胰蛋白酶处理对质膜Ｈ^＋—ATPase钒酸钠抑制效应的影响

采用经蔗糖密度梯度法纯化的大豆（Ｇlycine max L.)下胚轴质膜微囊为材料,分析了胰蛋白酶处理对质膜Ｈ^ -ATPase钒酸钠抑制效应的影响。实验结果显示,温和胰蛋白酶处理显提高Ｈ^ -ATPase的ＡＴＰ水解活力。并且发现酶切处理降低了钒酸钠对ATPase的抑制效应,当钒酸钠浓度为２mmol/L时,ATPase活力仅被抑制５３．４９％,而未经酶切的对照组则被抑制６４．１３％,ＡＴＰ水解动力学分析表明,胰蛋白酶酶切处理既不影响ＡＴＰ水解的Ｋm值也不影响钒酸钠的抑制类型,酶切前后的Ｋm值都等于０．３４mmol/L,并且都属于反竞争抑制。以上结果显示胰蛋白酶酶切处理可能改变了磷酸酶结构域的结构而影响了钒酸钠的抑制效应,暗示Ｃ－末端调节着磷酸酶结构域的结构和功能。     

溶血卵磷脂对大豆下胚轴质膜H^＋—ATPase ATP和对—硝基苯磷酸水解活性的影响

研究了溶血卵磷脂 (lysophosphatidylcholine,lyso PC)对大豆 (Glycinemax (L .)Merr.)下胚轴质膜H _ATPaseATP和对_硝基苯磷酸 (ρ_nitrophenylphosphate ,PNPP)水解的影响。结果显示 ,lyso_PC可以刺激ATP水解活力 ,当lyso_PC浓度在 0～ 0 .0 3%范围时 ,ATP水解活力明显提高 ,lyso_PC浓度高于 0 .0 3%后增加缓慢 ;当lyso_PC浓度为0 .0 3%时 ,ATP水解活力提高 80 .5 %。动力学分析表明 ,lyso_PC处理可以使ATP水解的Vmax从 0 .46 μmolPi·mg-1protein·min-1升高到 0 .87μmolPi·mg-1protein·min-1;使Km 从 0 .88mmol/L升高到 1.15mmol/L。最适pH也从 6 .5变为 7.0。实验还发现lyso_PC可以促进羟胺对ATP水解的抑制作用 ,lyso_PC处理后ATP水解被羟胺 (2 0 0mmol/L)抑制 84.4% ,而未经lyso_PC处理的对照组则仅被抑制 74.4%。然而 ,lyso_PC处理不影响PNPP水解活力和钒酸钠抑制效应。以上结果表明 ,质膜H _ATPase的激酶结构域可能是其C末端自抑制结构域的作用位点或调节区域     

盐生杜氏藻质膜ATPase及其对高渗震动的反应

用水溶性多聚物 ( dextran T5 0 0 PEG 335 0 )两相法制备盐生杜氏藻细胞质膜 ,经检测质膜纯度较高 ,原位膜约占 78%。质膜 ATPase的动力学常数 Km 和 Vmax分别为0 5 8mmol L和 4 3 5 9μmol Pi ( mg protein· h) ;最适 p H值是 7 5。质膜 ATPase的活性随Mg Cl2 和 Ca Cl2 浓度的升高而增加 ,但较高浓度的 Mg Cl2 和 Ca Cl2 有轻微的抑制作用 ;KCl促进质膜 ATPase的活性 ,在 1 0 0 mmol L时达到最大 ,高于 1 0 0 mmol L时抑制效应显著。钒酸钠、DES、DCCD和 NEM明显地抑制质膜 ATPase的活性 ;而 Na N3、Na NO3、Na Mo O4和KCN对质膜 ATPase的活性影响不大。高渗震动刺激了质膜 ATPase的活性。     

钒酸钠对叶绿体ATP酶和光合功能的影响

钒酸钠是一种对红色链胞霉(nurospora)质膜—ATP酶有抑制作用的药物。Bowman近来发现氧化态五价钒离子对有产电质子泵(Electrogenic proton pump)作用的质膜—H~ -ATP酶也有专一的抑制效应,但它不影响线粒体的ATP酶活力。至于它对叶     

不同生境两种生态型芦苇叶片质膜H~ -ATPase的比较(英文)

