Halotolerant cyanobacterium Aphanothece halophytica contains an Na+-dependent F1F0-ATP synthase with a potential role in salt-stress tolerance

Aphanothece halophytica is a halotolerant alkaliphilic cyanobacterium that can grow in media of up to 3.0 m NaCl and pH 11. Here, we show that in addition to a typical H(+)-ATP synthase, Aphanothece halophytica contains a putative F(1)F(0)-type Na(+)-ATP synthase (ApNa(+)-ATPase) operon (ApNa(+)-atp). The operon consists of nine genes organized in the order of putative subunits β, ε, I, hypothetical protein, a, c, b, α, and γ. Homologous operons could also be found in some cyanobacteria such as Synechococcus sp. PCC 7002 and Acaryochloris marina MBIC11017. The ApNa(+)-atp operon was isolated from the A. halophytica genome and transferred into an Escherichia coli mutant DK8 (Δatp) deficient in ATP synthase. The inverted membrane vesicles of E. coli DK8 expressing ApNa(+)-ATPase exhibited Na(+)-dependent ATP hydrolysis activity, which was inhibited by monensin and tributyltin chloride, but not by the protonophore, carbonyl cyanide m-chlorophenyl hydrazone (CCCP). The Na(+) ion protected the inhibition of ApNa(+)-ATPase by N,N'-dicyclohexylcarbodiimide. The ATP synthesis activity was also observed using the Na(+)-loaded inverted membrane vesicles. Expression of the ApNa(+)-atp operon in the heterologous cyanobacterium Synechococcus sp. PCC 7942 showed its localization in the cytoplasmic membrane fractions and increased tolerance to salt stress. These results indicate that A. halophytica has additional Na(+)-dependent F(1)F(0)-ATPase in the cytoplasmic membrane playing a potential role in salt-stress tolerance.     

盐地碱蓬叶片液泡膜H^＋—ATPase B亚基的克隆及盐胁迫下表达分析

植物液泡膜H^ -ATPase在建立跨液泡膜质子梯度、促进液泡Na^ 区域化、提高植物耐盐性方面发挥着重要作用。本实验从盐生植物盐地碱蓬(Suaeda salsa L.)cDNA文库分离到碱蓬叶片液泡膜H^ -ATPase B亚基cDNA克隆。测序表明该基因长达1974bp,开放阅读框有1470bp编码489个氨基酸,含有一个保守的ATP结合位点,其蛋白分子量约为54．29kD。Northern及Western印迹表明盐地碱蓬液泡膜H^ -ATPase B亚基表达明显受NaCl胁迫诱导,并且在NaCl胁迫下,B亚基在转录及翻译水平上与液泡膜H^ -ATPase c亚基存在协同作用。盐胁迫下,盐地碱蓬液泡H^ -ATPase B亚基与c亚基的协同表达增加了液泡H^ -ATPase的数量,从而提高了液泡H^ -ATPase活性,为碱蓬叶片液泡Na^ 区域化提供了动力,最终提高了碱蓬植株的耐盐性。     

Yeast plasma membrane Ena1p ATPase alters alkali-cation homeostasis and confers increased salt tolerance in tobacco cultured cells

In plants, the plasma membrane Na(+)/H(+) antiporter is the only key enzyme that extrudes cytosolic Na(+) and contributes to salt tolerance. But in fungi, the plasma membrane Na(+)/H(+) antiporter and Na(+)-ATPase are known to be key enzymes for salt tolerance. Saccharomyces cerevisiae Ena1p ATPase encoded by the ENA1/PMR2A gene is primarily responsible for Na(+) and Li(+) efflux across the plasma membrane during salt stress and for K(+) efflux at high pH and high K(+). To test if the yeast ATPase would improve salt tolerance in plants, we expressed a triple hemagglutinin (HA)-tagged Ena1p (Ena1p-3HA) in cultured tobacco (Nicotiana tabacum L.) cv Bright Yellow 2 (BY2) cells. The Ena1p-3HA proteins were correctly localized to the plasma membrane of transgenic BY2 cells and conferred increased NaCl and LiCl tolerance to the cells. Under moderate salt stress conditions, the Ena1p-3HA-expressing BY2 clones accumulated lower levels of Na(+) and Li(+) than nonexpressing BY2 clones. Moreover, the Ena1p-3HA expressing BY2 clones accumulated lower levels of K(+) than nonexpressing cells under no-stress conditions. These results suggest that the yeast Ena1p can also function as an alkali-cation (Na(+), Li(+), and K(+)) ATPase and alter alkali-cation homeostasis in plant cells. We conclude that, even with K(+)-ATPase activity, Na(+)-ATPase activity of the yeast Ena1p confers increased salt tolerance to plant cells during salt stress.     

