Organic disulfides as a means to generate streak-free two-dimensional maps with narrow range basic immobilized pH gradient strips as first dimension

Streaking is a severe problem when narrow range basic immobilized pH gradient strips are used as the first dimension of two-dimensional (2-D) electrophoresis. It is demonstrated that this cysteinyl related streaking is eliminated when focusing is done in the presence of hydroxyethyl disulfide (DeStreak). Use of DeStreak also results in 2-D maps with simplified spot patterns and improved reproducibility.     

Optimization of IPG strip equilibration for the basic membrane protein mABC1

Many proteins with extreme physical properties, including basic and acidic proteins, membrane proteins, and very large proteins, present specific challenges to 2-DE separation. Using a pressure-blotting approach, we demonstrate that a basic integral membrane protein, mitochondrial ATP-binding cassette protein 1 (mABC1), focuses in the IPG strip, but fails to enter into the 2-D SDS-PAGE gel. Through modifying the equilibration conditions between the IPG strip and 2nd dimension, we demonstrate that only by increasing both the volume (from 3 to 6 mL for a 7-cm strip) and SDS concentration (from 2 to 10%) of the equilibration buffer is migration of mABC1 into the 2nd dimension achieved. While 2-DE remains one of the core separation technologies of proteomic analysis, proteins that are extremely basic, hydrophobic, or of large mass present significant challenges to 2-DE separation due to aggregation, oxidation, precipitation, and the physical limitations of the 1-D IPG strip. Since the advent of commercially available IPG strips, numerous groups have experimented with IEF conditions using various detergents alone or in combination, alternative denaturants, and thiol oxidation agents to improve protein focusing. Effective 2-DE separation of membrane proteins has been affected dramatically by these advances in protein solubilization, as well as improvements in isolation of membranes, delipidation, and active in-gel rehydration. Since the development of commercially available basic IPG strips, the most significant advance in the separation of basic proteins has been the introduction of hydroxyethyldisulfides, either alone or in combination with DTT. While hydrophobic proteins were once virtually absent from the 2-D gel, and basic proteins were only visible as dense streaks, now many groups are undertaking large-scale analyses of membranes and basic proteins. Using this base of experimental tools, we embarked on a proteomic analysis of cardiac mitochondrial membranes, hoping to combine the knowledge gained from ongoing targeted protein chemistry and molecular biology studies with a broader-based proteomic analysis. Of particular interest is the inner mitochondrial membrane protein mABC1 (mitochondrial ATP-binding cassette protein 1), which may play a significant role in cardioprotection as part of the mitochondrial ATP-sensitive potassium channels. Therefore, in designing our 2-DE approach, it was crucial to ensure that mABC1 is focused, observable, and quantifiable, despite being an integral membrane protein of pI 9.37.     

Proteome resolution by two-dimensional gel electrophoresis varies with the commercial source of IPG strips

By facilitating reproducible first dimension separations, commercial immobilized pH gradient (IPG) strips enable high throughput and high-resolution proteomic analyses using two-dimensional gel electrophoresis (2DE). Amersham, Biorad, Invitrogen, and Sigma all market linear pH 3-10 IPG strips. We have applied optimized 2DE protocols with both membrane and soluble brain protein extracts to critically evaluate all four products. Resolved protein spots were quantitatively evaluated after carrying out these protocols using IPG strips from the four companies. Biorad and Amersham IPG strips resolved a high number of membrane and soluble proteins, respectively. Furthermore, Amersham IPG strips eluted the largest amount of protein into the second dimension gels and had the most protein remaining in the strip after 2DE. Biorad and Amersham IPG strips maintained a consistent linear pH 3-10 gradient, whereas those from Invitrogen appeared nonlinear or "compressed" within the central pH region. The gradient range within Sigma IPG strips appeared to be slightly less than pH 3-10, due to one extended pH unit within the gradient. Overall, all four commercially available IPG strips have the ability to resolve both membrane and soluble brain proteomes. The difference is that Amersham and Biorad do so more consistently and with better spot resolution. It appears that the physical/chemical nature of commercially available IPG strips can vary considerably, leading to marked differences in subsequent protein resolution in 2DE. These differences likely reflect variations in the uptake of proteins into the strips, and differences in the focusing and elution of proteins from the first to the second dimension. These differences would appear, in part, to underlie some inter-lab variations in the effective resolution of proteomes.     

