Involvement of Plasma Membrane H+-ATPase in Adaption of Rice to Ammonium Nutrient

The preference of paddy rice for NH4+ rather than NO3ˉ is associated with its tolerance to low pH since a rhizosphere acidification occurs during NH4+ absorption.However,the adaptation of rice root to low pH has not been fully elucidated.The plasma membrane H+-ATPase is a universal electronic H+ pump,which uses ATP as energy source to pump H+ across the plasma membranes into the apoplast.The key function of this enzyme is to keep pH homeostasis of plant cells and generate a H+ electrochemical gradient,thereby providing the driving force for the active influx and efflux of ions and metabolites across the plasma membrane.This study investigated the acclimation of plasma membrane H+-ATPase of rice root to low pH.This mechanism might be partly responsible for the preference of rice plants to NH4+ nutrition.

Effects of salinity on activities of H^+-ATPase, H^+-PPase and membrane lipid composition in plasma membrane and tonoplast vesicles isolated from soybean(Glycine max L.) seedlings

The effects of NaCl stress on the H +-ATPase, H +-PPase activity and lipid composition of plasma membrane(PM) and tonoplast(TP) vesicles isolated from roots and leaves of two soybean cultivars(Glycine max L.) differing in salt tolerance(Wenfeng7, salt-tolerant; Union, salt-sensitive) were investigated. When Wenfeng7 was treated with 0.3%(W/V) NaCl for 3 d, the H +-ATPase activities in PM and TP from roots and leaves exhibited a reduction and an enhancement, respectively. The H +-PPase activity in TP from roots also increased. Similar effects were not observed in roots of Union. In addition, the increases of phospholipid content and ratios of phospholipid to galactolipid in PM and TP from roots and leaves of Wenfeng7 may also change membrane permeability and hence affect salt tolerance.

质膜H^(+)-ATPase基因对铝胁迫下水稻硝态氮吸收的 调控作用

为探讨细胞质膜ATP酶(PM H^(+)-ATPase)基因对铝胁迫下水稻(Oryza sativa L.)吸收硝态氮(NO_(3)^(-)-N)的调控,本试验以2个水稻品种峰1A和峰1A优5为研究对象,以无铝处理幼苗为对照,分析铝胁迫下水稻根尖PM H^(+)-ATPase活性、H^(+)-泵活性、H^(+)通量、PM H^(+)-ATPase基因家族(OsA1~OsA10)表达水平、PM H^(+)-ATPase和14-3-3蛋白的互作水平以及NO_(3)^(-)-N吸收量。结果表明,与对照相比,铝胁迫下2个水稻品种根尖PM H^(+)-ATPase活性、H^(+)-泵活性和根尖H^(+)通量下降,PM H^(+)-ATPase和14-3-3蛋白的互作水平下降。铝胁迫抑制了OsA1、OsA5、OsA7和OsA8基因的表达,其中OsA7的表达水平显著下调,铝胁迫下峰1A和峰1A优5的OsA7表达量仅为对照组的21%和39%。NO_(3)^(-)-N吸收量较对照下降,分别为对照的81%和85%。综上,PM H^(+)-ATPase基因的表达水平影响水稻对NO_(3)^(-)-N的吸收能力,OsA1、OsA5、OsA7和OsA8在铝胁迫下水稻吸收NO_(3)^(-)-N过程中起关键的调控作用。本研究结果可为增强酸铝条件下水稻吸收NO_(3)^(-)-N的能力,促进水稻生长及增产提供理论依据。

Involvement of Plasma Membrane Ca^(2+)/H^+ Antiporter in Cd^(2+) Tolerance

Cation exchangers （CAXs） belong to the cation/Ca2＋exchanger superfamily which have been extensively investigated in plant tonoplasts over the last decade. Recently, the roles of CAXs involved in heavy metal accumulation and tolerance in plants have been studied for phytoremediation and food security. In this mini review, we summarize the roles of the Ca2＋/H＋ antiporter in Ca2＋ signal transduction, maintaining ion homeostasis and sequestering heavy metals into the vacuole. Moreover, we present a possible role of the plasma membrane Ca2＋/H＋ antiporter in heavy metal detoxification.