Role of the V-ATPase in regulation of the vacuolar fission-fusion equilibrium

Like numerous other eukaryotic organelles, the vacuole of the yeast Saccharomyces cerevisiae undergoes coordinated cycles of membrane fission and fusion in the course of the cell cycle and in adaptation to environmental conditions. Organelle fission and fusion processes must be balanced to ensure organelle integrity. Coordination of vacuole fission and fusion depends on the interactions of vacuolar SNARE proteins and the dynamin-like GTPase Vps1p. Here, we identify a novel factor that impinges on the fusion-fission equilibrium: the vacuolar H(+)-ATPase (V-ATPase) performs two distinct roles in vacuole fission and fusion. Fusion requires the physical presence of the membrane sector of the vacuolar H(+)-ATPase sector, but not its pump activity. Vacuole fission, in contrast, depends on proton translocation by the V-ATPase. Eliminating proton pumping by the V-ATPase either pharmacologically or by conditional or constitutive V-ATPase mutations blocked salt-induced vacuole fragmentation in vivo. In living cells, fission defects are epistatic to fusion defects. Therefore, mutants lacking the V-ATPase display large single vacuoles instead of multiple smaller vacuoles, the phenotype that is generally seen in mutants having defects only in vacuolar fusion. Its dual involvement in vacuole fission and fusion suggests the V-ATPase as a potential regulator of vacuolar morphology and membrane dynamics.     

Function of transport H+-ATPases in plant cell plasma and vacuolar membranes of maize under salt stress conditions and effect of adaptogenic preparations

Participations of electrogenic H+-pumps of plasma and vacuolar membranes represented by E1-E2 and V-type H+-ATPases in plant cell adaptation to salt stress conditions has been studied by determination of their transport activities. Experiments were carried out on corn seedlings exposed during 1 or 10 days at 0.1 M NaCl. Preparations Methyure and Ivine were used by seed soaking at 10(-7) M. Plasma and vacuolar membrane fractions were isolated from corn seedling roots. In variants without NaCl a hydrolytical activity of plasma membrane H+-ATPase was increased with seedling age and its transport one was changed insignificantly, wherease the response of the weaker vacuolar H+-ATPase was opposite. NaCl exposition decreased hydrolytical activities of both H+-ATPases and increased their transport ones. These results demonstrated amplification of H+-pumps function especially represented by vacuolar H+-ATPase. Both preparations, Methyure mainly, caused a further increase of transport activity which was more expressed in NaCl variants. Obtained results showed the important role of these H+-pumps in plant adaptation under salt stress conditions realized by energetical maintenance of the secondary active Na+/H+ -antiporters which remove Na+ from cytoplasm.     

Evidence for the involvement of vacuolar activity in metal(loid) tolerance: vacuolar-lacking and -defective mutants of Saccharomyces cerevisiae display higher sensitivity to chromate, tellurite and selenite

