两相分配法制备南极红酵母质膜

用葡聚糖 T-500(Dextran T-500)和聚乙二醇(PEG-3350)两相体系制备南极红酵母(Rhodotorula sp.)菌株 NJ298 的质膜.首先在 2 mmol/L KCl 浓度下,选用5种不同的聚合物浓度(5.6%、5.8%、6.0%、6.2%、6.4%,W/W),研究了 NJ298 质膜在两相体系中的分配情况,在此基础上进一步研究了 KCl 浓度(2 mmol/L、4 mmol/L、6 mmol/L、8 mmol/L、10 mmol/L)对 NJ298 质膜的纯度及得率的影响.结果表明,选用6.0%聚合物浓度,4 mmol/LKCl 的两相分配体系,分离3次可得到相对纯度在 78.2%的南极红酵母质膜组分,标志酶鉴定及磷钨酸染色电镜检测均表明获得了高纯度密实的正向型的质膜囊泡.这为进一步研究该菌株的南极极端环境适应机制奠定了基础.     

两相法分离地被菊叶片质膜的研究

以地被菊(Dendranthema×grandiflorum Kitamura)叶片为材料,通过水溶性聚合物Dextran T-500和PEG 3350所构成的两相分配体系制备质膜。在一定盐浓度（5 mmol.L-1 NaCl）下选用5种不同的聚合物浓度（5.8%、6.0%、6.2%、6.4%、6.6%,W/W）,研究了地被菊叶片质膜在两相体系中的分配情况,在此基础上进一步研究了不同盐浓度（2、4、5、10、20 mmol.L-1 NaCl）对地被菊叶片质膜的纯度及蛋白产率的影响。标志酶鉴定及磷钨酸染色电镜检测的结果表明,地被菊叶片选用6.2%（W/W）聚合物浓度和7 mmol.L-1 NaCl组成的两相分配体系可获得较高纯度的密实正向型质膜囊泡。     

两相法分离地被菊叶片质膜的研究

以地被菊(Dendranthema×grandiflorum Kitamura)叶片为材料,通过水溶性聚合物Dextran T-500和PEG 3350所构成的两相分配体系制备质膜.在一定盐浓度(5mm01·L-1NaCl)下选用5种不同的聚合物浓度(5.8%、6.0%、6.2%、6.4%、6.6%,W/W),研究了地被菊叶片质膜在两相体系中的分配情况,在此基础上进一步研究了不同盐浓度(2、4、5、10、20mm01·L-1NaCl)对地被菊叶片质膜的纯度及蛋白产率的影响.标志酶鉴定及磷钨酸染色电镜检测的结果表明,地被菊叶片选用6.2%(W/W)聚合物浓度和7mm01·L-1NaCl组成的两相分配体系可获得较高纯度的密实正向型质膜囊泡.     

胡杨质膜的纯化及其H＋-ATPase活性的研究

用Dextran T-500, PEG 3350两相分配法分离并纯化了悬浮培养的胡杨细胞质膜.不同聚合物浓度(5.5%、5.7%、5.9%、6.1%、6.3%、6.5%)和KCl浓度(0、5、10、15 mmol/L)对分离效果影响的研究结果表明, 采用聚合物浓度为5.9%和无盐存在的两相分配体系可获得纯度较高的胡杨细胞质膜.纯化的质膜H^＋-ATPase的活力提高8倍,且酶定向程度较高,这为进一步研究胡杨细胞质膜特性及获得高纯度H^＋-ATPase提供了良好基础.     

