Protein extraction from the earthworm Eisenia fetida for 2‐DE

We identified an efficient protocol for extracting proteins from whole earthworm, Eisenia fetida, for 2‐DE. Sample preparation is a critical step in a 2‐DE proteome approach and is absolutely essential for obtaining good results. Six protein extraction protocols based on different protein precipitation agents were tested and evaluated using 2‐DE. The methods generated remarkably different 2‐DE protein spot patterns. We conclude that trichloroacetic acid (TCA)‐A eliminates interfering compounds, thus allowing for the efficient resolubilization of proteins. TCA‐A gives good distinction, more bands in 1‐DE gels, and the most number of protein spots in 2‐DE gels. It is also rapid, provides the higher protein yield, and has the less number of steps. To demonstrate the quality of the extracted proteins, we cut several protein spots that were common to four methods from 2‐DE gels, analyzed them using MALDI‐TOF/TOF MS, and tentatively identified them. The classic TCA‐A method proved to be most useful as a standard method of extracting proteins from E. fetida.     

PROTEOMICS OF THE RED ALGA,GRACILARIA CHANGII (GRACILARIALES,RHODOPHYTA)1

The application of proteomics in alga research is still quite limited. The present report describes the establishment of the proteome of a red alga of economic importance, Gracilaria changii (Xia et Abbott) Abbott, Zhang et Xia. Initially, four protein extraction methods including direct precipitation by trichloroacetic acid/acetone, direct lysis using urea buffer, Tris buffer, and phenol/chloroform extraction were compared for their suitability to generate G. changii proteins for two‐dimensional gel electrophoresis (2‐DE). The phenol/chloroform protein extraction method gave the best 2‐DE resolution of the proteins. Using these 2‐DE gels and mass spectrometry, several proteins including pigment proteins, metabolic enzymes, and ion transporters were identified. These findings highlight the potential of using proteomic approaches for the investigation of G. changii protein function.     

Optimization of a phenol extraction‐based protein preparation method amenable to downstream 2DE and MALDI‐MS based analysis of bacterial proteomes

2DE is one of the most efficient and widely used methods for resolving complex protein mixtures. For efficient analysis of complex samples, high‐resolution separation of proteins on 2D gel is essential, and for that purpose good sample preparation is crucial. In this study, we have improvized a method for preparing bacterial total cellular proteome, from a strategy applied earlier to recalcitrant plant tissues, which gave high‐quality resolution on 2DE. The method involving phenol extraction followed by methanol/ammonium acetate precipitation was first optimized for the chemolithotrophic proteobacteria Tetrathiobacter kashmirensis WT001 and Pseudaminobacter salicylatoxidans KCT001 that did not yield quality protein preps in conventional trichloroacetic acid/acetone precipitation method. Subsequently, to validate its general applicability, the method was evaluated against the trichloroacetic acid/acetone precipitation method for two other model bacteria, i.e. Escherichia coli DH5α and Mycobacterium smegmatis mc²6. Identification of at least four proteins each from the outer membrane, periplasm, and cytoplasm of T. kashmirensis by MALDI‐MS not only proved the efficiency of the method in extracting proteins from the different cellular compartments but also the amenability of the obtained protein spots toward MALDI‐MS based identification.     

Comparative studies of four protein preparation methods for proteomic study of the dinoflagellate Alexandrium sp. using two-dimensional electrophoresis

Alexandrium is a wide-spread genus of dinoflagellate causing harmful algal blooms and paralytic shellfish poisoning around the world. Proteomics has been introduced to the study of Alexandrium, but the protein preparation method is still unsatisfactory with respect to protein spot number, separation and resolution, and this has limited the application of a proteomic approach to the study of dinoflagellates. In this study we compared four protein preparation methods for the two-dimensional electrophoresis (2DE) analysis of A. tamarense: (1) urea/Triton X-100 buffer extraction with trichloroacetic acid (TCA)/acetone precipitation; (2) direct precipitation with TCA/acetone; (3) 40 mM Tris (hydroxymethyl) aminomethane (Tris) buffer extraction; and (4) 50 mM Tris/5% glycerol buffer extraction. The results showed that, among the four protein preparation methods, the method combining the urea/Triton X-100 buffer extraction and TCA/acetone precipitation allowed detection of the highest number and quality of protein spots with a clear background. Although the direct TCA/acetone precipitation method also detected a high number of protein spots with a clear background, the spot number, separation and intensity were not as good as those obtained from the urea/Triton X-100 buffer extraction with TCA/acetone precipitation method. The 40 mM Tris buffer and 50 mM Tris/5% glycerol buffer methods allowed the detection of fewer protein spots and a pH range only from 4 to 7. Subsequently, the urea/Triton X-100 buffer extraction with TCA/acetone precipitation method was successfully applied to profiling protein expression in A. catenella under light stress conditions and the differential expression proteins were identified using MALDI TOF–TOF mass spectrometry. The method developed here appears to be promising for further proteomic studies of this organism and related species.     