水稻根系细胞膜H^+-ATPase对铵硝营养的响应差异

用两相法分离了铵态氮(NH4+-N)和硝态氮(NO3--N)营养下水稻苗期根系的细胞膜,并测定了细胞膜上H+-ATPase的水解活性,以期阐明水稻根系细胞质膜上H+-ATPase对不同氮素形态的响应差异。两相法分离的细胞膜纯度达到95%以上。在离体条件下,NH4+-N营养的水稻根系细胞膜H+-ATPase的水解活性和H+-ATPase的Km和Vmax均显著高于NO3--N营养。NH4+-N营养的水稻根系细胞膜H+-ATPase最适pH值为6.0,而NO3--N营养的在pH6.2左右。Westernblot结果表明,NH4+-N营养的水稻根系细胞膜H+-ATPase浓度显著高于NO3--N营养的H+-ATPase。说明NH4+-N营养的水稻根系细胞膜H+-ATPase活性高是因为单位细胞膜上的H+-ATPase分子数量大于NO3--N营养,并且在NH4+-N营养的水稻根系细胞膜上可能存在着与NO3--N营养不同的H+-ATPase的同工酶。因此,NH4+-N营养的水稻根系细胞膜H+-ATPase活性高很可能是水稻根系对铵态氮营养的一种适应机制。

水稻根系细胞膜H^+-ATPase对缺磷的反应

用两相法分离了供磷(+P)和缺磷(-P)营养下水稻苗期根系的细胞膜,并测定了细胞膜上H+-ATPase的水解活性,以期阐明水稻根系细胞质膜上H+-ATPase对不同缺磷的反应机制。结果表明,缺磷的水稻根系细胞膜H+-ATPase的水解活性和H+-ATPase的Vmax,Km均低于正常供磷的植物;缺磷的水稻根系细胞膜H+-ATPase最佳pH值为6.0,而正常供磷植物的为pH 6.4左右;Western Blot结果说明,缺磷水稻根系细胞膜H+-ATPase酶浓度与正常供磷植物相似。本试验结果还说明,缺磷水稻根系细胞膜H+-ATPase活性低的原因并不是因为其单位细胞膜上的H+-ATPase酶分子数量小于正常供磷的植物,而是缺磷水稻根系细胞膜上H+-ATPase的同工酶的组成与供磷植物相比发生了变化。这很可能是缺磷胁迫下水稻根系细胞膜H+-ATPase的一种适应机制。

水稻叶片质膜H^+-ATPase对酸雨胁迫的适应机制

采用水培法研究酸雨胁迫对水稻叶片质膜H+-ATPase活性的影响,结果表明,高强度酸雨(pH 2.5和pH 3.0组)胁迫下,pH 2.5组质膜H+-ATPase活性显著受抑,胞内pH降低,POD活性受抑,pH3.0组质膜H+-ATPase活性上升,胞内pH降低,POD活性升高,质膜透性和MDA含量均增加,Fv/Fm和叶鲜重降低;低强度酸雨(3.0<pH≤5.5)胁迫下,质膜H+-ATPase活性应激升高,虽胞内pH降低,POD活性升高,质膜未遭明显损伤,对生长的抑制程度明显低于高强度酸雨胁迫.可见,酸雨胁迫下,质膜功能蛋白H+-ATPase能在一定范围内调节胞内pH,进而缓解大量H+引发的活性氧积累,减轻质膜损伤,从而增强作物对酸雨胁迫的抗逆性和适应性.