两相法分离纯化橡胶树树皮质膜

橡胶树树皮质膜H~+-ATPase在橡胶树产排胶过程中扮演着重要角色,制备高纯度及高活性的质膜是研究质膜H~+-ATPase特性和功能的必要条件。该研究以一年生巴西橡胶树(Hevea brasiliensis)树皮为材料,利用差速离心法获得粗膜微粒体,通过两相分配法分离纯化质膜,并研究两相体系中不同浓度聚合物(5.9%、6.1%、6.3%、6.5%、6.7%,W/W)和KCl(2、5、8、11、14 mmol·L~(-1))对质膜蛋白得率和纯化效率的影响。通过Bradford法对质膜蛋白得率进行检测,同时采用酶活性检测法对质膜纯度进行检测,分析结果表明选用6.4%(W/W)聚合物浓度和5mmol·L~(-1)KCl组成的两相体系可获得较高纯度和得率的橡胶树树皮质膜。通过电镜观察法在形态学上对质膜纯度进一步评价,利用铅铀能侵染全部膜组分使其染色,而磷钨酸只能专一性地侵染质膜并使其染色这一特性,分别使用铅铀和磷钨酸对切片进行染色,并通过透射电镜对切片染色程度进行直接观察,结果表明提取的粗膜微粒体中质膜组分较少,存在大量的细胞器膜污染,而纯化后的质膜膜组分较单一,其他膜组分污染较少,而且质膜大小较均一,可以用于进行后续橡胶树树皮质膜H~+-ATPase特性和功能的研究。     

胡杨质膜的纯化及其H~ -ATPase活性的研究

用DextranT 5 0 0 ,PEG 335 0两相分配法分离并纯化了悬浮培养的胡杨细胞质膜 .不同聚合物浓度(5 5 %、 5 7%、 5 9%、 6 1%、 6 3%、 6 5 % )和KCl浓度 (0、 5、 10、 15mmol/L)对分离效果影响的研究结果表明 ,采用聚合物浓度为 5 9%和无盐存在的两相分配体系可获得纯度较高的胡杨细胞质膜 .纯化的质膜H ATPase的活力提高 8倍 ,且酶定向程度较高 ,这为进一步研究胡杨细胞质膜特性及获得高纯度H ATPase提供了良好基础     

小麦旗叶高纯度质膜的提取及蛋白质组学双向电泳体系的建立

以生长到Feekes 8.5时期小麦旗叶为试验材料,通过差速离心结合两相法提取 并纯化质膜蛋白,进而在裂解液选择、SDS-PAGE胶浓度及蛋白质上样量等方面对质膜蛋白质双向电泳体系进行了优化.结果表明,采用6.4% PEG 3 350/Dextran T-500 (W/W)两相体系可以获得纯度高达87.9%质膜微囊. 经TCA-丙酮法裂解蛋白,以12% SDS-PAGE分离胶对900 μg质膜蛋白进行双向电泳,在2-DE图谱上可分辨出173个蛋白点. 建立了一套用于小麦旗叶高纯度质膜的提取方法及其蛋白质组学双向电泳体系.     

抗盐胡杨Na+/H+逆向转运蛋白基因PeNhaD1的功能

将胡杨Na /H 逆向转运蛋白基因PeNhaD1,分别转入对盐敏感的缺失质膜和缺失液泡膜Na /H 逆向转运蛋白基因的酵母突变菌株ANT3和GX1中。结果表明,在pH6.0、Na 浓度为80mmol/L(固体培养基)或400mmol/L(液体培养基)的条件下,转化具有目的基因的酵母ANT3具有更高的耐盐性,而将目的基因转化到突变株GX1时,却不能提高其耐盐性。实验结果说明PeNhaD1可能是通过编码质膜Na /H 逆向转运蛋白而提高酵母的耐盐性的,推测其在胡杨耐盐机制中的作用可能是提高拒盐性。     

两相分配法制备玉米根质膜及其纯度鉴定

用Ｄｅｘｔｒａｎ Ｔ５００,ＰＥＧ３３５０两相体系制备玉米根质膜,首先在高盐浓度下选用五种不同的聚合物浓度,研究了玉米根系膜在两相体系中的分配情况,在此基础上研究了ＮａＣｌ浓度对玉米根质膜的纯度及得率的影响。结果表明,制备了玉米根质膜选用６．２％聚合物浓度,７．５ｍｍｏｌ／Ｌ ＮａＣｌ的两相体系比较合适。     

