高压电场对A549细胞中ABCG2和V-ATPase的表达及其耐药性的影响

目的:探讨高压电场对A549细胞中ABCG2和V-ATPase表达量的影响;探讨高压电场对A549细胞耐药性的影响。方法:MTT法测细胞生长曲线,明确能导致细胞可逆性电穿孔的最高电场强度。慢病毒构建ABCG2和V-ATPase低表达的A549细胞系,并用电场处理,用q-RT-PCR和Western-blot法检测处理前后ABCG2和V-ATPase的m RNA和蛋白表达量的变化。最适强度的高压电场处理各组细胞,在处理前后的细胞中分别加入阿霉素,用高效液相色谱法检测各组细胞中阿霉素浓度。结果:当电场强度为1500 V/cm时,肿瘤细胞增殖最慢;电场强度为1500 V/cm时,肿瘤细胞中ABCG2和V-ATPase的m RNA和蛋白的表达量分别降至对照组的58%和61%,具有统计学差异;1500 V/cm强度的电场可以提高肿瘤细胞内阿霉素的浓度3-4倍。结论:高压电场可以显著降低肿瘤细胞中V-ATPase和ABCG2的m RNA和蛋白的表达量并降低肿瘤细胞的耐药性。     

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。     

V-ATPases的功能及其抑制剂研究进展

V-ATPases作为一类酶,在真核细胞中广泛存在。V-ATPases是一个由多个亚基组成的复合物,主要有两个结构域,分别是位于外周的V1结构域和跨膜的V0结构域。V1结构域可以通过水解ATP供能;而V0结构域是质子的通道。它们发挥作用主要是通过水解ATP供能,泵运H＋进入囊泡腔中或泵H＋出细胞外。V-ATPases定位于细胞器膜及某些特殊细胞的细胞质膜,参与骨吸收、肿瘤的侵袭及耐药等生理及病理过程,因而V-ATPases是治疗骨质疏松、糖尿病及肿瘤等人类疾病的候选分子靶标。目前有许多研究致力于发现新的潜在的特异的V-ATPase抑制剂。     

家蚕V型ATP酶B亚基的克隆及表达特征

V型ATP酶(Vacuolar-type ATPase)是一种定位于细胞膜和细胞器膜上的氢离子转运酶。它利用ATP水解的能量将氢离子转运到液泡、囊泡或者胞外,从而维持细胞内正常的酸碱环境。V型ATP酶B亚基(V-ATPase B)作为ATP的催化位点,也有着非常重要的作用。为了探讨家蚕V-ATPase B(Bm V-ATPase B)的功能,首先从家蚕五龄幼虫的中肠c DNA中克隆了Bm V-ATPase B基因并构建原核表达载体进行原核表达,获得了重组蛋白,经质谱鉴定正确后,通过镍柱亲和层析的方法纯化了该蛋白并制备了多克隆抗体;最后分析了该蛋白在家蚕丝腺中的表达特征并利用免疫荧光对其在丝腺中的表达位置进行了定位。结果显示Bm V-ATPase B基因序列全长1 473 bp,预测蛋白分子量55 k Da,预测等电点5.3。通过Western blotting对家蚕5龄第3天和上蔟第1天幼虫丝腺的不同区段进行Bm V-ATPase B蛋白的表达特征分析,发现在两个时期该蛋白均在前部丝腺高量表达,而在中部丝腺和后部丝腺表达量相对较低。进一步对两个时期丝腺的不同区段进行免疫荧光定位,发现该蛋白在两个时期的前部丝腺、中部丝腺和后部丝腺均定位于细胞层。利用激光共聚焦显微镜对该蛋白进行进一步的定位,发现该蛋白主要在丝腺的细胞膜表达。研究结果明确了该蛋白在丝腺中的表达模式,为深入研究该蛋白在蚕丝纤维形成中的作用奠定了基础。     

