水牛睾丸曲精细管蛋白质组双向电泳方法的建立及优化

建立并优化了沼泽型水牛睾丸曲精细管蛋白质分离的双向电泳体系,为后续水牛睾丸曲精细管蛋白质表达谱的鉴定和研究奠定基础。比较不同IPG胶条(线性与非线性)、胶条pH范围和蛋白质上样量这三个参数对双向电泳结果的影响。结果显示,采用上样量350μg的曲精细管总蛋白、24 cm且pH值4～7的线性IPG胶条能够更好地分离水牛睾丸曲精细管蛋白质,获得质量较好且分辨率较高的双向电泳图谱,得到大约486个蛋白点。双向凝胶电泳技术能够对水牛睾丸曲精细管蛋白质进行有效分离,并通过对双向电泳体系的优化可获得蛋白质点清晰且分辨率更高的双向电泳图谱。     

发菜蛋白质组双向电泳技术的建立及优化

为建立适用于发菜(Nostoc flagelliforme)蛋白质组研究的双向电泳技术,对发菜蛋白质的提取、裂解、上样量、IEF及SDS-PAGE电泳等关键步骤进行了优化,结果显示:发菜蛋白质主要分布在pH 4～7范围内,采用改良TCA法可提高提取液中蛋白质的含量和双向电泳图谱的分辨率,裂解液含60 mmol/L DTT,24 cm IPG胶条上样量1.5 mg时不仅提高了蛋白质的溶解性,而且改善了双向电泳的分离效果,得到近800个蛋白点,且蛋白点清晰,图谱分辨率较好.采用优化后的双向电泳体系提高了发菜蛋白质双向电泳的分辨率和重复性,建立起一套适用于发菜蛋白质组分析的双向电泳方法.     

玉米花丝蛋白质组双向电泳条件的优化

以玉米温敏自交不亲和系‘HE97’的花丝为材料,比较了3种不同蛋白质提取方法对双向电泳结果的影响,并对其中的蛋白质上样量、等电聚焦条件及SDS-PAGE凝胶浓度进行了探索与优化。结果表明,与酚提取法和改良的酚提取法相比,采用三氯乙酸/丙酮提取法提取蛋白质操作简便,所得的双向电泳图谱蛋白质点数较多,图谱背景清晰,是一种提取玉米花丝蛋白质的有效方法。优化后的双向电泳技术体系适合于玉米花丝全蛋白质的双向电泳分析。     

蝴蝶兰叶片蛋白质提取及双向电泳体系优化

通过对蛋白质提取、IPG胶条选择、上样量、水化方式、聚焦条件等方面的优化,建立蝴蝶兰叶片蛋白质的双向电泳体系。结果表明,采用酚抽提法提取蝴蝶兰叶片蛋白质的纯度较高,复溶较完全;双向电泳优化体系选用24 cm pH 3～10 NL的IPG胶条,被动水化,上样量为1.35 mg,B1程序进行等电聚焦,12%分离胶进行第二向电泳,考马斯亮蓝G-250染色。该方法获得分辨率较高、重复性较好的蝴蝶兰叶片双向电泳图谱,蛋白数点多达1163个,可以满足蝴蝶兰蛋白质组学研究和分析。     

松材线虫全蛋白的提取及其双向电泳体系优化

目的:一种适用于双向电泳体系的松材线虫全蛋白提取方法的建立及其双向电泳体系的优化.方法:以松材线虫为实验材料,比较2种不同的蛋白提取方法,并对双向电泳中的IPG胶条长度、IPG胶条最适pH范围、上样量等3个方面的条件进行优化.结果:采用TCA-丙酮法提取的蛋白质浓度较高,达到2.18μg/μl.使用pH5 ～8、24cm的IPG干胶条,上样量为120μg,经双向电泳分离可得到背景清晰、分辨率较高的2 - DE图谱,能检测到2 000个左右清晰的蛋白点,含有相对丰富的蛋白信息量.结论:该实验所建立的松材线虫提取方法和优化体系可以为今后松材线虫蛋白质组学的研究奠定技术基础.     

