硝酸纤维膜和丙酮沉淀尿蛋白质保存方法的比较

硝酸纤维膜法是一种简单、快速、经济的尿液蛋白质保存方法,但其与传统尿液蛋白质丙酮沉淀方法的差异有待进一步研究。相同尿液分别经硝酸纤维膜法和丙酮沉淀法制备尿蛋白质,经液相串联质谱分析鉴定蛋白质,采用谱图数定量,研究两种不同方法的差别。结果显示硝酸纤维膜法和丙酮沉淀法鉴定蛋白质数目几乎相同,鉴定蛋白质在谱图数的分布上几乎相同,鉴定蛋白质在蛋白质变异系数的分布上也几乎相同。因此,硝酸纤维膜法处理尿蛋白质与丙酮沉淀法基本一致,可以应用于大规模临床尿液样本的保存。     

6硝酸纤维膜和丙酮沉淀尿蛋白质保存方法的比较

硝酸纤维膜法是一种简单、快速、经济的尿液蛋白质保存方法,但其与传统尿液蛋白质丙酮沉淀方法的差异有待进一步研究。相同尿液分别经硝酸纤维膜法和丙酮沉淀法制备尿蛋白质,经液相串联质谱分析鉴定蛋白质,采用谱图数定量,研究两种不同方法的差别。结果显示硝酸纤维膜法和丙酮沉淀法鉴定蛋白质数目几乎相同,鉴定蛋白质在谱图数的分布上几乎相同,鉴定蛋白质在蛋白质变异系数的分布上也几乎相同。因此,硝酸纤维膜法处理尿蛋白质与丙酮沉淀法基本一致,可以应用于大规模临床尿液样本的保存。     

尿蛋白膜保存法与直接冻存法的成本效益分析

为了比较尿液蛋白PVDF膜富集保存法(尿膜)和尿液直接冻存法两种方法的优缺点。通过比较两种方法在时间、所占空间、费用、蛋白降解程度及大样本临床实践性方面的区别。发现在所占空间、电费方面及临床实践性方面尿膜保存法优于直接冻存法,而在时间及耗材花费方面直接冻存法优于尿膜保存法。因此尿蛋白的尿膜保存法比直接冻存法有更强的实际应用价值。     

胆管癌胆汁蛋白质样品制备和双向电泳条件的优化

采用合适的裂解液和沉淀方法,提取胆管癌胆汁中的蛋白质,获得分辨率高、重复性好的蛋白质双向电泳图谱.通过不同裂解液和蛋白质沉淀方法提取胆汁蛋白的效果比较,设计了不同的样品制备方法,并且对双向电泳(2-DE)的条件进行优化.结果显示,试验确定了适合胆管癌胆汁的裂解液配方(LSⅣ),丙酮沉淀的蛋白分布完整,沉淀效率相对较高.高伏时、长时间的等电聚焦可以获得高分辨率、重复性好的蛋白质双向电泳图谱.因此,本方法可以应用到胆管癌胆汁蛋白的提取,也可以对其他体液蛋白质样品的制备和双向电泳提供借鉴.     

野油菜黄单胞菌分泌组双向电泳样品制备方法的建立

野油菜黄单胞菌野油菜致病变种(Xanthomonas campestris pv.campestris,Xcc)是十字花科植物黑腐病的病原细菌。我们建立了Xcc的蛋白质组学研究平台,用于分离、鉴定该菌的致病相关蛋白。为了减少胞外多糖(exopolysaccharide,EPS)对蛋白材料质量的影响,我们构建了EPS缺陷的Xcc8004ΔgumB突变体。本研究以Xcc8004ΔgumB出发菌株,用诱导培养液培养,取细胞上清通过超滤浓缩得到蛋白质粗提物,分别采用丙酮沉淀法、试剂盒纯化法和丙酮沉淀-试剂盒联用法来纯化蛋白质粗提物,通过比较双向电泳的结果优选最佳的样品制备方法。结果证明丙酮沉淀-试剂盒联用法较为理想,所得双向电泳图片清晰,分辨率高。因此,此方法可以用于制备野油菜黄单胞菌分泌组双向电泳样品,并可以满足进一步研究的需要。     

一种简便经济的薄层凝胶电泳保存方法——滤纸转移自干法

在分析性聚丙烯酰胺凝胶电泳特别是平板等电聚焦电泳中,薄层凝胶越来越被广泛采用,它有节省试剂、加样量少、电泳时间短、分辨率高及冷却效果好等优点。分析者都希望能将电泳染色后的凝胶理想地保存下来,目前所采用的方法均是直接将凝胶干燥在玻璃板或凝胶支持膜上(由于凝胶太薄不能转移),或者使用专用的透明保存膜,有时还要用真空干燥器干燥。     