铵、硝营养对水稻叶细胞膜H^+-ATPase和质子泵活性的影响

用两相法分离铵态氮(NH4+-N)和硝态氮(NO3--N)培养的水稻苗期叶细胞膜,并测定了细胞膜H+-ATPase水解活性和质子泵活性,以期阐明铵、硝营养对水稻叶细胞膜H+-ATPase的影响。结果表明,叶细胞膜H+-ATPase活性最佳pH值均为6.2。NO3--N培养的水稻叶细胞膜H+-ATPase的水解活性、Vmax和Km均显著高于NH4+-N培养的水稻叶;Western Blot分析结果看出,NO3--N培养的水稻叶细胞膜H+-ATPase酶浓度也高于NH4+-N培养的水稻叶,说明NO3--N培养的水稻叶中单位细胞膜上的H+-ATPase酶分子数量大于NH4+-N培养的水稻叶,这与细胞膜上H+-ATPase蛋白的表达量升高有关。此外,NO3--N培养的水稻叶质子泵初速度和膜囊体内外H+浓度梯度均高于NH4+-N培养。由于NO3-的跨膜运输是与细胞膜上H+-ATPase紧密联系的主动运输过程,NO3--N培养的水稻叶片细胞膜H+-ATPase活性和质子泵活性高可能与水稻叶细胞吸收大量NO3-有关。

水稻质膜H^+-ATPase基因对拟南芥遗传转化及其抗盐性分析

RT-PCR扩增得水稻质膜H+-ATPase全长cDNA(PM-H+-ATPase),构建了植物表达载体获得质粒pBI121-PM-H+-ATPase,农杆菌介导、真空渗入法转化PM-H+-ATPase基因入拟南芥,得35株T1代卡那抗性植株。抗性植株PCR分析表明,抗性植株整合了目的基因。Northern杂交分析进一步表明T3代转基因拟南芥表达了目的基因。抗盐(NaHCO3和NaCl)性分析表明:转基因植株的耐盐能力明显高于野生型;盐碱胁迫下转基因植株开花优先于野生型植株。

中度干旱胁迫下内生真菌印度梨形孢对旱稻根系细胞膜H^(+)-ATPase的影响

【目的】研究中度干旱胁迫下,内生真菌印度梨形孢(Piriformospora indica)对旱稻根系细胞膜H^(+)-ATPase的影响,解析印度梨形孢提高旱稻耐旱性的分子生理机制。【方法】将无菌旱稻幼苗及带有GFP标签的印度梨形孢菌饼(P. indica-GFP)接种于备好的PNM培养基中,于26℃/22℃、14 h/10 h (光/暗)培养两周,采用激光共聚焦显微镜观察水稻根部定殖的印度梨形孢菌。采用盆栽试验方法,分别种植定殖与未定殖印度梨形孢的旱稻(Oraza sativa,中旱3)幼苗,保持土壤中度干旱胁迫,培养幼苗2周后,取根系样品,测定根系细胞膜H^(+)-ATPase及生长情况,生长素IAA含量,以及H^(+)-ATPase相关基因的表达。【结果】通过旱稻根系转录组分析,发现相比于未接种印度梨形孢的旱稻,接种印度梨形孢旱稻根系生长素相关基因表达显著上调。同时,接种印度梨形孢旱稻根系生长素含量、H^(+)分泌、细胞膜H^(+)-ATPase活性及根毛长度显著高于未接种印度梨形孢旱稻。中度干旱胁迫下,与未接种印度梨形孢旱稻相比,接种印度梨形孢旱稻根系细胞膜H^(+)-ATPase相关基因表达显著上调。此外,中度干旱胁迫下,接种印度梨形孢旱稻地上部干重、根系干重、总根长及根毛长度都显著高于未接种印度梨形孢旱稻。【结论】在中度干旱胁迫下,印度梨形孢通过提高旱稻根系生长素含量,调控根系细胞膜H^(+)-ATPase活性,进而促进根毛发育。

A critical review on natural compounds interacting with the plant plasma membrane H^(+)-ATPase and their potential as biologicals in agriculture

The plant plasma membrane(PM)H^(+)-ATPase is an essential enzyme controlling plant growth and development.It is an important factor in response to abiotic and biotic stresses and is subject to tight regulation.We are in demand for new sustainable natural growth regulators and as a key enzyme for regulation of transport into the plant cell the PM H^(+)-ATPase is a potential target for these.In this review,we have evaluated the known non-protein natural compounds with regulatory effects on the PM H^(+)-ATPase,focusing on their mechanism of action and their potential as biologicals/growth regulators in plant production of future sustainable agriculture.