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。     

两相分配法制备玉米根质膜及其纯度鉴定

用ＤｅｘｔｒａｎＴ５００,ＰＥＧ３３５０两相体系制备玉米根质膜．首先在高盐浓度（２２ｍｍｏｌ／ＬＮａＣｌ）下选用五种不同的聚合物浓度（５．８％、６．０％、６．２％、６．３％、６．４％,Ｗ／Ｗ）,研究了玉米根质膜在两相体系中的分配情况,在此基础上进一步研究了Ｎａ－Ｃｌ浓度（２、４、５、１１、２２ｍｍｏｌ／Ｌ）对玉米根质膜的纯度及得率的影响．结果表明,制备玉米根质膜选用６．２％（Ｗ／Ｗ）聚合物浓度,７．５ｍｍｏｌ／ＬＮａＣｌ的两相体系比较合适．标志酶鉴定及低ｐＨ值磷钨酸染色电镜检测均表明获得了高纯度密实的正向型的质膜囊泡,质膜标志酶ＶＯ３－４－ＡＴＰａｓｅ的活性潜势达８８．９％．     

Subcellular Localization and Kinetic Characterization of ABA Binding Proteins in Maize Root

By means of differential centrifugation, cytosol fraction and microsome were prepared from maize roots which have been grown in dark for 4 d. Highly purified plasma membranes were isolated from the microsome in two-phase aqueous system which is composed of 6.9 % (W/W) Dextran T500 and PEG 3350. The tonoplast was collected from the interface between 1% and 8% (W/W) Dextran T70 after gradient centrifugation. Electron microscopic observation and marker enzyme activities analysis proved that these fractions contained very few other membranes. Microvolume radioactivity ligand binding assay indicated that the specific binding sites of ABA in maize root microsome were mainly distributed on tonoplast and plasma membrane fractions. Their specific binding activity was 2485.4 and 1257.3 fmol/mg protein, respectively, the specific binding activity of cytosol fraction being the lowest (one order of magnitude lower). The dissociation constant (KD) of ABA-BP in plasma membrane was 1.57 nmol/L.     

用两相法纯化玉米精细胞质膜

纯系玉米(Zea mays L.)708的新鲜花粉经蔗糖溶液等渗温育、低渗胀破,用30％Percoll不连续密度梯度离心,制备大量的生活精细胞。精细胞用French压力室破碎后离心(90000×g,4℃),获得微粒体。随后,用16g的(6.2％Dextran T500/6.2％PEG3350)两相系统加以纯化。一级分离后,上相液(U_1)的K~ 刺激的Mg~(2 )-ATP酶活性稍低于下相液(L_1);对U_1进行二级分离后,U_2的K~ 刺激的Mg~(2 )-ATP酶活性远远高于下相液(U_2L),分离率达到61.1％。膜蛋白质的分离趋势与K~ 刺激的Mg~(2 )-ATP酶相似。选用细胞色素C氧化酶作为线粒体的标志酶,虽只经一级分离,但在U_1中已检测不到该酶活性。精细胞质膜的磷钨酸特异染色电镜观察结果显示,由二级分离所得质膜的纯度达到90％以上。     

玉米根ABA结合蛋白的亚细胞定位及动力学性质

以玉米（Ｚｅａ ｍａｙｓＬ．）根或胚芽鞘为材料,经匀浆、分级离心得到胞质部分和膜部分（微粒体）,进一步用６．２％ （Ｗ／Ｗ ） Ｄｅｘｔｒａｎ Ｔ５００ 和ＰＥＧ ３３５０ 两相系统制备质膜,用１％ 和８％ （Ｗ ／Ｗ） Ｄｅｘｔｒａｎ Ｔ７０ 梯度离心制备液泡膜． 电镜鉴定及多种标志酶检测表明,制备获得了高纯度正向型质膜和富含液泡膜的组分,其它内膜的污染很少． 用微量放射配体结合（ＭＲＬＢ）实验证明,玉米根微粒体的ＡＢＡ专一性结合位点主要分布在液泡膜和质膜上,这两种膜组分与ＡＢＡ 的特异结合活性分别为２４８５．４ ｆｍ ｏｌ／ｍ ｇ ｐｒｏｔｅｉｎ 和１２５７．３ ｆｍ ｏｌ／ｍ ｇ ｐｒｏ－ｔｅｉｎ,玉米根段胞质部分结合活性最低（差一个数量级）．质膜上ＡＢＡ－ＢＰ与ＡＢＡ 的结合平衡解离常数（ＫＤ）为１．５７ ｎｍ ｏｌ／Ｌ．     