小麦根蛋白提取与双向电泳方法的优化与应用

为了建立一套适合小麦根蛋白质组分析的双向电泳系统（2-DE）,得到更加清晰的电泳图谱,本研究以小麦幼苗根系为材料,对根蛋白的提取方法、上样量等进行了优化。研究发现,上样量为1200μg时,Trizol抽提法提取的蛋白能够获得图像清晰、分辨率高、重复性好的双向电泳图谱,基本满足小麦根系蛋白质组学的分析和研究。     

桶形芋螺毒管蛋白质组双向电泳条件优化

目的：优化双向电泳的条件,建立适用于桶形芋螺毒管蛋白质组分析的双向电泳方法。方法：对毒管蛋白的提取、上样量及SDS-PAGE凝胶浓度等影响因素进行优化。结果：乙酸提取法适宜于毒管蛋白的提取,对于pH3～10、17cm的IPG胶条,当上样量为0.75mg,聚焦70000Vhr,SDS-PAGE凝胶浓度为15%时,可提高双向电泳的分离效果,所得蛋白点清晰、数目达到1003个。结论：采用优化的条件进行双向电泳,能得到分辨率高、重现性好、完整的双向电泳图谱,为后续桶形芋螺毒管蛋白质组学研究打下基础。     

多子房小麦蛋白质双向电泳体系的建立及优化

为建立适用于显性多子房小麦细胞质效应的蛋白质双向电泳体系,以显性多子房小麦材料DUOII与特异细胞质材料TeZhiI杂交的F1幼穗为材料,采用TCA-丙酮法提取蛋白质,并在IPG胶条长度和pH范围、SDS-PAGE凝胶浓度及蛋白质上样量等方面,对多子房小麦幼穗蛋白质双向电泳体系进行了探究与优化.结果表明,本文采用的蛋白质定量方法准确度高(R²=0.9999),确立了17 cm, pH4～7的IPG胶条, 12% SDS-PAGE分离胶,上样量为900 μg的双向电泳方法体系,获得了最适合本研究蛋白质组分析的双向电泳图谱. 经PDQuest 2DE 8.0.1软件分析,2-DE图谱上可分辨出1.444±14个清晰蛋白质点,且重复性较高(95%), 相关系数为0.960. 建立了一套适用于显性多子房小麦细胞质效应研究的蛋白质双向电泳体系.     

建立和优化双向电泳分析柱花草根系蛋白谱的方法

本研究以柱花草根系为材料,比较了不同蛋白质提取方法和蛋白上样量等因素对双向电泳方法分析根系蛋白图谱的影响。结果表明,在苯酚法提取蛋白中,加入0.7mol·L-1NaCl和20%乙醇,并在蛋白沉淀过程中加入1/10倍体积5mol·L-1NaCl,能够有效去除组织样品中的非蛋白成分,结合使用pH4～7范围的IPG胶条,1mg根系蛋白可以在双向电泳图谱上分辨出较多蛋白点,图谱背景清晰,该体系适合柱花草根系蛋白质的双向电泳分析。     

蒙古沙冬青叶蛋白质双向电泳体系的建立和优化

开展蒙古沙冬青叶组织的蛋白质组学研究,需要建立和优化叶的蛋白质组双向电泳体系。本研究以蒙古沙冬青(Ammopiptanthus mongolicus)叶片为材料,比较了不同总蛋白提取方法(TCA-丙酮法和Tris-饱和酚法)、不同染色方法(考马斯亮蓝染色和硝酸银染色)和不同蛋白质上样量对双向凝胶电泳蛋白质得率和等电聚焦效果的影响。结果显示,采用TCA-丙酮法提取蒙古沙冬青叶片总蛋白,蛋白质上样量500μg,以硝酸银染色SDS-PAGE胶,双向电泳的分辨率最高,图谱清晰。该方法的建立为开展蒙古沙冬青叶片蛋白质组定量和定性分析奠定了基础。     