Ca^(2+)-dependent TaCCD1 cooperates with TaSAUR215 to enhance plasma membrane H^(+)-ATPase activity and alkali stress tolerance by inhibiting PP2C-mediated dephosphorylation of TaHA2 in wheat

Alkali stress is a major constraint for crop production in many regions of saline-alkali land.However,little is known about the mechanisms through which wheat responds to alkali stress.In this study,we identified a calcium ion-binding protein from wheat,TaCCD1,which is critical for regulating the plasma membrane(PM)H^(+)-ATPase-mediated alkali stress response.PM H+-ATPase activity is closely related to alkali tolerance in the wheat variety Shanrong 4(SR4).We found that two D-clade type 2C protein phosphatases,TaPP2C.D1 and TaPP2C.D8(TaPP2C.D1/8),negatively modulate alkali stress tolerance by dephosphorylating the penultimate threonine residue(Thr926)of TaHA2 and thereby inhibiting PM H+-ATPase activity.Alkali stress induces the expression of TaCCD1 in SR4,and TaCCD1 interacts with TaSAUR215,an early auxin-responsive protein.These responses are both dependent on calcium signaling triggered by alkali stress.TaCCD1 enhances the inhibitory effect of TaSAUR215 on TaPP2C.D1/8 activity,thereby promoting the activity of the PM H^(+)-ATPase TaHA2 and alkali stress tolerance in wheat.Functional and genetic analyses verified the effects of these genes in response to alkali stress,indicating that TaPP2C.D1/8 function downstream of TaSAUR215 and TaCCD1.Collectively,this study uncovers a new signaling pathway that regulates wheat responses to alkali stress,in which Ca^(2+)-dependent TaCCD1 cooperates with TaSAUR215 to enhance PM H+-ATPase activity and alkali stress tolerance by inhibiting TaPP2C.D1/8-mediated dephosphorylation of PM H+-ATPase TaHA2 in wheat.

低温、高pH胁迫对水稻幼苗根系质膜、液泡膜ATP酶活性的影响

以耐冷性不同的两个水稻品种为材料 ,比较研究了幼苗根系质膜、液泡膜ATP酶对低温 (8℃ )及高pH (8.0 )胁迫的反应。结果表明 :水稻根细胞质膜和液泡膜上均存在Ca2 + ATP酶 ,但活性远低于H+ ATP酶。耐冷品种武育粳 3号经低温 (8℃ )处理 2d ,根系质膜和液泡膜H+ ATP酶、Ca2 + ATP酶活性均明显升高 ,至冷处理 12d ,H+ ATP酶、Ca2 + ATP酶活性有所下降 ,但仍与对照相近 ;而冷敏感品种汕优6 3经低温 (8℃ )处理 2d ,根系质膜H+ ATP酶活性略有升高 ,而质膜Ca2 + ATP酶以及液泡膜H+ ATP酶、Ca2 + ATP酶活性已明显下降 ;至冷处理 12d ,4种酶活性均明显低于对照。高 pH胁迫使质膜和液泡膜H+ ATP酶活性下降 ,而使Ca2 + ATP酶活性上升。高 pH胁迫会加剧低温冷害。结果表明 ,耐冷品种质膜。

根际pH对水稻细胞膜质子泵基因表达的影响

通过水培试验研究了不同根际pH对水稻(日本晴)细胞膜质子泵基因表达的影响。以栽培在pH 5.5的营养液中的水稻作为对照,然后分别转移到pH 3.5和pH 7.5的营养液中培养。研究发现,质子泵基因OsPMA1、OsPMA2、OsPMA3、OsPMA7在根系和叶片中均有表达;当营养液pH为3.5或7.5时,上述质子泵基因的表达总体上均比对照(pH5.5)降低。但植物地上部的质子泵表达不受根际pH的影响。而且,pH越低,水稻生物量与体内的氮含量越低。其可能的原因是,水稻在pH骤然降为3.5的营养液中没有及时适应高浓度的H+胁迫,导致根系细胞膜质子泵受抑制,进而影响水稻对养分的吸收。而pH 7.5与植物细胞质pH相当,质子泵无需过量表达即可用于养分吸收。说明根际pH直接影响到根系细胞膜质子泵在转录水平上的表达,并间接影响根系对养分的吸收和植物的生长。