Protein extraction from plant tissues for 2DE and its application in proteomic analysis

Plant tissues contain large amounts of secondary compounds that significantly interfere with protein extraction and 2DE analysis. Thus, sample preparation is a crucial step prior to 2DE in plant proteomics. This tutorial highlights the guidelines that need to be followed to perform an adequate total protein extraction before 2DE in plant proteomics. We briefly describe the history, development, and feature of major sample preparation methods for the 2DE analysis of plant tissues, that is, trichloroacetic acid/acetone precipitation and phenol extraction. We introduce the interfering compounds in plant tissues and the general guidelines for tissue disruption, protein precipitation and resolubilization. We describe in details the advantages, limitations, and application of the trichloroacetic acid/acetone precipitation and phenol extraction methods to enable the readers to select the appropriate method for a specific species, tissue, or cell type. The current applications of the sample preparation methods in plant proteomics in the literature are analyzed. A comparative proteomic analysis between male and female plants of Pistacia chinensis is used as an example to represent the sample preparation methodology in 2DE‐based proteomics. Finally, the current limitations and future development of these sample preparation methods are discussed. This Tutorial is part of the International Proteomics Tutorial Programme (IPTP17).     

Evaluation of two-dimensional difference gel electrophoresis for protein profiling. Soluble proteins of the marine bacterium Pirellula sp. strain 1

Two-dimensional gel electrophoresis (2DE) is a central tool of proteome research, since it allows separation of complex protein mixtures at highest resolution. Quantification of gene expression at the protein level requires sensitive visualization of protein spots over a wide linear range. Two-dimensional difference gel electrophoresis (2D DIGE) is a new fluorescent technique for protein labeling in 2DE gels. Proteins are labeled prior to electrophoresis with fluorescent CyDyes trade mark and differently labeled samples are then co-separated on the same 2DE gel. We evaluated 2D DIGE for detection and quantification of proteins specific for glucose or N-acetylglucosamine metabolism in the marine bacterium Pirellula sp. strain 1. The experiment was based on 10 parallel 2DE gels. Detection and comparison of the protein spots were performed with the DeCyder trade mark software that uses an internal standard to quantify differences in protein abundance with high statistical confidence; 24 proteins differing in abundance by a factor of at least 1.5 (t test value <10(-9)) were identified. For comparison, another experiment was carried out with four SYPRO-Ruby-stained 2DE gels for each of the two growth conditions; image analysis was done with the ImageMaster trade mark 2D Elite software. Sensitivity of the CyDye fluors was evaluated by comparing Cy2, Cy3, Cy5, SYPRO Ruby, silver, and colloidal Coomassie staining. Three replicate gels, each loaded with 50 microg of protein, were run for each stain and the gels were analyzed with the ImageMaster software. Labeling with CyDyes allowed detection of almost as many protein spots as staining with silver or SYPRO Ruby.     

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。     

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。     

Proteomic approach to probe for larval proteins of the mussel Mytilus galloprovincialis

A proteomic approach was used to search for larval proteins specific to the mussel Mytilus galloprovincialis from Galicia in northwest Spain. The study included both a comparative analysis, through two-dimensional electrophoresis, of protein expression maps of the larvae of the mussel and of 5 abundant and commercially important bivalve species from the region (Ostrea edulis, Cerastoderma edule, Pecten maximus, Tapes decussatus, and Venarupis pullastra) and subsequent mass spectrometric analysis of some of the protein spots. A total of 18 spots were selected and isolated from gels of M. galloprovincialis larvae. From their relative position on the electrophoresis gels, 6 of these were clearly exclusive to the mussel species. However, it was not clear whether the other spots were shared by other species. To overcome this ambiguity, first an analysis using matrix assisted laser desorption ionization with time-of-flight (MALDI-TOF) was conducted on the 6 spots of Mytilus that could possibly be shared with only one species. The peptide mass fingerprinting was completely different for the proteins compared. This result confirmed that the 6 proteins were exclusively mussel proteins, but demonstrated the utility of this approach when working with species that are poorly represented at the protein level in databases.     

Protein Extraction From Leaves of Aloe vera L., A Succulent and Recalcitrant Plant, for Proteomic Analysis

An improved method for extracting proteins from leaf tissues of Aloe vera L., a recalcitrant plant species, for proteomic analysis is presented. In this protocol, the following critical components are included. A washing step is added prior to homogenization of the tissue to eliminate contaminants, and a concentrated 2× extraction buffer (pH 7.5) is used to increase protein yield. Compared to classical trichloroacetic acid–acetone and phenol extraction methods, this novel protocol has yielded two-dimensional electrophoresis gels with minimal (if any) streaking and provided high-quality protein samples. This protocol is expected to be applicable to other recalcitrant plant tissues.     