利用两相法纯化质膜微囊,研究了分布于西北沙漠地区的两种生态型芦苇(Phragmites communis Trin.)(水生芦苇和重度盐化草甸芦苇,分别简称为水芦和盐芦)叶片质膜H -ATPase的部分性质。结果显示,与水芦相比,盐芦质膜H -ATPase的ATP水解活性升高,Km值由1.27 mmol/L降至0.30 mmol/L,但Vmax没有显著差异。并且该酶活性对温度的敏感性和pH谱型也发生了变化。以对硝基苯磷酸盐为底物,低浓度时盐芦的质膜H -ATPase水解活性高于水芦,高浓度时则没有差异。Km在水芦和盐芦中分别为3.61 mmol/L和1.92 mmol/L,但Vmax在两种生态型中没有差异。钒酸盐抑制实验表明,两种生态型的质膜H -ATPase磷酸-酶区的催化性质不同。胰酶对质膜H -ATPase活性的活化谱型也存在差异,说明该酶C末端的结构或性质发生了变化。此外,与水芦相比,盐芦质膜H -ATPase的质子泵活性及与水解活性的耦联程度也升高了。以上结果说明,当芦苇从水生环境向盐渍环境过渡时,质膜H -ATPase的催化性质发生了变化,这些变化可能是由酶结构的修饰和不同的同工酶谱引起的。H -ATPase催化性质的变化可能是对盐渍生境的适应性反应。     

草甘膦对叶绿体能量转换的影响

除草剂草甘膦抑制植物叶绿体光合磷酸化活力,促进希尔反应活力,表现出明显的解偶联效应。它对叶绿体膜上腺三磷酶(ATPase)活力也起抑制效应,说明ATP合成被抑制不是由ATP酶活力变化所引起。这种解偶联现象主要是因光下质子转移受到抑制,在较低浓度的草甘膦影响下,先抑制质醌转移的质子进入膜内腔,浓度增加到20 mM,对水释放质子也有抑制。所以草甘膦对叶绿体能量转换的影响主要反映在质子转移被抑制,引起磷酸化活力受抑制。     

钒酸钠、叠氮钠对小麦根细胞K~+吸收和质膜K~+-Mg~(2+)-ATPase的作用

Neurospora细胞膜质子泵(H~+-ATPase)专一性抑制剂钒酸钠,抑制小麦离体根K~+的吸收与H~+分泌,并抑制小麦根细胞膜-K~+-Mg~(2+)-ATPase活力。它对K~+吸收的抑制效应,可能是抑制质膜K~+-Mg~(2+)-ATPase活力的结果。而且在起抑制作用的时间上有明显地不同,表明钒酸钠对K~+、H~+在细胞膜中的通道影响不同。叠氮钠解链小麦根的呼吸,降低根细胞的ATP水平,但从实验开始就完全抑制小麦根K~+的吸收,对质膜K~+-Mg~(2+)-ATP-ase的活力没有影响。可能叠氮钠只阻止“载体”对K~+接受的过程。应用~86R_b+示踪的K~+吸收试验表明,钒酸钠对小麦根K~+吸收的抑制%,不为增加外部溶液K~+浓度而减低。增加底物ATP浓度,也不能减低钒酸钠对质膜-ATPase的抑制%。钒酸钠的抑制作用是非竞争性抑制。~3H-亮氨酸渗入试验表明钒酸钠对“载体”的合成没有干扰作用。VO_4~(3-)离子明显促进小麦根的呼吸,并提高根细胞的ATP水平,这种ATP水平的提高,可能是质膜-ATPase受到抑制,主动运输过程减弱的结果。     

不同生境两种生态型芦苇叶片质膜H+-ATPase的比较

利用两相法化纯化质膜微囊,研究了分布西北沙地区的两种生态型芦苇(Phragmites communis trih.)水生芦苇和重度盐化草甸芦苇,分别简称为水芒和盐芦)叶片质膜H - ATPase的部分性质.结果显示,与水芦相比,盐芦质膜H -ATPase的ATP水解活性升高,Km值由1.27mmol\l降至Vmax没有显著差异.并且该酶活性对温度的敏感必玫PH谱型也发生了变化.以对硝基苯磷酸盐为底物,低浓度时盐芦的的质膜H -ATPase水解活性有差异.钡酸盐抑制实验表明,两种生态的质膜H -ATPase磷酸-酶区的催化性质不同.胰酶对质膜H -ATPase活性的活化谱型也存在差异,说明该酶C末端的结构或性质发生了变化.此外,与水芦相比,盐芦质膜H -ATPase的质子泵活性的耦联程度也升高了.以上结果明,当芦苇从水生环境向盐渍环境过渡时,质膜H -ATPase的催化性质发生了变化,这些变化可能是由酶结构的修饰和不同的同工酬酶谱引起的.H -ATPase催化性质的变化可能是对盐渍生境的适应性反应.     