植物原生质膜的糖转运蛋白

高等植物光合细胞同化的糖类由质外体途径穿过原生质膜转运时,利用Ｈ＾＋－ＡＴＰ形成的质了左糖逆电化学势进行共转运是由糖转运蛋白介导的。文中对近年来植物原生质膜单糖和蔗糖转运蛋白的克隆、鉴定及特性,糖转运蛋白组织定位和表达及其与光合同化物运和分配的关系等同研究进展作了介绍。     

盐胁迫对豌豆根液泡膜H^＋—ATPase活性及含量的影响

为了阐明液泡膜H^ -ATPase在盐胁迫下的作用和适应性调节机制,对豌豆（Pisum sativum L.）植株进行不同盐浓度和不同盐胁迫时间（1－3d）的处理后,分别测定液泡膜H^ -ATPase的H^ 转运活性、水解性和蛋白含量（A亚基）的变化。结果表明,100mmol/L和200mmol/L NaCl 处理1dH^ -ATPase的水解活性没有变化,而250mmol/L NaCl处理1d引起水解活性降低约25％。100mmol/L NaCl处理2d内水解活性没有变化,而第3天活性下降约20％。但是上述盐胁迫均能提高液泡膜H^ -ATPase的质子转运活性,说明盐胁迫后H^ -ATPase的水解活性和质子转运活性的变化不成比例,盐胁迫可能导致偶联比率的改变。Western blot研究发现,上述盐胁迫对液泡膜H^ -ATPase（A亚基）的含量基本无影响,仅100mmol/L NaCl处理3d后A亚基的量略有下降,这些结果证明,盐胁迫能刺激提高豌豆根液泡膜H^ -ATPase的H^ 泵效率,且泵效率的提高是源于偶联比率的改变,而不是由于ATP水解活性的提高和蛋白含量的增加。     

肿瘤细胞外泌体对肿瘤血管新生的调控作用

外泌体可将其内容物蛋白质、脂类、RNA、循环DNA等生物活性分子由供体细胞转运至受体细胞,对细胞与细胞间的通讯发挥重要调控作用。肿瘤细胞可以主动释放包括外泌体在内的胞外囊泡进入周围微环境。血管为肿瘤的生长提供氧气和营养物质,因此血管新生是肿瘤生长所必需的。研究发现,蛋白或非编码RNA在不同肿瘤细胞衍生的外泌体中存在特异性表达的现象。肿瘤外泌体将其内含的非编码RNA以及蛋白转运至内皮细胞,上调促血管新生因子的表达,进而提高内皮细胞的活性,促进其增殖、迁移和管腔形成。     

一种用于肿瘤药物治疗的新型人源性穿膜肽的优化及其应用

细胞穿膜肽(cell-penetrating peptide,CPP)作为一种体内大分子药物跨膜运输载体被广泛研究和应用。中期因子Midkine(MK)是人体的一种带有肝素结合域(heparin-binding domain,HBD)的生长因子。报道了MK中HBD的部分富含碱性氨基酸的基因序列(命名为MK-S0)与绿色荧光蛋白(EGFP)基因融合表达后,能将EGFP有效地转运入胞内,且其穿膜转运效率高于经典穿膜肽Tat。将MK-S0序列进一步突变优化改造得到的midkine-mutantΔ4(MK-Δ4),其穿膜效率比天然序列来源的MK-S0提高16倍以上,且MK-Δ4的穿膜转运作用适用于多种肿瘤细胞。穿膜机制分析研究结果显示,MK-Δ4可与细胞表面硫酸乙酰肝素结合,随之以巨胞饮形式内吞入胞。采用MTT方法检测的细胞生长抑制试验结果显示,连接有MK-Δ4的苦瓜来源的核糖体失活蛋白MAP30比单独的MAP30对HeLa肿瘤细胞的药效可提升5.8倍,大大提高了这种药物蛋白抑杀肿瘤细胞的效果。由此表明,源于MK的这种经过突变改造的MK-Δ4,可作为一种新型高效的细胞穿膜肽,将药物蛋白有效运输到细胞内发挥抗肿瘤效应。     