The responses of Saccharomyces cerevisiae towards the oxyanions tellurite, selenite and chromate were investigated in order to establish the involvement of the yeast vacuole in their detoxification. Three mutants of S. cerevisiae with defective vacuolar morphology and function were used; mutant JSR180D1 is devoid of any vacuolar-like structure while ScVatB and ScVatC are deficient in specific protein subunits of the vacuolar (V)-H -ATPase. All the mutant strains showed increased sensitivity to tellurite and chromate compared to their parental strains. Such sensitivity of the mutants was associated with increased accumu-lation of tellurium and chromium. These results indicate that accumulation of both tellurium and chromium occurred mainly in the cytosolic compartment of the cell, with detoxification influenced by the presence of a functionally-active vacuole which may play a role in compartmentation as well as regulation of the cytostolic compartment for optimal expression of a detoxification mechanism, e.g. reduction. In contrast, the vacuolar-lacking mutant, JSR180D1, and the defective V-H ATPase mutant ScVatB displayed lower selenium accu-mulation than their parental strains. Additionally, the mutant strain ScVatB displayed a higher tolerance to selenite than the parental strain. This result suggests that accumulation of selenium occurs mainly in the vacuolar compartment of the cell with tolerance depending on the ability of the cytosolic component to reduce selenite to elemental selenium, which might, in turn, be related to activity of the V-H -ATPase. These results are discussed in relation to vacuolar compartmentation and the significance of the vacuolar H -ATPase in cytosolic homeostasis of H both of which may affect the accumulation, reduction, and toler-ance to the tested metal(loids). © Rapid Science 1998     

Functional conservation between yeast and plant endosomal Na(+)/H(+) antiporters

Vacuolar compartmentation of Na(+) is an essential mechanism for salinity tolerance since it lowers cytosolic Na(+) levels while contributing to osmotic adjustment for cell turgor and expansion. The AtNHX1 protein of Arabidopsis thaliana substituted functionally for ScNHX1, the endosomal Na(+)/H(+) antiporter of yeast. Ion tolerance conferred by AtNHX1 and ScNHX1 correlated with ion uptake into an intracellular pool that was energetically dependent on the vacuolar (H(+))ATPase. AtNHX1 localized to vacuolar membrane fractions of yeast. Hence, both transporters share an evolutionarily conserved function in Na(+) compartmentation. AtNHX1 mRNA levels were upregulated by ABA and NaCl treatment in leaf but not in root tissue.     

The yeast model for batten disease: mutations in BTN1, BTN2, and HSP30 alter pH homeostasis

The BTN1 gene product of the yeast Saccharomyces cerevisiae is 39% identical and 59% similar to human CLN3, which is associated with the neurodegenerative disorder Batten disease. Furthermore, btn1-Delta strains have an elevated activity of the plasma membrane H(+)-ATPase due to an abnormally high vacuolar acidity during the early phase of growth. Previously, DNA microarray analysis revealed that btn1-Delta strains compensate for the altered plasma membrane H(+)-ATPase activity and vacuolar pH by elevating the expression of the two genes HSP30 and BTN2. We now show that deletion of either HSP30 or BTN2 in either BTN1(+) or btn1-Delta strains does not alter vacuolar pH but does lead to an increased activity of the vacuolar H(+)-ATPase. Deletion of BTN1, BTN2, or HSP30 does not alter cytosolic pH but diminishes pH buffering capacity and causes poor growth at low pH in a medium containing sorbic acid, a condition known to result in disturbed intracellular pH homeostasis. Btn2p was localized to the cytosol, suggesting a role in mediating pH homeostasis between the vacuole and plasma membrane H(+)-ATPase. Increased expression of HSP30 and BTN2 in btn1-Delta strains and diminished growth of btn1-Delta, hsp30-Delta, and btn2-Delta strains at low pH reinforce our view that altered pH homeostasis is the underlying cause of Batten disease.     

Activation and significance of vacuolar H+-ATPase in Saccharomyces cerevisiae adaptation and resistance to the herbicide 2,4-dichlorophenoxyacetic acid

The stimulation of the activity of the H(+)-ATPase present in the vacuolar membrane (V-ATPase) of Saccharomyces cerevisiae is here described in response to a moderate stress induced by 2,4-dichlorophenoxyacetic acid (2,4-D). This in vivo activation (up to 5-fold) took place essentially during the adaptation period, preceding cell division under herbicide stress, in coordination with a marked activation of plasma membrane H(+)-ATPase (PM-ATPase) (up to 30-fold) and the decrease of intracellular and vacuolar pH values, suggesting that activation may be triggered by acidification. Single deletion of VMA1 and genes encoding other V-ATPase subunits led to a more extended period of adaptation and to slower growth under 2,4-D stress. Results suggest that a functional V-ATPase is required to counteract, more rapidly and efficiently, the dissipation of the physiological H(+)-gradient across vacuolar membrane registered during 2,4-D adaptation.     