水分胁迫下钙螯合剂与CPZ抑制剂对棉花根和下胚轴两种ATPase的效应(简报)

水分胁迫下棉花根和下胚轴质膜（PM）H－ATPase和Ca2－ATPase活力、表观Km值以及Vmax降低。－0．3MPa和-1．1MPa胁迫下质膜AT－Pase活力随时间延长分别呈“V”字形变化和下降趋势。钙螯合剂（EGTA）、CaM抑制剂（CPZ）对棉花根和下胚轴质膜ATPase活性有明显的抑制效应,抑制程度为-1．1MPa大于-0．3MPa大于对照。     

赤小豆抑制剂对胰蛋白酶不可逆抑制作用的动力学探讨

本文从中药赤小豆(Phaseolus Calcaratus,Roxb)中分离出一种胰蛋白酶抑制剂。通过一系列酶促反应动力学的研究表明,赤小豆抑制剂对胰蛋白酶有较强的不可逆竞争性抑制作用。其Km和ki值分别为1.43×10~(-3)mmol/L和2.4×10~(-6)mmol/L。     

Changes in Inhibitory Effect of Vanadate on the Plasma Membrane H+-ATPase Under Trypsin Treatment

The changes in inhibitory effect of vanadate on the plasma membrane H + ATPase were studied with mild trypsin treatment using plasma membrane vesicles purified from soybean （Glycine max L.）hypocotyles by sucrose gradient centrifugation. Results showed that under mild trypsin treatment the ATPase ATP hydrolysis activity was increased significantly. It was also found that the inhibitory effect of vandate was reduced after proteolysis. In the presence of 2 mmol/L vanadate, the ATP hydrolysis activity of the cleaved ATPase was inhibited by only 53.49%,while that of the un-cleaved ATPase was inhibited by 64.13%. Kinetic studies indicated that both the Km values and the inhibition type of vanadate were not affected by trypsin treatment. Upon proteolysis, Km remained as 0.34 mmol/L,while vanadate was still an uncompetitive inhibitor. Taking together, the structure and activity of the ATPase phosphatase domain were affected by trypsin treatment, implying that this domain might be regulated by the C-terminal end of the plasma membrane H+ ATPase.     

Effect of Lysophosphatidylcholine on ATP and ρ-Nitrophenyl Phosphate Hydrolysis by the Plasma Membrane H+-ATPase from Soybean Hypocotyls

The stimulatory effect of lysophosphatidylcholine (lyso-PC) on ATP and ρ-nitrophenyl phosphate (PNPP) hydrolysis by the plasma membrane H+-ATPase from soybean (Glycine max (L.) Merr.) hypocotyls was studied. Results showed that lyso-PC stimulated the hydrolysis of ATP; ATP hydrolysis was enhanced dramatically when lyso-PC was within 0-0.03%, and increased slightly when lyso-PC was higher than 0.03%. At the concentration of 0.03%, lyso-PC stimulated ATP hydrolysis by 80.5%. Kinetics analysis showed that V max increased from 0.46μmol Pi·mg-1 protein·min-1 to 0.87 μmol Pi·mg-1 protein·min-1 while Km increased from 0.88 mmol/L to 1.15 mmol/L under lyso-PC treatment. The optimum pH of ATP hydrolysis was shifted from 6.5 to 7.0. Moreover, it was found lyso-PC enhanced the inhibition of ATP hydrolysis by hydroxylamine. In the presence of 200 mmol/L hydroxylamine, ATP hydrolysis was inhibited by 74.4%, while it was inhibited by 84.4% when treated with lyso-PC. However, PNPP hydrolysis and the inhibitory effect of vanadate were not affected by lyso-PC. The above results indicated that the kinase domain might be an action site or regulatory region of the C-terminal autoinhibitory domain in the plant plasma membrane H+-ATPase.     

Drought stress stimulates p-nitrophenyl phosphate hydrolysis rate of the plasma membrane H+-ATPase from wheat leaves

The influence of drought stress on the ATP and p-nitrophenyl phosphate (PNPP) hydrolysis activity by plasma membrane H⁺-ATPase was investigated using purified plasma membrane vesicles from wheat leaves by two-phase partitioning. Drought stress increased the ATPase activity, and the optimal pH was shifted from 6.5 to about 7.0. Drought stress also stimulated the PNPP hydrolysis rate. The K_m for PNPP hydrolysis was moved from 4.49 ± 0.33 mM to 3.64 ± 0.12 mM. In addition, the PNPP hydrolysis was more sensitive to vanadate under drought compared to the control. However, the inhibitory effect of hydroxylamine on the ATPase was not changed by the present drought stress. In addtion, drought stress also decreased the trypsin activation of PNPP hydrolysis by PM H⁺-ATPase. These results suggested that drought stress altered the catalytic mechanism of the plasma membrane H⁺-ATPase, and the stimulation of its activity by drought stress was mainly due to increase of the catalytic activity of its phosphatase domain. It is also suggested that drought stress might alter the structure or property of the C-terminal end of PM H⁺-ATPase, therefore increasing the catalytic activity of the phosphatase domain.     