α-amylase production in aqueous two-phase systems with Bacillus subtilis

The production of α-amylase (1,4-α-d-glucan glucanohydrolase, EC 3.2.1.1) by Bacillus subtilis has been studied in repeated batch fermentations in aqueous two-phase systems. In a phase system composed of PEG 600, 8% (w/w), PEG 3350, 5% (w/w)/Dextran T 500, 2% (w/w), 82% of the enzyme partitioned to the top phase. The enzyme concentration in the top phase reached 0.85–1.35 U ml^?1 during the fermentations compared with 0.58 U ml^?1 in the reference fermentation. In the phase system composed of PEG 3350, 9% (w/w)/Dextran T 500, 2% (w/w), 73% of the enzyme partitioned to the top phase. However, the enzyme concentration in this phase system reached only 0.35 U ml^?1 in the top phase. The bacterial cells were microscopically observed to partition totally to the bottom phase in the aqueous two-phase system used. The results are discussed in relation to recirculation of cells by immobilizing to a solid matrix. Extraction of the product to the top phase and the effect of the phase polymers, especially PEG, on the production are also discussed.     

Characterization of ATPase activities in rice root plasmalemma vesicles isolated by two-phase partitioning

Plasma membrane vesicles were isolated from the roots of 7-day-old rice plants ( Oryza sativa L. cv. Bahía) by utilizing an aqueous polymer two-phase system with 6.2%:6.2% (w/w) Dextran T500 and polyethylene glycol 3350 (PEG) at pH 7.6. Plasmalemma vesicles of high purity were obtained as indicated by the vanadate-sensitive K⁺, Mg²⁺-ATPase activity that was 18 times higher in the upper (PEG-rich) phase than in the lower (Dextran-rich) phase and by specific staining with sodium silicotungstate. Two peaks of ATPase activity were found. One showed a pH optimum at 6.0 in the presence of 150 m M KCl and 3 m M ATP with apparent K_m (ATP) and V_max of 0.75 m M and 79 μmol (mg protein)⁻¹ h⁻¹, respectively. With 50 m M KCl and 7 m M ATP a pH optimum of 6.5, an apparent K_m (ATP) of 6.3 m M and V_max of 159 μmol (mg protein)⁻¹ h⁻¹ were determined. Both activities were specific for ATP, unspecific for monovalent cations, sensitive to sodium vanadate and Ca²⁺ but insensitive to azide and nitrate.     

Partition of membrane particles in aqueous two-polymer phase system and its practical use for purification of plasma membranes from plants

A simplified method for the isolation of a plasma membrane-enriched fraction from plants utilizing an aqueous two-polymer phase system is outlined. Mainly, the plant used was Orchard grass (Dactylis glomerata L.). The two-phase system consisted of 5.6% (w/w) of dextran T500 and 5.6% (w/w) of polyethyleneglycol 4000 in 0.5 molar sorbitol-15 millimolar Tris-maleate (pH 7.3), and 30 millimolar NaCl. In this system, the plasma membranes and the other membranes were preferentially partitioned into the top phase and into the lower phase, respectively. The purity of the isolated plasma membrane was sufficiently high even after a single partition (i.e. about 85% purity) and more than 90% purity was obtained after repeating the partition in a newly prepared lower phase. The plasma membrane was identified with the aid of phosphotungstic acid-chromic acid stain and the association of vanadate-sensitive Mg²⁺-ATPase. The plasma membrane-associated ATPase had a pH optimum at 6.5 and showed a high specificity for Mg²⁺ and ATP. KCl stimulation was low (6% stimulation) at the pH optimum, but a relatively high stimulation (23%) occurred at pH 5.5. This method for plasma membrane isolation may be applicable to a wide variety of plants and plant tissue including green leaves.