适于小麦叶片蛋白质组分析的样品提取方法研究

以‘铭贤169'小麦苗期叶片为材料,分别采用传统的TCA/丙酮沉淀法、酚提取-甲醇/醋酸铵沉淀法以及改进的TCA/丙酮沉淀-酚/SDS联合抽提法提取叶片总蛋白,进行双向电泳分离和胶体考染,以建立适用于小麦蛋白质组分析的样品制备方法.结果表明:TCA/丙酮沉淀法较酚提取-甲醇/醋酸铵沉淀法获得的蛋白杂质较少,在二维电泳图谱中的蛋白点较酚抽提-甲醇/醋酸铵沉淀法提取的蛋白点清晰且多.相比于以上2种提取蛋白样品方法,改进的TCA/丙酮沉淀-酚/SDS联合抽提法提取的小麦叶片蛋白杂质少、二维电泳图谱上的点明显增多、分辨率较高.所选小麦的代表性蛋白点能获得成功鉴定.该方法可推广应用于水稻叶片蛋白质组分析的样品提取.     

蚜虫全蛋白提取方法的比较研究

为建立适于SDS-PAGE分析的蚜虫蛋白质样品制备平台,以便为蚜虫蛋白质的双向电泳分析奠定基础,本研究比较了TCA/丙酮沉淀、PEG提取、饱和酚抽提和直接裂解4种蛋白质提取方法.结果表明:不同样品制备方法的蛋白提取率有显著的差异,其中直接裂解法的提取率最高,为17.43 mg/g;其次是饱和酚抽提法,提取率为12.30 mg/g;而PEG制备法提取率最低,只有7.96 mg/g.利用SDS-PAGE电泳对不同的蛋白质样品进行了分析,发现在凝胶图谱上显现的条带也有明显的差异,其中饱和酚抽提法显现的条带数最多,为36条,且从14.4 kDa～116.0 kDa范围有广泛分布,条带清晰;PEG提取法条带数为30条,一些蛋白条带丢失或不明显;TCA/丙酮沉淀法的蛋白条带集中分布在25.0 kDa～67.0 kDa区域;直接裂解法条带数仅为24条,且小分子量的条带可辩率很低.通过以上结果可以得出,饱和酚抽提法最适用于蚜虫全蛋白样品的制备.     

极端嗜酸热古菌Acidianus manzaensis膜蛋白提取方法的建立及应用

以万座嗜酸两面菌(Acidianus manzaensis)为研究对象,探索并优化其膜蛋白提取方法,以优化后的方法提取该菌分别以单质硫(S0)和亚铁(Fe2+)为能源底物进行生长时的膜蛋白质,并进行聚丙烯酰胺凝胶电泳(SDS-PAGE)研究膜蛋白在两种能源底物培养下的表达差异。首先通过80℃水浴60-70 min对A.manzaensis胞外黏附蛋白进行初步分离。其次比较了不同提取剂(Triton X-110,SDS和Triton X-114)对膜蛋白的提取效果,结果表明Triton X-114的提取效果较好,其最佳浓度为10%(w/v);比较了不同沉淀剂(三氯乙酸(TCA),丙酮,三氯乙酸/丙酮,甲醇和乙醇)对膜蛋白质沉淀的效果,结果表明TCA/丙酮的沉淀效果最不理想,会导致沉淀后低分子量蛋白发生缺失,而其他几种没有明显差别,综合比较选择较常用的丙酮作为膜蛋白提取的沉淀剂。最后基于优化后膜蛋白提取方法,分别对S0和Fe2+培养的A.manzaensis膜蛋白质进行提取及SDS-PAGE,结果发现分子量为35.6 k D和16.9 k D的蛋白只在A.manzaensis以S0生长时出现,表明这些蛋白质很可能在A.manzaensis硫氧化中发挥了重要作用;分子量为72 k D和26 k D的蛋白质在A.manzaensis以Fe2+生长时比其以S0生长时显著表达上调,表明此蛋白可能与A.manzaensis铁氧化相关。     