9R穿膜肽可增强P53抗肿瘤效果

为解决P53蛋白难以进入细胞内部发挥治疗作用的瓶颈难题.将p53基因融合插入带有9个精氨酸作为穿膜肽的表达载体中表达融合蛋白CPPs-P53,并与没有穿膜肽的P53蛋白进行比较,利用Western blotting方法检测蛋白的表达情况,MTT及Annexin V/PI双染法检测细胞生长抑制率及细胞凋亡率.Western blotting检测表明已成功在原核表达系统中表达融合蛋白CPPs-P53和P53蛋白,且蛋白纯度均已达到90％以上;MTT检测表明,P53蛋白对肿瘤细胞的生长虽有一定的抑制作用,但融合蛋白CPPs-P53与之相比,对肿瘤细胞生长的抑制效果显著增强,细胞生长抑制率有明显的提升,并且细胞生长抑制率呈现剂量依赖性;Annexin V/PI双染检测细胞凋亡情况也表明P53虽可以在一定程度上诱导肿瘤细胞的凋亡,但与P53蛋白相比较,融合蛋白CPPs-P53诱导的凋亡细胞明显增加,凋亡率是P53蛋白的2～3倍.由此说明在抑制肿瘤细胞的生长和诱导细胞凋亡方面,CPPs-P53比没有穿膜肽的P53蛋白的效果更显著.     

枸杞液泡膜H^+-转运焦磷酸酶基因LbVP1克隆及表达分析北大核心CSCD

液泡膜H^+-转运焦磷酸酶在调节植物生长发育和逆境胁迫应答中发挥重要作用。本研究在已构建的枸杞本地数据库中先进行VP基因电子克隆,然后结合RT-PCR方法克隆到一个枸杞液泡膜H^+-转运焦磷酸酶编码基因LbVP1,并对其序列结构、时空表达模式进行了初步分析。LbVP1开放阅读框全长2301 bp,编码766氨基酸残基。多序列比对显示该基因与拟南芥AVP基因相似性达87.9%,序列结构生物信息学预测和亚细胞定位实验表明,该基因具有液泡膜H^+-转运焦磷酸酶的保守结构域和跨膜区,可能在液泡膜发挥作用。荧光定量PCR结果显示,LbVP1在花、叶和不同发育阶段果实中存在时空表达差异,干旱胁迫处理下叶片和果实中该基因表达量与对照存在(极)显著差异(P<0.01,P <0.05)。研究结果将为阐明该基因在枸杞抗旱分子调控机制中的作用提供基础理论依据。     

Vacuolar H(+)-ATPase is expressed in response to gibberellin during tomato seed germination

Completion of germination (radicle emergence) by gibberellin (GA)-deficient (gib-1) mutant tomato (Lycopersicon esculentum Mill.) seeds is dependent upon exogenous GA, because weakening of the endosperm tissue enclosing the radicle tip requires GA. To investigate genes that may be involved in endosperm weakening or embryo growth, differential cDNA display was used to identify mRNAs differentially expressed in gib-1 seeds imbibed in the presence or absence of GA(4+7). Among these was a GA-responsive mRNA encoding the 16-kD hydrophobic subunit c of the V(0) membrane sector of vacuolar H(+)-translocating ATPases (V-ATPase), which we termed LVA-P1. LVA-P1 mRNA expression in gib-1 seeds was dependent on GA and was particularly abundant in the micropylar region prior to radicle emergence. Both GA dependence and tissue localization of LVA-P1 mRNA expression were confirmed directly in individual gib-1 seeds using tissue printing. LVA-P1 mRNA was also expressed in wild-type seeds during development and germination, independent of exogenous GA. Specific antisera detected protein subunits A and B of the cytoplasmic V(1) sector of the V-ATPase holoenzyme complex in gib-1 seeds only in the presence of GA, and expression was localized to the micropylar region. The results suggest that V-ATPase plays a role in GA-regulated germination of tomato seeds.     