Na+/H+逆向转运蛋白和植物耐盐性

Na^ /H^ 逆向转运蛋白对植物耐盐起着重要作用,它利用质膜H^ -ATPase或液泡膜H^ -ATPase及PPiase泵H^ 产生的驱动力把Na^ 排出细胞或在液泡中区隔化以消除Na^ 的毒害。主要讨论植物中Na^ /H^ 逆向转运蛋白研究在分子水平的最新进展。     

Increased vacuolar Na(+)/H(+) exchange activity in Salicornia bigelovii Torr. in response to NaCl

Shoots of the halophyte Salicornia bigelovii are larger and more succulent when grown in highly saline environments. This increased growth and water uptake has been correlated with a large and specific cellular accumulation of sodium. In glycophytes, sensitivity to salt has been associated with an inability to remove sodium ions effectively from the cytoplasm in order to protect salt-sensitive metabolic processes. Therefore, in Salicornia bigelovii efficient vacuolar sequestration of sodium may be part of the mechanism underlying salt tolerance. The ability to compartmentalize sodium may result from a stimulation of the proton pumps that provide the driving force for increased sodium transport into the vacuole via a Na(+)/H(+) exchanger. In current studies, increased vacuolar pyrophosphatase activity (hydrolysis of inorganic pyrophosphate and proton translocation) and protein accumulation were observed in Salicornia bigelovii grown in high concentrations of NaCl. Based on sodium-induced dissipation of a pyrophosphate-dependent pH gradient in vacuolar membrane vesicles, a Na(+)/H(+) exchange activity was identified and characterized. This activity is sodium concentration-dependent, specific for sodium and lithium, sensitive to methyl-isobutyl amiloride, and independent of an electrical potential. Vacuolar Na(+)/H(+) exchange activity varied as a function of plant growth in salt. The affinity of the transporter for Na(+) is almost three times higher in plants grown in high levels of salt (K(m)=3.8 and 11.5 mM for plants grown in high and low salt, respectively) suggesting a role for exchange activity in the salt adaptation of Salicornia bigelovii.     

Roles of the VMA3 gene product, subunit c of the vacuolar membrane H(+)-ATPase on vacuolar acidification and protein transport. A study with VMA3-disrupted mutants of Saccharomyces cerevisiae

VMA3, a structure gene of the vacuolar membrane H(+)-ATPase subunit c of Saccharomyces cerevisiae, has been cloned and characterized. The VMA3 gene encodes a hydrophobic polypeptide with 160 amino acids as reported previously by Nelson and Nelson (Nelson, H., and Nelson, N. (1989) FEBS Lett. 247, 147-153). Peptide sequence analysis indicated that the VMA3 gene product lacks N-terminal methionine and does not have a cleavable signal sequence. To investigate functional and structural roles of the subunit c for vacuolar acidification and protein transport to the vacuole, haploid mutants with the disrupted VMA3 gene were constructed. The vma3 mutants can grow in nutrient-enriched medium, but they have completely lost the vacuolar membrane H(+)-ATPase activity and the ability of vacuolar acidification in vivo. The subunit c was found to be indispensable for the assembly of subunits a and b of the H(+)-ATPase complex. The disruption of the VMA3 gene causes yeast cells with considerable lesions in vacuolar biogenesis and protein transport to the vacuole and inhibits endocytosis of lucifer yellow CH completely.     