Effects of freezing on plasma membrane H<Superscript>+</Superscript>-ATPase of the callus from <Emphasis Type="Italic">Chorispora bungeana</Emphasis>

The influence of freezing treatment on plasma membrane (PM) H⁺-ATPase was investigated using plasma membrane vesicles isolated from calluses from Chorispora bungeana Fisch. & C.A. Mey. by the discontinuous sucrose gradient centrifugation. Freezing treatment (−4 °C) for 5 d resulted in significant increases in the ATPase activity and the activity of p-nitrophenyl phosphate (PNPP) hydrolysis, decreases in the K_m for ATP hydrolysis and PNPP hydrolysis, and the shift of optimal pH from 6.5 to 7.0. Also, the activity PNPP hydrolysis was less sensitive to vanadate after freezing treatment compared to control, while the inhibition of ATP hydrolysis by hydroxylamine was more sensitive. In addition, freezing treatment also decreased the activation effects of trypsin on PNPP hydrolysis, but increased the activation effects of lysophosphatidylcholine on ATP hydrolysis. Taken together, these results suggested that PM H⁺-ATPase might play an important role during adaptation to freezing and enhancing the frost hardness in C. bungeana.     

Comparison of Plasma Membrane H^＋-ATPase Activity in Two Ecotypes of Reed （Phragmites communis） Leaves from Different Habitats

Plasma membrane (PM) vesicles of the leaves of two ecotypes of reed (Phragrnites communis Trin.), swamp reed (SR) and heavy salt meadow reed (HSMR) growing in the desert region of Northwest China, were purified by two-phase partitioning and the properties of their PM H^ -ATPases (EC 3.6.1.35) were compared. The specific activity of this enzyme was greater in HSMR than in SR and the Km lower (1.27mmol/L in SR and 0.30mmol/L in HSMR), and the Vmax of ATP hydrolysis activity showed no significant difference between the two ecotypes. The PM H^ -ATPase was more sensitive to denaturing temperatures in HSMR than in SR, and the pH profile also showed a slight difference, suggesting that the catalytic mechanism of this enzyme was different in HSMR compared with that in SR. The p-nitrophenyl phosphate (PNPP) hydrolysis activity of H^ -ATPase was higher in HSMR than in SR at low concentrations of PNPP, but showed no difference at high PNPP concentration. The Km for PNPP hydrolysis was 3.61mmol/L and 1.92mmol/L in SR and HSMR, respectively. And the Vmax of PNPP hydrolysis showed no significant difference in the two reed ecotypes. An experiment with the inhibitor vanadate showed that the catalytic mechanisms of the phosphatase domain of the ATPase were different in the two ecotypes. The data obtained following trypsin treatment showed a difference in the enzyme activity pattern, suggesting that there existed a possible change in the C-terminus of the ATPase, either in the structure or in the property or both of them. In addition, compared with SR, the ATP-dependent H^ pumping activity of ATPase and the coupling between proton transport and ATP hydrolysis in HSMR were increased. These results indicated that the properties of PM H^ -ATPase were changed in HSMR with compared to those in SR, which might include enzyme modifications and different isoforms expressed. The alterations of the properties of this enzyme might be an adaptive response to the habitat.     

Proton pumping kinetics and origin of nitrate inhibition of tonoplast-type H+-ATPase

A tonoplast-type vesicle preparation, substantially free from other subcellular membranes, was obtained from corn roots by equilibrium sucrose density gradient centrifugation. At pH 6.5 and in the presence of chloride ions, the tonoplast-type ATPase activity as measured by Pi release, was inhibited by nitrate ions. The ATPase activity was insensitive to molybdate and vanadate, indicating a minimum nonspecific phosphatase and plasma membrane contamination. The vesicles exhibited an ATP hydrolysis-supported proton uptake which was measured by the absorption change of acridine orange. The ATP hydrolysis supported uptake and the subsequent perturbant-induced release of protons (decay) was described by a kinetic model which was previously developed to evaluate the coupling between proton pumping and the primary energy yielding process for other biomembranes. The proton pumping activity was more sensitive to nitrate ions then was ATP hydrolysis. The differential effect and the kinetic analysis of nitrate inhibition led us to suggest that (i) the coupling between Pi release and proton pumping was indirect in nature and (ii) the primary inhibitory effect of nitrate ion was originated from an interaction with a protogenic protein domain which is functionally linked to the ATPase in the tonoplast-type membrane.     