家蚕蛹期雌雄生殖腺蛋白质双向电泳比较分析

分析家蚕Bombyx mori雌雄生殖腺细胞蛋白质,有利于发现性别分化相关的功能蛋白质,探讨生殖腺发育相关基因的表达调控机理。本研究利用蛋白质双向凝胶电泳和图像分析技术,分析家蚕蛹期第2天的雌雄生殖腺细胞蛋白质。结果表明: 在雄蚕生殖腺蛋白质电泳图谱中共检测到435个蛋白斑点,其中特异性蛋白斑点73个,占总蛋白斑点数的16.8％;雌蚕生殖腺的电泳图谱中有417个蛋白斑点,其中特异性蛋白斑点55个,占总蛋白斑点数的13.2％。雌雄能匹配的蛋白斑点有362对,匹配率达85.0％。     

适用于盐生植物的双向电泳样品制备方法

比较了三氯乙酸,丙酮沉淀法（TCA）、三氯乙酸沉淀法（E-TCA）和酚抽法（Phe）3种方法对盐生植物盐角草（Salicornia europaea L．）总蛋白的提取效果。3种方法分别得到579、343和535个蛋白点;TCA和E-TCA法所得图谱均存在严重的横向纹理,Phe法所得图谱则背景干净,基本上没有纹理。说明Phe法不仅能很好地提取盐角草蛋白,而且能有效去除样品中的盐分。对Phe法的提取液进行了改进,所得图谱背景更加清晰,蛋白点数增加。为其他盐生植物以及嗜盐微生物蛋白质的提取提供了重要参考。     

西花蓟马蛋白的提取及双向电泳体系的建立

【目的】蛋白样品的制备是获得良好双向凝胶电泳(2-DE)图谱的前提,建立合理的西花蓟马蛋白的双向电泳体系,获得分辨率较高、重复性较好的图谱,能够为后续的研究提供有力支撑。【方法】实验以西花蓟马成虫为实验材料,对比了饱和酚法、TCA/丙酮法和直接裂解法3种蛋白提取方法,从中选出最适宜双向电泳分析的一种蛋白提取方法。【结果】3种方法蛋白提取率差异显著,直接裂解法蛋白提取率最高,饱和酚法的蛋白提取率最低;3种方法的SDS-PAGE条带数差异不明显;TCA/丙酮法的双向凝胶图谱效果最好,蛋白点最多。【结论】TCA/丙酮法能够有效去除西花蓟马蛋白中的干扰物质,是最适合西花蓟马双向凝胶电泳的蛋白提取方法,为后续西花蓟马在蛋白组学方面的研究奠定了基础。     

Proteomic study of a model causative agent of harmful red tide,Prorocentrum triestinum I: Optimization of sample preparation methodologies for analyzing with two-dimensional electrophoresis