The V0-ATPase mediates apical secretion of exosomes containing Hedgehog-related proteins in Caenorhabditis elegans

Polarized intracellular trafficking in epithelia is critical in development, immunity, and physiology to deliver morphogens, defensins, or ion pumps to the appropriate membrane domain. The mechanisms that control apical trafficking remain poorly defined. Using Caenorhabditis elegans, we characterize a novel apical secretion pathway involving multivesicularbodies and the release of exosomes at the apical plasma membrane. By means of two different genetic approaches, we show that the membrane-bound V0 sector of the vacuolar H+-ATPase (V-ATPase) acts in this pathway, independent of its contribution to the V-ATPase proton pump activity. Specifically, we identified mutations in the V0 "a" subunit VHA-5 that affect either the V0-specific function or the V0+V1 function of the V-ATPase. These mutations allowed us to establish that the V0 sector mediates secretion of Hedgehog-related proteins. Our data raise the possibility that the V0 sector mediates exosome and morphogen release in mammals.     

Saccharomyces cerevisiae lacking Btn1p modulate vacuolar ATPase activity to regulate pH imbalance in the vacuole

The vacuolar H(+)-ATPase (V-ATPase) along with ion channels and transporters maintains vacuolar pH. V-ATPase ATP hydrolysis is coupled with proton transport and establishes an electrochemical gradient between the cytosol and vacuolar lumen for coupled transport of metabolites. Btn1p, the yeast homolog to human CLN3 that is defective in Batten disease, localizes to the vacuole. We previously reported that Btn1p is required for vacuolar pH maintenance and ATP-dependent vacuolar arginine transport. We report that extracellular pH alters both V-ATPase activity and proton transport into the vacuole of wild-type Saccharomyces cerevisiae. V-ATPase activity is modulated through the assembly and disassembly of the V(0) and V(1) V-ATPase subunits located in the vacuolar membrane and on the cytosolic side of the vacuolar membrane, respectively. V-ATPase assembly is increased in yeast cells grown in high extracellular pH. In addition, at elevated extracellular pH, S. cerevisiae lacking BTN1 (btn1-Delta), have decreased V-ATPase activity while proton transport into the vacuole remains similar to that for wild type. Thus, coupling of V-ATPase activity and proton transport in btn1-Delta is altered. We show that down-regulation of V-ATPase activity compensates the vacuolar pH imbalance for btn1-Delta at early growth phases. We therefore propose that Btn1p is required for tight regulation of vacuolar pH to maintain the vacuolar luminal content and optimal activity of this organelle and that disruption in Btn1p function leads to a modulation of V-ATPase activity to maintain cellular pH homeostasis and vacuolar luminal content.     

Novel vacuolar H+-ATPase complexes resulting from overproduction of Vma5p and Vma13p.

The vacuolar H(+)-ATPase (V-ATPase) is a multisubunit complex composed of two sectors: V(1), a peripheral membrane sector responsible for ATP hydrolysis, and V(0), an integral membrane sector that forms a proton pore. Vma5p and Vma13p are V(1) sector subunits that have been implicated in the structural and functional coupling of the V-ATPase. Cells overexpressing Vma5p and Vma13p demonstrate a classic Vma(-) growth phenotype. Closer biochemical examination of Vma13p-overproducing strains revealed a functionally uncoupled V-ATPase in vacuolar vesicles. The ATP hydrolysis rate was 72% of the wild-type rate; but there was no proton translocation, and two V(1) subunits (Vma4p and Vma8p) were present at lower levels. Vma5p overproduction moderately affected both V-ATPase activity and proton translocation without affecting enzyme assembly. High level overexpression of Vma5p and Vma13p was lethal even in wild-type cells. In the absence of an intact V(0) sector, overproduction of Vma5p and Vma13p had a more detrimental effect on growth than their deletion. Overproduced Vma5p associated with cytosolic V(1) complexes; this association may cause the lethality.     

