K⁺) for H⁺. The same exchange is mediated by Na⁺ (or K⁺)/H⁺ antiporters. However, in eukaryotic cells these antiporters are electroneutral and their function depends on a ΔpH across the plasma membrane. Therefore, the current notion is that the ENA ATPase is necessary at high external pH values, where the antiporters cannot mediate uphill Na⁺ efflux. This occurs in some fungal environments and at some points of protozoa parasitic cycles, which makes the ENA ATPase a possible target for controlling fungal and protozoan parasites. Another technological application of the ENA ATPase is the improvement of salt tolerance in flowering plants.     

Potassium Stimulation of Corn Root Plasmalemma ATPase : II. H-Pumping in Native and Reconstituted Vesicles with Purified ATPase

The stimulation by K⁺ of the initial rate of H⁺-pumping by ATPase was studied in native plasmalemma (Zea mays L. var Mona) vesicles and in reconstituted vesicles with enzyme purified on a glycerol gradient. In reconstituted vesicles, a very high H⁺-pumping rate (200,000% quenching per minute per milligram protein) was obtained with 9-amino-6-chloro-2-methoxyacridine provided that the pump was short-circuited by K⁺-valinomycin. A constant ionic strength was used to prevent indirect stimulation by the electrostatic effects of K⁺ salts. Indirect stimulation of H⁺-pumping by the short-circuiting effect of internal K⁺, could be abolished by using the permeant anions NO₃⁻ and Br⁻ in native, but not in reconstituted vesicles. In both materials, half-stimulation of the H⁺-pumping by K⁺ was observed at about 5 millimolar. The same stimulation was obtained when K⁺ was present only in the external solution or when it was present both outside and inside the vesicles. It was concluded that the stimulating effect of K⁺ on the H⁺-pumping evidenced in these experiments on both native and reconstituted vesicles was due to a direct effect of the cation on the cytoplasmic face of the ATPase. These results are discussed within the context of the hypothesis of an active K⁺ transport driven by the ATPase through a direct H⁺/K⁺ exchange mechanism.     

K stimulation of ATPase activity associated with the chloroplast inner envelope

Studies were conducted to characterize ATPase activity associated with purified chloroplast inner envelope preparations from spinach (Spinacea oleracea L.) plants. Comparison of free Mg²⁺ and Mg·ATP complex effects on ATPase activity revealed that any Mg²⁺ stimulation of activity was likely a function of the use of the Mg·ATP complex as a substrate by the enzyme; free Mg²⁺ may be inhibitory. In contrast, a marked (one- to twofold) stimulation of ATPase activity was noted in the presence of K⁺. This stimulation had a pH optimum of approximately pH 8.0, the same pH optimum found for enzyme activity in the absence of K⁺. K⁺ stimulation of enzyme activity did not follow simple Michaelis-Menton kinetics. Rather, K⁺ effects were consistent with a negative cooperativity-type binding of the cation to the enzyme, with the K_m increasing at increasing substrate. Of the total ATPase activity associated with the chloroplast inner envelope, the K⁺-stimulated component was most sensitive to the inhibitors oligomycin and vanadate. It was concluded that K⁺ effects on this chloroplast envelope ATPase were similar to this cation's effects on other transport ATPases (such as the plasmalemma H⁺-ATPase). Such ATPases are thought to be indirectly involved in active K⁺ uptake, which can be facilitated by ATPase-dependent generation of an electrical driving force. Thus, K⁺ effects on the chloroplast enzyme in vitro were found to be consistent with the hypothesized role of this envelope ATPase in facilitating active cation transport in vivo.     

Effect of Na(3)VO(4) on the P State of Nitella translucens

The capacity of sodium orthovanadate to inhibit the plasmalemma H⁺ ATPase of Nitella translucens internodal cells in vivo was tested. Here we show that 1 millimolar vanadate added externally depolarizes strongly and permanently the membrane potential, both in dark and light, to the Nernst potential for potassium consistent with pump inhibition by vanadate. From the results it is clear that the H⁺ ATPase is always active, under light or dark conditions, in contradiction with the widespread idea of pump inactivation by darkness. The changes in conductance for light, dark, and vanadate-induced conditions are analyzed. The effect of dark on membrane passive permeabilities and on the possibility that some plasmalemma channels could be regulated by a phosphorylation-dephosphorylation process is discussed.     