Intracellular Na and K distribution in Debaryomyces hansenii. Cloning and expression in Saccharomyces cerevisiae of DhNHX1

Debaryomyces hansenii is a salt-tolerant yeast that contains high amounts of internal Na(+). Debaryomyces hansenii kept more sodium than Saccharomyces cerevisiae in both the cytoplasm and vacuole when grown under a variety of NaCl concentrations. These results indicate a higher tolerance of Debaryomyces to high internal Na(+), and, in addition, suggest the existence of a transporter driving Na(+) into the vacuole. Moreover, a gene encoding a Na(+) (K(+))/H(+) antiporter from D. hansenii was cloned and sequenced. The gene, designated DhNHX1, exhibited significant homology with genes of the NHE/NHX family. DhNHX1 expression was induced neither at low pH nor by extracellular NaCl. A mutant of S. cerevisiae lacking its own Na(+) transporters (ena1-4Delta nha1 Delta nhx1 Delta), when transformed with DhNHX1, partially recovered cation tolerance as well as the ability to accumulate Na(+) and K(+) into the vacuole. Our analysis provides evidence that DhNhx1p transports Na(+) (and K(+)) into the vacuole and that it can play an important role in ion homeostasis and salt tolerance.     

Protective Effects of Glycinebetaine on Brassica chinensis Under Salt Stress (in English)

Brassica chinensis L. were foliarly applied with glycinebetaine (GB), as this species is unable to synthesis GB and sensitive to osmotic stress such as salt. The exogenous GB was easily absorbed and transported by the leaf of B. chinensis . Its application (0-20 mmol/L) enhanced the plant tolerance to salt stress. The treatment of 15 mmol/L GB significantly decreased the Na+ accumulation in leaf and root under NaCl stress. This difference in accumulating Na+ and K+ is caused by higher selectivity of root absorption. Furthermore, GB increased H+-ATPase activity of root plasma membrane evidently. This result strongly suggested that in root the decreased Na+ accumulation was caused by the GB accumulation that enhanced the extrusion of Na+ from the cell in some way through plasma membrane transporter, e.g. Na+/H+ antiport driven by H+-ATPase. The GB application was also found to stabilize the plasma membrane, to decrease the loss of chlorophyll, and to stimulate the osmosis induced proline response under salt stress.     

硅改善盐胁迫下库拉索芦荟生长和离子吸收与分布

Si2．0mmol／L处理明显缓解NaCl 100、200mmol／L胁迫120d对库拉索芦荟（Aloevera）生长的抑制作用。Si可显著降低NaCl胁迫下芦荟植株中的Na^＋和Cl^-含量,提高K^＋含量,从而显著降低K^＋／Na^＋,促进根对K^＋的选择性吸收（ASK,Na）和K^＋向地上部的选择性运输（TSK,Na）,以维持植株体内的离子稳态。根系和叶片横切面的X-射线能谱微区分析结果进一步证实了这一结果。Si改善盐胁迫下芦荟对K^＋的选择性吸收和运输的机制之一是通过显著提高盐胁迫下芦荟根细胞质膜H^＋ATPase、液泡膜H^＋-ATPase和液泡膜H^＋-PPase的活性。     

The action of adaptogenic preparations on vacuolar proton pumps activity in corn root cells under salt stress conditions

The function of two electrogenic H+ -pumps in plant vacuolar membrane (tonoplast) and their response to the salt stress conditions and adaptogenic preparations have been studied. Experiments were carried out on tonoplast fraction isolated from the roots of corn seedlings grown in water culture which were exposed at 7-day age in the presence of 0.1 M NaCl during 1 or 10 days. The role of every H+ -pump in potential generation was elucidated by assaying transport and hydrolytic activity of enzymes--V-type H+ -ATPase and H+ pyrophosphatase represented their mechanisms. It was found in the control variant that transport activity H+ -PPase exceeded considerably H+ -ATPase one in the tonoplast from 7-day seedlings. However this situation was changed in 18-day seedlings by H+ -ATPase transport activity increasing with age whereas its hydrolytic one was decreased. Both NaCI expositions caused the progressive decrease of transport and hydrolytic activity of H+ -PPase whereas H+ -ATPase responded to this factor by increasing transport activity, while its hydrolytic one fell. Bioactive preparations Methyure and Ivine (10(-7) M) used by seed soaking caused a further increase of H+ -ATPse transport activity especially in the presence of NaCl whereas H+ -PPase one was not changed. Methyure effect in these experiments was more pronounced. Obtained results demonstrated participation of tonoplast H+ -pumps in plant adaptation to NaCI which can be realized by amplification of Na+ -H(+) antiporter energization. An important role of vacuolar H+ -ATPase in growth and adaptation processes in plants has been proved.