汾酒大曲宏蛋白质组的制备与双向电泳技术的建立

采用TCA-丙酮沉淀法、丙酮沉淀、硫酸铵等沉淀法制备汾酒大曲的宏蛋白组样品,并用双向电泳来检测制备效果,结果表明：TCA-丙酮沉淀法制备的样品经电泳分离后,减轻了杂质干扰,其2-DE图谱中竖条纹干扰较少,且获得的蛋白点形状规则、清晰且无明显重叠现象,优于其它两种方法;经过两次水化液溶解的蛋白样品在等电聚焦时能保持4000 V较高电压;上样量为300μg左右的粗蛋白溶于二次水化液能得到点数更多、分辨率高的电泳图谱。建立了汾酒大曲宏蛋白质组的双向电泳体系,为汾酒品质研究奠定基础。     

A two-step procedure for efficient electrotransfer of both high-molecular-weight (greater than 400,000) and low-molecular-weight (less than 20,000) proteins

We have developed conditions for the efficient electrotransfer from polyacrylamide gels to nitrocellulose sheets of a broad size range of proteins (Mr 8,000 to Mr greater than 400,000). The important features of this procedure include a two-step electrotransfer, beginning with elution of low-molecular-weight polypeptides at a low current density (approximately 1 mA/cm2) for 1 h, followed by prolonged electrotransfer (16-20 h) at high current density (approximately 3.5-7.5 mA/cm2) in conditions that favor the elution of high-molecular-weight proteins. The transfer buffer includes 0.01% sodium dodecyl sulfate to enhance protein elution, and 20% methanol to improve the retention of proteins on the nitrocellulose sheet. The nitrocellulose is air-dried after transfer is complete to eliminate loss of proteins during subsequent processing. This transfer procedure works well with proteins prepared from many different cell types, and is suitable for use with all polyacrylamide gel systems tested. With little or no modification, our method should also be applicable to transfer membranes other than nitrocellulose.     

Preparative elution of proteins from nitrocellulose membranes after separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis

Various conditions were analyzed and optimized for the preparative elution of proteins from nitrocellulose membranes after transfer from sodium dodecyl sulfate (SDS)-polyacrylamide gels. The efficiency of elution was best using pyridine or acetonitrile elution solvents, intermediate for buffer containing a mixture of sodium dodecyl sulfate, Triton X-100, and sodium deoxycholate, and negligible for buffers containing any single detergent or chaotropic salt, such as urea or guanidine hydrochloride. The efficiency of elution with any solvent also depended on the molecular weight of the proteins, smaller proteins being more easily removed from membranes. As a general procedure, proteins may be eluted from nitrocellulose membranes by incubation with either 40% acetonitrile or 50% pyridine in 0.1 M ammonium acetate, pH 8.9, for 1-3 h at 5-37 degrees C. The recommended procedures for protein elution appear to offer a rapid, simple, and efficient means of recovering proteins from complex mixtures after separation by SDS-PAGE and transfer to nitrocellulose membranes.     

Electrophoretic transfer of proteins from sodium dodecyl sulfate-polyacrylamide gels to a positively charged membrane filter

Zeta-bind, a positively charged nylon membrane, was tested as an immobilizing matrix for the electrophoretic transfer of proteins from sodium dodecyl sulfate-polyacrylamide gels. It was found that Zeta-bind has a considerably greater capacity than does nitrocellulose for protein binding. Because of this property, more efficient elution of proteins from gels can be used (by omitting methanol from transfer buffers). The procedure described is more amenable to quantitation than usual nitrocellulose-based transfer. Antibody or lectin overlay techniques are also more sensitive on Zeta-bind than on nitrocellulose.     

High Yield Elution of Proteins from Sodium Dodecyl Sulfate–Polyacrylamide Gels at the Low-Picomole Level. Application to N-Terminal Sequencing of a Scarce Protein and to In-Solution Biological Activity Analysis of On-Gel Renatured Proteins

A simple, reliable procedure for practically quantitative (90–98%) and fast (<30 min) elution of proteins from SDS-PA gels is described with reproducible recoveries in the range from 100 to 1 pmol per band, which does not require the inclusion of detergents in the elution buffer. It consists in the combination of (1) highly sensitive on-gel protein detection (50 mol per band) with imidazole-SDS-zinc (reverse staining), (2) crushing of the protein band to produce 32-m gel particles, and (3) vortexing of the slurry in a solution of a zinc-complexing agent, e.g. glycine 0.5 M or EDTA 100 mM (100 l for a 100-pmol BSA band), at room temperature. Eluted proteins can be directly analyzed by RP-HPLC, quantitatively loaded onto a PVDF membrane, or, provided that they are previously renatured on-gel, analyzed by biological activity tests. The application of the procedure to in-solution enrichment of scarce proteins for N-terminal analysis is shown.     