Evaluation of sample preparation methods for the analysis of papaya leaf proteins through two‐dimensional gel electrophoresis

Introduction – A variety of sample preparation protocols for plant proteomic analysis using two‐dimensional gel electrophoresis (2‐DE) have been reported. However, they usually have to be adapted and further optimised for the analysis of plant species not previously studied. Objective – This work aimed to evaluate different sample preparation protocols for analysing Carica papaya L. leaf proteins through 2‐DE. Methodology – Four sample preparation methods were tested: (1) phenol extraction and methanol–ammonium acetate precipitation; (2) no precipitation fractionation; and the traditional trichloroacetic acid–acetone precipitation either (3) with or (4) without protein fractionation. The samples were analysed for their compatibility with SDS–PAGE (1‐DE) and 2‐DE. Fifteen selected protein spots were trypsinised and analysed by matrix‐assisted laser desorption/ionisation time‐of‐flight tandem mass spectrometry (MALDI‐TOF‐MS/MS), followed by a protein search using the NCBInr database to accurately identify all proteins. Results – Methods number 3 and 4 resulted in large quantities of protein with good 1‐DE separation and were chosen for 2‐DE analysis. However, only the TCA method without fractionation (no. 4) proved to be useful. Spot number and resolution advances were achieved, which included having an additional solubilisation step in the conventional TCA method. Moreover, most of the theoretical and experimental protein molecular weight and pI data had similar values, suggesting good focusing and, most importantly, limited protein degradation. Conclusion – The described sample preparation method allows the proteomic analysis of papaya leaves by 2‐DE and mass spectrometry (MALDI‐TOF‐MS/MS). The methods presented can be a starting point for the optimisation of sample preparation protocols for other plant species. Copyright © 2009 John Wiley & Sons, Ltd.     

Proteomic analysis of the development and germination of date palm (Phoenix dactylifera L.) zygotic embryos

By using a comparative proteomic approach (2‐DE coupled to MS/MS), the development, maturation, and germination of date palm zygotic embryos, have been studied. Proteins were trichloroacetic acid (TCA)–acetone–phenol extracted and resolved by 2‐DE in the 5–8 pH range. The total protein content and the number of spots resolved increased from early (12 weeks after pollination (WAP); 68.96 mg/g DW: 207 spots) to late (17 WAP; 240.85 mg/g DW: 261 spots) stages, decreasing upon germination (from 120.8 mg/g DW: 273 spots in mature embryos to 26.35 mg/g DW: 87 spots in 15 days after germination). Up to 194 spots showed qualitative or quantitative differences between stages. Statistical analysis of spot variation was performed by PCA, obtaining a more accurate grouping of the samples and determining the most discriminant spots. Samples were also clustered based on Pearson distance and Ward's minimum distance. Sixty‐five variable spots were subjected to MS analysis, resulting in 21 identifications. The identified proteins belong to the following functional categories: enzymes of glycolysis, tricarboxylic acid cycle, and carbohydrate biosynthesis, protein translation, storage (glutelin), and stress‐related proteins. The evolution pattern of the functional groups was examined and discussed in terms of metabolism adaptation to the different embryogenic and germination stages.     

Protein extraction/solubilization protocol for monocot and dicot plant gel-based proteomics

Sample preparation in plant proteomics is tedious, requiring modifications depending on the type of tissue involved. Here, we describe a protein extraction protocol for both monocotyledonous (monocot) and dicotyledonous (dicot) species, which significantly improves the solubilization of total proteins. For example, we used the primary leaf tissue and seeds from rice, a cereal crop and genome model system. Total protein was first precipitated with trichloroacetic acid/acetone extraction buffer (TCAAEB) and subsequently solubilized with a modified O’Farrell lysis buffer (LB) containing thiourea and tris (LB-TT). Separation of total leaf proteins by two-dimensional gel electrophoresis (2-DGE) revealed improved solubilization, as determined by an increased number of spots detected with Coomassie brilliant blue (CBB) staining. In addition, the resolution was better than when LB-TT was used alone for protein extraction. Seed proteins could be extracted in LB-TT itself without the need for TCAAEB, which resulted in a highly insoluble precipitate. Our CBB-stained 2-D gel protein profiles also demonstrated the efficacy of this protocol for total protein extraction/solubilization from the dicot genome model (Arabidopsis), a dicot disease model (cucumber), and two other important monocot cereal crop models (maize and wheat). Moreover, this is the first report on generating a 2-D gel proteome profile for wheat crown and cucumber leaf tissues. Finally, as examples of proteome reference maps, we obtained silver nitrate-stained, large-format 2-D gels for rice leaf and wheat crown LB-TT solubilized proteins.     