A comprehensive study to find the optimal sample preparation conditions for two-dimensional electrophoresis (2-DE) analysis of Prorocentrum triestinum, a model causative agent of harmful algal blooms (HABs) was carried out. The four major sample preparation steps for 2-DE: (a) cell disruption: i.e. sonication and homogenization with glass beads; (b) protein extraction : i.e. sequential and independent extraction procedures; (c) pre-electrophoretic treatment: these included (i) treatment with RNAase/DNAase or benzonase; (ii) ultracentrifugation to sediment large macromolecules such as DNA; (iii) desalting and concentration by ultrafiltration through a Microcon centrifugal filter device (MWCO: 3000 daltons); and (iv) desalting by a micro BioSpin chromatography column (MWCO: 6000 daltons); and (d) rehydration buffers, reducing agents and sample application in the first dimension isoelectric focussing were studied. Our results showed that sonication is easy to perform and resulted in a higher protein yield. Among the four extraction buffers, the urea containing buffers resulted in the extraction of the highest amount of protein while tris(hydroxymethyl)aminomethane buffers and trichloroacetic acid (TCA)/acetone precipitation allowed detection of a higher number of protein species (i.e. protein spots). Desalting by BioSpin and ultrafiltration have improved the 2-DE resolution of the water soluble fraction but have less effect on urea containing fractions. TCA/acetone precipitation was able to desalt all protein fractions independent of the extraction media, however extended exposure to this low pH medium has caused protein modification. Introduction of either DNase/RNase or benzonase treatment did not improve the discriminatory power of the 2-DE but this treatment did yield 2-DE with the clearest background. Proteolytic digestion was inhibited by addition of a protease inhibitor cocktail. Taken overall, a combination of sequential extraction and desalting by BioSpin chromatography for sample treatment before first dimension of 2-DE gave best results based on its simplicity and minimal protein loss. Finally, triscarboxyethylphosphine (TCEP) has performed well as a reducing agent in both the rehydration and equilibration buffers. The rehydration buffer found to be best in this study was 8.0 M urea, 2% 3-[(3-cholamidoprphyldimethylamino]-1-propanesulfonate, 4 mM TCEP and 1% immobilized pH gradient buffer. Subsequently, we applied this finding and performed 2-DE analysis on the soluble protein fractions extracted from light-starved cultured algal cells (nonblooming) and cultured cells grown under optimal conditions (blooming). 2-DE maps of these algal cultures were visibly different and many differentially expressed proteins were found.     

适用于黄麻根部蛋白质组学分析的双向电泳技术

以黄麻品种'9511'幼苗为试验材料,研究其根部蛋白提取方法的得率及不同的蛋白样品溶解方法、电泳上样量和IPG胶条pH范围对双向电泳图谱的影响.结果表明:采用三氯乙酸(TCA)/丙酮沉淀法提取黄麻根部蛋白质,蛋白得率为80 mg/g;蛋白粉末溶解采用两次水化法,裂解液中含有7 mol/L尿素、2 mol/L硫脲、4% CHAPS、65 mmol/L DTT、0.2%载体两性电解质和1 mmol/L PMSF,能够较充分地溶解蛋白质,且制备的样品浓度能够满足双向电泳上样要求;上样量为400 μg时得到的图谱分辨率高、蛋白斑点分布均匀、清晰;等电聚焦(Isoelectrofocusing,IEF)采用pH 4～7、17 cm的IPG胶条时所得图谱质量最佳.研究表明,样品的制备及IEF有效除盐对获得理想的2-DE图谱非常关键;取材、染色等细节对2-DE的重复性影响很大.     

不同提取方法及上样量对牡丹试管苗茎基部蛋白双向电泳的影响

为建立一套适合于牡丹试管苗茎基部蛋白的双向电泳技术,以便更好地利用蛋白质组技术研究牡丹试管苗不定根的发生机理,本研究比较了三种不同蛋白质提取方法对双向电泳结果的影响,并在蛋白质上样量方面进行了比较。结果表明,乙酸铵/甲醇酚提取法所得2-DE图谱的蛋白点很少,仅检测到45个,且较模糊,有明显的拖尾现象,分辨率很低;乙醇/乙醚丙酮法所得的蛋白点也较少(101个),较模糊,且横竖纹干扰较大;三氯乙酸/丙酮法所得蛋白点数较多,可检测到434个清晰的蛋白点,且形状规则,重复性好,适合后续分析,操作也较为简便。用三氯乙酸/丙酮法提取蛋白,采用800μg、1000μg和1200μg三个不同的上样量进行双向电泳,在上样量为1200μg时(IPGpH3～10,24cm),蛋白质在12%SDS-PAGE胶上得到了较好的分离,在2-DE图谱上可分辨出562个蛋白点。因此,三氯乙酸/丙酮法是较适合于牡丹试管苗茎基部蛋白质提取的方法,1200μg是较为合适的上样量。     