Influence of K＋ on the Coupling Between ATP Hydrolysis and Proton Transport by the Plasma Membrane H＋-ATPase from Soybean Hypocotyls

The plasma membrane vesicles were purified from soybean ( Glycine max L. ) hypocotyls by two-phase partitioning methods. The stimulatory effects of K+ on the coupling between ATP hydrolysis and proton transport by the plasma membrane H+-ATPase were studied. The results showed that the proton transport activity was increased by 850% in the presence of 100 mmol/L KC1, while ATP hydrolytic activity was only increased by 28.2%. Kinetic studies showed that Km of ATP hydrolysis decreased from 1.14 to 0.7 mmol/L, while Vmax of ATP hydrolysis increased from 285.7 to 344.8 nmol Pi·mg- l protein·min-1 in the presence of KC1. Experiments showed that the optimum pH was 6.5 and 6.0 in the presence and absence of KC1, respectively. Further studies revealed that K+ could promote the inhibitory effects of hydroxylamines and vanadates on the ATP hydrolytic activity. The above results suggested that K+ could regulate the coupling between ATP hydrolysis and proton transport of the plasma membrane H+ -ATPase through modulating the structure and function of the kinase and phosphatase domains of the plasma membrane H + -ATPase.     

Latency of Plasma Membrane H-ATPase in Vesicles Isolated by Aqueous Phase Partitioning : Increased substrate Accessibility or Enzyme Activation

The properties of the plasma membrane H⁺-ATPase and the cause of its latency have been studied using a highly purified plasma membrane fraction from oat (Avena sativa L., cv Victory) roots, prepared by aqueous two-phase partitioning. The ATPase has a maximum specific activity (at 37°C) in excess of 4 micromoles inorganic phosphate per milligram protein per minute in the presence of nondenaturing surfactants. It is inhibited by more than 90% by vanadate, is specific for ATP, has a pH optimum of 6.5, and is stimulated more than 4-fold by 50 millimolar K⁺ in the presence of low levels of the nondenaturing surfactants Triton X-100 and lysolecithin. This `latent' activity is usually explained as being a result of the inability of ATP to reach the ATPase in right-side out, sealed vesicles, until they are disrupted by surfactants. Consistent with this idea, trypsin digestion significantly inhibited the ATPase only in the presence of the surfactants. Electron spin resonance spectroscopy volume measurements confirmed that surfactant-free vesicles were mostly sealed to molecules similar to ATP. However, the Triton to protein ratio required to disrupt vesicle integrity completely is 10-fold less than that needed to promote maximum ATPase activity. We propose that plasma membrane ATPase activation is due not solely to vesicle disruption and accessibility of ATP to the ATPase but to the surfactants activating the ATPase by altering the lipid environment in its vicinity or by removing an inhibitory subunit.     

Characterization of the catalytic subunit of an anion pump

The ArsA protein, the 63-kDa catalytic subunit of an oxyanion-translocating ATPase, was purified by successive chromatography using Q-Sepharose, red agarose, and phenyl-Sepharose to a specific activity in excess of 1 mumol of ATP hydrolyzed per min per mg of protein. ATPase activity was dependent on the presence of the oxyanionic substrates. Inhibitors of other classes of ion-translocating ATPases had no effect on ArsA ATPase activity, including N,N'-dicyclohexyl-carbodiimide, azide, vanadate, and nitrate. The apparent Km for ATP was determined to be 0.13 mM. The optimal pH range for ATP hydrolysis was 7.5 to 7.8. ATPase activity required Mg2+ at a molar ratio of 2 ATP:1 Mg2+. Limited proteolysis by trypsin was used to study conformational changes produced upon binding of substrates to the ArsA protein. In the absence of substrates, the ArsA protein was rapidly cleaved by trypsin to a major product of 30 kDa. ATP was partially protected from trypsin digestion, while the anionic substrate antimonite alone had no effect on proteolysis. Combination of the two substrates nearly completely protected the ArsA protein from proteolysis. Proteolytic cleavage correlated with loss of anion-stimulated ATPase activity and substrate protection from cleavage correlated with retention of activity. These results demonstrate that ATP and antimonite together produce a conformational change which is different from that of the ArsA protein in the presence of either substrate alone and suggest interaction between the oxyanion and ATP binding sites.