耐低钾水稻的根质膜ATPase和H^+分泌特性

对耐低钾和不耐低钾的水稻（ＯｒｙｚａｓａｔｉｖａＬ．）“威优４９”和“远诱１号”的根原生质膜ＡＴＰａｓｅ性质的研究表明，这两种水稻的质膜ＡＴＰａｓｅ活性的最适ｐＨ均为６０，均在底物ＡＴＰ浓度为３ｍｍｏｌ／Ｌ时达到最大反应速度，Ｋｍ值均在０．８５左右。Ｋ＋对这两种水稻的质膜ＡＴＰａｓｅ活性均具有促进作用。当介质中［Ｋｍ］≤５０ｍｍｏｌ／Ｌ时随［Ｋ＋］的增大，对耐低钾品种根质膜ＡＴＰａｓｅ活性的促进作用明显大于不耐低钾品种；当介质［Ｋ＋］在１００～２００ｍｍｏｌ／Ｌ之间时，Ｋ＋对两种水稻品种质膜ＡＴＰａｓｅ活性的刺激效应的差别减小。这两个水稻品种的基础Ｈ＋分泌没有明显差别，但钾刺激的Ｈ＋分泌存在差异，Ｋ＋对耐低钾品种Ｈ＋分泌的刺激效应大于不耐低钾品种。抑制剂实验表明在耐低钾和不耐低钾的水稻品种中，Ｋ＋刺激的根质膜ＡＴＰａｓｅ活性，Ｋ＋刺激的Ｈ＋分泌和Ｋ＋吸收之间存在着紧密的联系。对Ｋ＋刺激的质膜ＡＴＰａｓｅ活性和Ｈ＋分泌的抑制会减少根对Ｋ＋的吸收量。推测耐低钾水稻的质膜ＡＴＰａｓｅ和Ｈ＋分泌对Ｋ＋更为敏感，特别是在低浓度Ｋ＋存在时，可能是耐低钾水稻更能利用低浓度Ｋ＋、在低钾环境中能更好生长的一个原因。

水稻根质膜Ca^(2+)/H^+反向转运体的存在及其特性

由Ca2+/H+反向转运体蛋白的特异多肽制备的抗体,通过免疫印迹显示水稻根质膜上存在分子量为44.5kD的蛋白。同位素闪烁记数法检测水稻根质膜上45Ca2+转运活性显示存在依赖于跨膜质子梯度的Ca2+/H+反向转运体,Mn2+可部分地抑制其转运活性。动力学分析表明,OsCAX2的Vmax=34.72nmol/(min·mg),Km=3.83μmol/L,其最适pH为7.2。

铝胁迫下质膜H^+-ATPase对水稻硝态氮吸收的影响

为了研究铝胁迫下水稻质膜H^+-ATPase对硝态氮吸收影响,以‘滇优35号’(粳稻)为试验材料,采用溶液培养法研究50μmol·L^(-1) Al^(3+)胁迫下添加质膜H^+-ATPase的激活剂壳梭孢素(FC)和抑制剂腺苷-5’-单磷酸(AMP)对质膜H^+-ATPase水解活性和H^+-泵活性,质膜H^+-ATPase和14-3-3蛋白的相互作用对水稻NO_3^--N吸收的影响。结果表明,AMP处理使铝胁迫下水稻质膜H^+-ATPase水解活性、H^+-泵的活性,质膜H^+-ATPase和14-3-3蛋白的相互作用下降,H_2O_2和MDA含量增加,从而导致水稻NO_3^--N吸收降低。FC处理可使铝胁迫下水稻质膜H^+-ATPase水解活性、H^+-泵的活性以及质膜H^+-ATPase和14-3-3蛋白的相互作用增加,H_2O_2和MDA含量下降,从而使水稻NO_3^--N吸收增加。这些研究结果表明铝胁迫通过影响质膜H^+-ATPase与14-3-3蛋白互作来影响质膜H^+-ATPase水解活性和氢泵活性以及H_2O_2和MDA含量,进而影响对硝态氮的吸收。