Sensitivity of tonoplast-bound adenosine-triphosphatase from hevea to inhibitors

The tonoplast-bound H⁺-translocating ATPase from Hevea latex was found to be insensitive to vanadate, diethylstilbestrol, and octylguanidine, which are specific inhibitors of the plasma membrane ATPase. The inhibitors of the mitochondrial ATPase, oligomycin and azide, and also rotenone and antimycin A, were all without effect. In contrast, trimethyltin chloride strongly inhibited the activity of Hevea tonoplast ATPase.

Among the different carbodiimides tested, which strongly inhibit the Hevea tonoplast ATPase, N,N′-dicyclohexylcarbodiimide was the most inhibitory. N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline was also an efficient inhibitor.

This unique inhibitor sensitivity of the Hevea tonoplast H⁺-translocating ATPase suggests that this enzyme differs in its mode of operation from all other known H⁺-translocating ATPases.

     

Distribution and structure of the vacuolar H ATPase in endosomes and lysosomes from LLC-PK1, cells

Vacuolar proton pumps acidify several intracellular membrane compartments in the endocytic pathway. We have examined the distribution of the vacuolar H⁺ ATPase in LLC-PK₁ cells and the structure of the biosynthetically labeled enzyme in membrane fractions enriched for endosomes or lysosomes. LLC-PK₁ cells were allowed to internalize cytochrome c-coated colloidal gold as a marker for endocytic compartments. Proton pumps were identified in these cells by staining the cells with a monoclonal antibody against the vacuolar pump detected with either immunogold or immunoperoxidase techniques. H⁺ ATPase labeling was seen on structures resembling endosomes and lysosomes, but not on Golgi or plasma membrane. To examine the structure of the H⁺ ATPase in these compartments, we labeled LLCPK₁ cells for 24 h with [³⁵S]methionine and used a Percoll gradient to obtain fractions enriched for endosomes or lysosomes. H⁺ ATPase immunoprecipitated from both fractions with monoclonal anti-H⁺ ATPase antibodies had labeled polypeptides of 70, 56, and 31 kDa. On two-dimensional gels, a comparison of the H⁺ ATPase from the endosomal and lysosomal fractions revealed that the 70-, 56-, and 31-kDa subunits were similar in both fractions. The results show that the vacuolar H⁺ ATPase in these cells is distributed primarily in endosomes and lysosomes and that the structure of the enzyme is similar in both compartments.     

Recent Molecular Approaches to the Physiology of the Plasma Membrane Proton Pump

During the last 3 years, genes for plasma membrane H⁺-ATPases from fungi, protozoa and plants have been isolated. Sequence similarities indicate that H⁺-ATPases constitute a separate group with the family of ATPases with phosphorylated intermediates. Yeast is a convenient model system to approach the physiology of H⁺-ATPases by recombinant DNA methodologies. A mutational analysis of yeast H⁺-ATPase has demonstrated that the enzyme is essential and rate-limiting for growth. Intracellular pH homeostasis is one of the crucial functions of H⁺-ATPase. In addition, there are indications for the direct energization of some essential transport system. The regulation of ATPase activity is probably mediated by an interaction between the active site and an inhibitory domain at the carboxyl-terminus.     

Elucidation of antimicrobial activity and mechanism of action by N-substituted carbazole derivatives

Compounds belonging to a carbazole series have been identified as potent fungal plasma membrane proton adenosine triphophatase (H⁺-ATPase) inhibitors with a broad spectrum of antifungal activity. The carbazole compounds inhibit the adenosine triphosphate (ATP) hydrolysis activity of the essential fungal H⁺-ATPase, thereby functionally inhibiting the extrusion of protons and extracellular acidification, processes that are responsible for maintaining high plasma membrane potential. The compound class binds to and inhibits the H⁺-ATPase within minutes, leading to fungal death after 1–3 h of compound exposure in vitro. The tested compounds are not selective for the fungal H⁺-ATPase, exhibiting an overlap of inhibitory activity with the mammalian protein family of P-type ATPases; the sarco(endo)plasmic reticulum calcium ATPase (Ca²⁺-ATPase) and the sodium potassium ATPase (Na⁺,K⁺-ATPase). The ion transport in the P-type ATPases is energized by the conversion of ATP to adenosine diphosphate (ADP) and phosphate and a general inhibitory mechanism mediated by the carbazole derivative could therefore be blocking of the active site. However, biochemical studies show that increased concentrations of ATP do not change the inhibitory activity of the carbazoles suggesting they act as allosteric inhibitors. Furthermore decreased levels of intracellular ATP would suggest that the compounds inhibit the H⁺-ATPase indirectly, but Candida albicans cells exposed to potent H⁺-ATPase-inhibitory carbazoles result in increased levels of intracellular ATP, indicating direct inhibition of H⁺-ATPase.