Vacuolar-Type H+ -ATPases Are Associated with the Endoplasmic Reticulum and Provacuoles of Root Tip Cells

To understand the origin of vacuolar H+ -ATPases (V-ATPases) and their cellular functions, the subcellular location of V-H+ -ATPases was examined immunologically in root cells of oat seedlings. A V-ATPase complex from oat roots consists of a large peripheral sector (V1) that includes the 70-kD (A) catalytic and the 60-kD (B) regulatory subunits. The soluble V1 complex, thought to be synthesized in the cytoplasm, is assembled with the membrane integral sector (V0) at a yet undefined location. In mature cells, V-ATPase subunits A and B, detected in immunoblots with monoclonal antibodies (Mab) (7A5 and 2E7), were associated mainly with vacuolar membranes (20-22% sucrose) fractionated with an isopycnic sucrose gradient. However, in immature root tip cells, which lack large vacuoles, most of the V-ATPase was localized with the endoplasmic reticulum (ER) at 28 to 31% sucrose where a major ER-resident binding protein equilibrated. The peripheral subunits were also associated with membranes at 22% sucrose, at 31 to 34% sucrose (Golgi), and in plasma membranes at 38% sucrose. Immunogold labeling of root tip cells with Mab 2E7 against subunit B showed gold particles decorating the ER as well as numerous small vesicles (0.1-0.3 [mu]m diameter), presumably pro-vacuoles. The immunological detection of the peripheral subunit B on the ER supports a model in which the V1 sector is assembled with the V0 on the ER. These results support the model in which the central vacuolar membrane originates ultimately from the ER. The presence of V-ATPases on several endomembranes indicates that this pump could participate in diverse functional roles.     

A 100 kDa polypeptide associates with the V0 membrane sector but not with the active oat vacuolar H(+)-ATPase, suggesting a role in assembly

The vacuolar H(+)-ATPase (V-ATPase) is responsible for acidifying endomembrane compartments in eukaryotic cells. Although a 100 kDa subunit is common to many V-ATPases, it is not detected in a purified and active pump from oat (Ward J.M. and Sze H. (1992) Plant Physiol. 99, 925-931). A 100 kDa subunit of the yeast V-ATPase is encoded by VPH1. Immunostaining revealed a Vph1p-related polypeptide in oat membranes, thus the role of this polypeptide was investigated. Membrane proteins were detergent-solubilized and size-fractionated, and V-ATPase subunits were identified by immunostaining. A 100 kDa polypeptide was not associated with the fully assembled ATPase; however, it was part of an approximately 250 kDa V0 complex including subunits of 36 and 16 kDa. Immunostaining with an affinity-purified antibody against the oat 100 kDa protein confirmed that the polypeptide was part of a 250 kDa complex and that it had not degraded in the approximately 670 kDa holoenzyme. Co-immunoprecipitation with a monoclonal antibody against A subunit indicated that peripheral subunits exist as assembled V1 subcomplexes in the cytosol. The free V1 subcomplex became attached to the detergent-solubilized V0 sector after mixing, as subunits of both sectors were co-precipitated by an antibody against subunit A. The absence of this polypeptide from the active enzyme suggests that, unlike the yeast Vph1p, the 100 kDa polypeptide in oat is not required for activity. Its association with the free Vo subcomplex would support a role of this protein in V-ATPase assembly and perhaps in sorting.     

Subunit H of the V-ATPase involved in endocytosis shows homology to beta-adaptins

The vacuolar ATPase (V-ATPase) is a multisubunit enzyme that facilitates the acidification of intracellular compartments in eukaryotic cells and plays an important role in receptor-mediated endocytosis, intracellular trafficking processes, and protein degradation. In this study we show that the C-terminal fragment of 350 residues of the regulatory subunit H (V1H) of the V-ATPase shares structural and functional homologies with the beta-chains of adaptor protein complexes. Moreover, the fragment is similar to a region in the beta-subunit of COPI coatomer complexes, which suggests the existence of a shared domain in these three different families of proteins. For beta-adaptins, this fragment binds to cytoplasmic di-leucine-based sorting motifs such as in HIV-1 Nef that mediate endocytic trafficking. Expression of this fragment in cells blocks the internalization of transmembrane proteins, which depend on di-leucine-based motifs, whereas mutation of the consensus sequence GEY only partly diminishes the recognition of the sorting motif. Based on recent structural analysis, our results suggest that the di-leucine-binding domain consists of a HEAT or ARM repeat protein fold.     