Purification of commercial preparations of NADP+ from AMP contamination

A method for purification of commercial preparations of NADP+ from AMP contamination is described. The purification procedure includes one-step anion-exchange chromatography on Dowex-1 (formate) and results in a highly purified salt-free coenzyme with a yield of 70-80%. The chromatography conditions have been selected allowing for complete separation of AMP from NADP+ in a HCOOH concentration gradient. This is followed by NADP+ elution with 1.5 M HCOOH containing HCOOK at a concentration at which the salt remains in solution during subsequent precipitation and washing of NADP+ with acetone. An addition of HCOOK is necessary to reduce the coenzyme elution volume that is important for further precipitation of NADP+ with acetone.     

Membrane‐Based SDS Depletion Ahead of Peptide and Protein Analysis by Mass Spectrometry

SDS interferes with both bottom‐up and top‐down MS analysis, requiring removal prior to detection. Filter‐aided sample preparation (FASP) is favored for bottom‐up proteomics (BUP) while acetone precipitation is popular for top‐down proteomics (TDP). We recently demonstrated acetone precipitation in a membrane filter cartridge. Alternatively, our automated electrophoretic device, termed transmembrane electrophoresis (TME), depletes SDS for both TDP and BUP studies. Here TME is compared to these two alternative methods of SDS depletion in both BUP and TDP workflows. To do so, a modified FASP method is described applicable to the SDS purification and recovery of intact proteins, suitable for LC/MS. All three methods reliably deplete >99.8% SDS. TME provide higher sample yields (average 90%) than FASP (55%) or acetone precipitation (57%), translating into higher total protein identifications (973 vs 877 FASP or 890 acetone) and higher spectral matches (2.5 times) per protein. In a top down workflow, each SDS‐depletion method yields high‐quality MS spectra for intact proteins. These results show each of these membrane‐based strategies is capable of depleting SDS with high sample recovery and high spectra quality for both BUP and TDP studies.     

Staining of proteins on SDS polyacrylamide gels and on nitrocellulose membranes by Alta, a colour used as a cosmetic

We describe here the use of Alta, a pre-existing scarlet-red stain of cosmetic use, for staining proteins on sodium dodecyl sulfate (SDS) polyacrylamide gels, as well as for a single step staining of gels and nitrocellulose membranes during Western blot analysis. This stain, which is composed of 0.8% Crocein scarlet (brilliant crocein) and 0.2% Rhodamine B, is inexpensive, easy to use and nearly as sensitive as Coomassie Brilliant Blue (CBB) R-250. The gels can be stained in 10% Alta (2 h) and can be destained effectively only with 7% acetic acid as opposed to the conventional destainer (methanol/acetic acid/water) required for CBB-stained gels. In an alternative procedure, the proteins can be stained on the gel while electrophoresis by simply using 5% Alta in the top tank buffer and the stain can be viewed under UV-transilluminator. This procedure can also be used for Western blot analysis, as a single step procedure for staining of proteins on the gel as well as on the nitrocellulose membrane, as the stain is retained on the membrane after protein transfer. Thus, this staining procedure allows monitoring of proteins after each step in the Western blot, thereby eliminating the need to run separate gels for staining and Western blot analysis, and also the need for Ponceau Red S staining of the nitrocellulose membrane during Western blot analysis.     

Enrichment and identification of integral membrane proteins from barley aleurone layers by reversed-phase chromatography, SDS-PAGE, and LC-MS/MS

The plasma membrane of the cereal aleurone layer is the site of perception of germination signals and release of enzymes to the starchy endosperm. Analysis of membrane proteins is challenging due to their hydrophobicity and low abundance; thus, little is known about the membrane proteins involved in seed germination. A membrane fraction highly enriched for the plasma membrane H+-ATPase was prepared from barley aleurone layers by aqueous two-phase partitioning. Because detergent and salt washes did not efficiently remove soluble proteins from the membrane preparations, an alternative procedure was developed, comprising batch reversed-phase chromatography with stepwise elution of hydrophobic proteins by 2-propanol. Proteins in the most hydrophobic fraction were separated by SDS-PAGE and identified by LC-MS/MS and barley EST sequence database search. The method was efficient for enrichment of integral membrane proteins with relatively low levels of soluble contaminating proteins. Forty-six proteins associated with barley aleurone plasma membranes were identified, including proteins with more than 10 transmembrane domains. Among the identified proteins were two new isoforms of the plasma membrane H+-ATPase, two proteins possibly involved in ion-channel regulation, and two proteins of unknown function. This represents the first analysis of membrane proteins involved in seed germination using a proteomics approach.