Sources of Variability among Replicate Samples Separated by Two-Dimensional Gel Electrophoresis

Two-dimensional gel electrophoresis (2DE) offers high-resolution separation for intact proteins. However, variability in the appearance of spots can limit the ability to identify true differences between conditions. Variability can occur at a number of levels. Individual samples can differ because of biological variability. Technical variability can occur during protein extraction, processing, or storage. Another potential source of variability occurs during analysis of the gels and is not a result of any of the causes of variability named above. We performed a study designed to focus only on the variability caused by analysis. We separated three aliquots of rat left ventricle and analyzed differences in protein abundance on the replicate 2D gels. As the samples loaded on each gel were identical, differences in protein abundance are caused by variability in separation or interpretation of the gels. Protein spots were compared across gels by quantile values to determine differences. Fourteen percent of spots had a maximum difference in intensity of 0.4 quantile values or more between replicates. We then looked individually at the spots to determine the cause of differences between the measured intensities. Reasons for differences were: failure to identify a spot (59%), differences in spot boundaries (13%), difference in the peak height (6%), and a combination of these factors (21). This study demonstrates that spot identification and characterization make major contributions to variability seen with 2DE. Methods to highlight why measured protein spot abundance is different could reduce these errors.     

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.     

Optimising the Use of TRIzol-extracted Proteins in Surface Enhanced Laser Desorption/ Ionization (SELDI) Analysis

Background  

Research with clinical specimens is always hampered by the limited availability of relevant samples, necessitating the use of a single sample for multiple assays. TRIzol is a common reagent for RNA extraction, but DNA and protein fractions can also be used for other studies. However, little is known about using TRIzol-extracted proteins in proteomic research, partly because proteins extracted from TRIzol are very resistant to solubilization.     

Proteomic characterization of seeds from yellow lupin (Lupinus luteus L.)

Yellow lupin (Lupinus luteus L.) is a legume crop containing a large amount of protein in its seeds. In this study, we constructed a seed‐protein catalog to provide a foundation for further study of the seeds. A total of 736 proteins were identified in 341 2DE spots by nano‐LC‐MS/MS. Eight storage proteins were found as multiple spots in the 2DE gels. The 736 proteins correspond to 152 unique proteins as shown by UniRef50 clustering. Sixty‐seven of the 152 proteins were associated with KEGG‐defined pathways. Of the remaining proteins, 57 were classified according to a GO term. The functions of the remaining 28 proteins have yet to be determined. This is the first yellow lupin seed–protein catalog, and it contains considerably more data than previously reported for white lupin (L. albus L.).     

Preliminary analysis of the cauliflower mitochondrial proteome

Purified cauliflower (Brassica oleracea var. botrytis) mitochondrial proteins fractionated into soluble, membrane, integral membrane and peripheral membrane samples were analyzed by 2D- PAGE (isoelectric focusing/ SDS polyacrylamide gel electrophoresis). 2D gels patterns were compared using the Imager Master 2D Elite software. 561 silver stained protein spots were resolved after electrophoresis under standard conditions of a whole protein extract. In the soluble fraction a prevalent number of more intense protein spots was observed. The cauliflower protein 2D patterns resembled Arabidopsis thaliana 2D patterns. The two protein spots selected which occupied a similar isoelectric point positions on both gels represented the same proteins as revealed by ESI-MS analysis of cauliflower proteins. The third selected spot belongs to unidentified proteins. The comparative analysis of mitochondrial suborganellar fractions proved the usefulness of this approach.     

DMSO, an Organic Cleanup Solvent for TCA/Acetone-Precipitated Proteins, Improves 2-DE Protein Analysis of Rice Roots

Protein extraction is a critical step in a two-dimensional electrophoresis (2-DE)-based proteomic analysis. Dimethyl sulfoxide (DMSO), a small organic molecule, is widely used as a solvent in biological sciences. In this study, we modified the cleanup step of the commonly used trichloroacetic acid (TCA)/acetone method of protein extraction by using 20?% DMSO/acetone as a solvent to wash TCA?Cacetone-precipitated pellets. The improved protocol (TCA/acetone?CDMSO) was compared with the TCA/acetone and phenol extraction method based on the protein yield, the number of spots, and resolution on 2-DE maps. TCA/acetone?CDMSO washing increased protein yield, and improved the resolution in 2-DE with less background, streaking, and smearing. This method also produced the highest number of protein spots. To our knowledge, the present study is the first to use DMSO as a cleanup solvent for TCA/acetone-precipitated proteins to enhance their quality prior to 2-DE.