灵芝子实体原基双向电泳和总蛋白质提取方法的建立

比较了Tris-饱和酚法和三氯乙酸(TCA)/丙酮沉淀法对灵芝子实体原基总蛋白质的提取效果。用Image Master 2D Platinum6.0软件分析两种方法所提蛋白质的双向电泳图谱,分别得到565和273个蛋白质点;(TCA)/丙酮沉淀法在碱性端低分子量区域有些蛋白质斑点存在拖尾现象,Tris-饱和酚法能有效去除样品中的盐分,使蛋白质的聚焦效果更好,蛋白点数增加。Tris-饱和酚法可做为灵芝子实体原基总蛋白质的提取方法并为其他药用真菌总蛋白质的提取提供参考,同时为本实验室后续研究灵芝双向性固体发酵雷公藤的蛋白差异表达奠定了基础。     

箭毒木种子蛋白质样品制备及双向电泳改良方法

建立箭毒木（Antiaris toxicaria）种子总蛋白的提取方法,以及可以对其蛋白质组进行分析的双向电泳条件。通过各种条件的优化与组合,建立了以TCA-丙酮为基础的Tris—HCl提取法提取总蛋白,第1向电泳为固相pH梯度等电聚焦,第2向电泳为垂直平板SDS-PAGE的双向电泳体系。通过对样品制备、样品溶解、等电聚焦电泳、SDS-聚丙烯酰胺凝胶电泳以及染色方法等关键步骤进行分析,获得了满意的双向电泳图谱。在探索适合箭毒木种子蛋白质组学研究双向电泳方法中,比较了三氯乙酸-丙酮沉淀法、和Tris—HCl法,以及对双向电泳过程中的关键步骤的改良,认为Tris—HCl法为最适方法,所得图谱背景清晰,蛋白质信息量最大,为箭毒木属植物的差异蛋白质组学的后续研究打下了坚实的基础。     

A Standard Operating Procedure (SOP) for the preparation of intra- and extracellular proteins of Clostridium acetobutylicum for proteome analysis

We report on the development of a Standard Operating Procedure (SOP) for extraction and handling of intra- and extracellular protein fractions of Clostridium acetobutylicum ATCC 824 for reproducible high quality two-dimensional gel electrophoresis (2-DE) analyses. Standardized cells from a phosphate-limited chemostat were used to evaluate different protein preparation methods. For the preparation of the secretome, a dialysis/ultrafiltration procedure resulted in higher protein yields and proved to be more reliable compared to different precipitation methods using TCA, DOC-TCA, acetone, and PEG 6000. Sonication was found to be the most efficient method among different tested techniques of cell disruption for the analysis of the intracellular proteome. Furthermore, the effect of protease inhibitors and sample storage conditions were tested for both intra- and extracellular protein samples. Significant changes in the protein pattern were observed depending on the addition of protease inhibitors. 2-DE gels with a pH gradient from 4 to 7 prepared according to the developed SOP contained at least 736 intracellular and 324 extracellular protein spots.     

A high-efficiency,two-dimensional gel electrophoresis platform for mature leaves of grass pea (<Emphasis Type="Italic">Lathyrus sativus</Emphasis> L.)

Grass pea (Lathyrus sativus L.) is the most drought-tolerant legume crop rich in dietary protein. However, little is known about the molecular mechanisms of its drought resistance. Two-dimensional gel electrophoresis (2-DE) is an important experiment technique in proteomics, which has been applied extensively in studies on plant resistance to abiotic stress. To establish an effective 2-DE platform and further study the drought-resistance mechanisms of grass pea using proteomic approaches, three protein extraction methods, different isoelectric focusing (IEF) conditions and various types of gel strips were evaluated using mature leaves. The results showed that the trichloroacetic acid (TCA)/acetone protein extraction method, extending time at low voltage for IEF and using 18 cm gel strip with pH 4.0–7.0 were optimum conditions for 2-DE analysis of grass pea leaves. Applying these optimized 2-DE conditions, 1,481 total protein spots were detected in control leaves and 1,346 spots in polyethylene glycol -treated leaves, of which 67 differentially expressed protein spots were obtained relative to the control. These data suggested that an efficient 2-DE platform with high repeatability and resolution for grass pea mature leaves had been established for the first time here, which could be further used to investigate the drought-resistance molecular mechanisms of grass pea.