New mode of action for a knottin protein bioinsecticide: pea albumin 1 subunit b (PA1b) is the first peptidic inhibitor of V-ATPase

PA1b (for pea albumin 1 subunit b) is a plant bioinsecticide lethal to several pests that are important in agriculture or human health. PA1b belongs to the inhibitory cystine knot family or knottin family. Originating from a plant (the garden pea) commonly eaten by humans without any known toxic or allergic effects, PA1b is a candidate for transgenic applications and is one of the most promising biopesticides for pest control. Using whole-cell patch-clamp techniques on Sf9 PA1b-sensitive lepidopteran insect cells, we discovered that PA1b reversibly blocked ramp membrane currents in a dose-dependent manner (EC(50) = 0.52 μM). PA1b had the same effect as bafilomycin, a specific inhibitor of the vacuolar proton pump (V-type H(+)-ATPase), and the PA1b-sensitive current depended on the internal proton concentration. Biochemical assays on purified V-ATPase from the lepidopteran model Manduca sexta showed that PA1b inhibited the V(1)V(0)-type H(+)-ATPase holoenzyme activity (IC(50) ～ 70 nM) by interacting with the membrane-bound V(0) part of the V-ATPase. V-ATPase is a complex protein that has been studied increasingly because of its numerous physiological roles. In the midgut of insects, V-ATPase activity is essential for energizing nutrient absorption, and the results reported in this work explain the entomotoxic properties of PA1b. Targeting V-ATPase is a promising means of combating insect pests, and PA1b represents the first peptidic V-ATPase inhibitor. The search for V-ATPase inhibitors is currently of great importance because it has been demonstrated that V-ATPase plays a role in so many physiological processes.     

PKR1 encodes an assembly factor for the yeast V-type ATPase

Deletion of the yeast gene PKR1 (YMR123W) results in an inability to grow on iron-limited medium. Pkr1p is localized to the membrane of the endoplasmic reticulum. Cells lacking Pkr1p show reduced levels of the V-ATPase subunit Vph1p due to increased turnover of the protein in mutant cells. Reduced levels of the V-ATPase lead to defective copper loading of Fet3p, a component of the high affinity iron transport system. Levels of Vph1p in cells lacking Pkr1p are similar to cells unable to assemble a functional V-ATPase due to lack of a V0 subunit or an endoplasmic reticulum (ER) assembly factor. However, unlike yeast mutants lacking a V0 subunit or a V-ATPase assembly factor, low levels of Vph1p present in cells lacking Pkr1p are assembled into a V-ATPase complex, which exits the ER and is present on the vacuolar membrane. The V-ATPase assembled in the absence of Pkr1p is fully functional because the mutant cells are able to weakly acidify their vacuoles. Finally, overexpression of the V-ATPase assembly factor Vma21p suppresses the growth and acidification defects of pkr1Delta cells. Our data indicate that Pkr1p functions together with the other V-ATPase assembly factors in the ER to efficiently assemble the V-ATPase membrane sector.     

V-ATPase, ScNhx1p and yeast vacuole fusion

Membrane fusion is the last step in trafficking pathways during which membrane vesicles fuse with target organelles to deliver cargos. It is a central cellular reaction that plays important roles in signal transduction, protein sorting and subcellular compartmentation. Recent progress in understanding the roles of ion transporters in vacuole fusion in yeast is summarized in this article. It is becoming increasingly evident that the vacuolar proton pump V-ATPase and vacuolar Na+/H+ antiporter ScNhx1p are key components of the vacuole fusion machinery in yeast. Yeast ScNhx1p regulates vacuole fusion by controlling the luminal pH. V-ATPases serve a dual role in vacuolar integrity in which they regulate both vacuole fusion and fission reactions in yeast. Fission defects are epistatic to fusion defects. Vacuole fission depends on the proton translocation activity of the V-ATPase; by contrast, the fusion reaction does not need the transport activity but requires the physical presence of the proton pump. V0, the membrane-integral sector of the V-ATPase, forms trans-complexes between the opposing vacuoles in the terminal phase of vacuole fusion where the V0trans-complexes build a continuous proteolipid channel at the fusion site to mediate the bilayer fusion.