模拟酸雨对水稻叶片质膜H^+-ATPase活性与矿质元素含量的影响

采用水培法研究模拟酸雨(p H=5.0、3.5、2.5)对水稻叶片质膜H+-ATPase活性与矿质元素含量的影响.结果显示:与对照(CK)相比,酸雨处理5 d(胁迫期)后,p H=5.0组质膜H+-ATPase活性与活化能、K+、Ca2+、Mg2+含量均无显著变化,仅细胞渗透势下降.p H=3.5酸雨导致细胞渗透势、K+含量下降,质膜H+-ATPase活性、H+-ATPase活化能、Ca2+含量明显上升,Mg2+含量无显著变化.p H=2.5组H+-ATPase活性、细胞渗透势和K+、Mg2+含量明显下降,H+-ATPase活化能和Ca2+含量上升,表明矿质元素含量不仅受H+-ATPase活性的调控,还与酸雨强度和离子价态有关.经5 d恢复(恢复期)后,p H=5.0组各指标均恢复到CK水平,p H=3.5组除细胞渗透势外均恢复至CK水平,p H=2.5处理组各指标虽未达到CK水平,但较胁迫期有所恢复.表明K+、Ca2+、Mg2+含量受H+-ATPase活性的调节,且恢复效果受酸雨强度影响.

镧对酸雨胁迫下水稻叶片质膜H^+-ATPase活性的影响

为了明晰稀土提高植物抗酸性的内在机制,采用水培法研究了镧(La,15 mg·L^(-1))对酸雨(AR,pH=3.5、2.5)胁迫下水稻叶片质膜H+-ATPase活性的影响.结果显示:与CK相比,pH=3.5 AR组水稻相对生长速率减小,质膜H+-ATPase活性升高,胞内H+增多,CAT活性升高,H_2O_2和MDA含量升高,质膜脂肪酸不饱和度指数(IUFA)降低.La+pH 3.5 AR组水稻各项指标优于pH=3.5 AR组,表明La促使AR下质膜H+-ATPase活性升高,将胞内过多的H+泵出,减缓AR伤害,维持水稻正常生长.另外,La能增强CAT活性,清除过多的H_2O_2,减轻膜脂过氧化程度,使质膜IUFA升高,膜的流动性增强,提高质膜H+-ATPase活性.pH=2.5 AR组水稻相对生长速率、质膜H+-ATPase活性、CAT活性与质膜IUFA均降低,而胞内H+、H_2O_2和MDA含量升高.La+pH 2.5 AR组与pH=2.5 AR组水稻各指标均无明显差异,La对pH=3.5 AR组的缓解效果优于pH=2.5 AR组.综上可知,La对AR下质膜H+-ATPase活性的调节增强了植物耐酸性,这与La能维持AR下较好的质膜环境有关.同时,La的调控效果受AR强度限制.

模拟酸雨对水稻叶片质膜H^+-ATPase活性与胞内Ca^(2+)浓度的影响

在水培条件下研究了模拟酸雨(pH=2.5～5.5)对水稻叶片胞内Ca2+浓度和质膜H+-ATPase活性的影响.结果表明:与对照组(CK)相比,酸雨处理5 d(胁迫期)后,pH=5.5和5.0处理组的水稻叶片胞内H+浓度、质膜H+-ATPase活性、胞内Ca2+浓度、质膜Ca2+-ATPase活性无显著变化;pH=4.0和3.5处理组各指标显著升高,且H+-ATPase活性随Ca2+浓度升高而上升;pH=3.0和2.5处理组各指标显著降低,此时胞内Ca2+缺失,对H+-ATPase活性的调节作用受到限制.经正常条件培养5 d(恢复期)后,pH=4.0和3.5处理组各指标均恢复至CK的处理水平,表明H+-ATPase活性受到Ca2+调控已恢复到正常;pH=3.0和2.5处理组的Ca2+浓度高于CK及胁迫期,H+-ATPase活性低于CK但高于胁迫期,表明H+-ATPase活性受Ca2+调控得到部分恢复.因此,酸雨胁迫下胞内Ca2+对质膜H+-ATPase活性有一定调节作用,且受酸雨强度的制约.