Technical updates to basic proteins focalization using IPG strips

ABSTRACT: BACKGROUND: Gel-based proteomic is a popular and versatile method of global protein separation and quantification. However, separation of basic protein still represents technical challenges with recurrent problems of resolution and reproducibility. RESULTS: Three different protocols of protein loading were compared using MCF7 cells proteins. In-gel rehydration, cup-loading and paper-bridge loading were first compared using 6--11 IPG strips, as attempted, in-gel rehydration gave large horizontal steaking; paper-bridge loading displayed an interesting spot resolution, but with a predominant loss of material; cup-loading was selected as the most relevant method, but still needing improvement. Twelve cup-loading protocols were compared with various strip rehydration, and cathodic wick solutions. Destreak appeared as better than DTT for strip rehydration; the use of isopropanol gave no improvement. The best 2DE separation was observed with cathodic wicks filled with rehydration solution complemented with DTT. Paper-bridge loading was finally analyzed using non-limited samples, such as bovine milk. In this case, new spots of basic milk proteins were observed, with or without paper wicks. CONCLUSION: According to this technical study of basic protein focalization with IPG strips, the cup-loading protocol clearly displayed the best resolution and reproducibility: strips were first rehydrated with standard solution, then proteins were cup-loaded with destreak reagent, and focalisation was performed with cathodic wicks filled with rehydration solution and DTT. Paper-bridge loading could be as well used, but preferentially with non-limited samples.     

A quantitative investigation into the losses of proteins at different stages of a two-dimensional gel electrophoresis procedure

We report the results of a systematic investigation to quantify the losses of protein during a well-established two-dimensional polyacrylamide gel electrophoresis (2-DE) procedure. Radioactively labelled proteins ([(14)C]bovine serum albumin and a homogenate prepared from the liver of a rat that had been injected with [(35)S]methionine) were used, and recovery was quantified by digesting pieces of gel in H(2)O(2) and subjecting the digests to liquid scintillation counting. When samples were loaded onto the first dimension immobilised pH gradient strips by in-gel rehydration, recovery of protein from the strips was 44-80% of the amount of protein loaded, depending on the amount of protein in the sample. Most of the unrecovered protein appeared to have adhered to the reswelling tray. Losses during isoelectric focusing (IEF) were much smaller (7-14%), although approximately 2% of the protein appeared to migrate from sample strips to adjacent blank strips in the focussing apparatus. A further 17-24% of the proteins were lost into the buffers during equilibration prior to running in the second dimension. Losses during the second dimension run and subsequent staining with SYPRO Ruby amounted to less than 10%. The overall loss during 2-DE was reduced by approximately 25% when proteins were loaded onto the IEF strips using sample cups instead of by in-gel rehydration. These extensive and variable losses during the 2-DE procedure mean that spot intensities on 2-DE gels cannot be used to derive reliable, quantitative information on the amounts of proteins present in the original sample.     

A combination of immobilised pH gradients improves membrane proteomics

Membrane protein analyses have been notoriously difficult due to hydrophobicity and the general low abundance of these proteins compared to their soluble cytosolic counterparts. Shotgun proteomics has become the preferred method for analyses of membrane proteins, in particular the recent development of peptide immobilized pH gradient isoelectric focusing (IPG-IEF) as the first dimension of two-dimensional shotgun proteomics. Recently, peptide IPG-IEF has been shown to be a valuable shotgun proteomics technique through the use of acidic narrow range IPG strips, which demonstrated that small acidic p I increments are rich in peptides. In this study, we assess the utility of both broad range (BR) (p I 3-10) and narrow range (NR) (p I 3.4-4.9) IPG strips for rat liver membrane protein analyses. Furthermore, the use of these IPG strips was evaluated using label-free quantitation to demonstrate that the identification of a subset of proteins can be improved using NR IPG strips. NR IPG strips provided 2603 protein assignments on average (with 826 integral membrane proteins (IMPs)) compared to BR IPG strips, which provided 2021 protein assignments on average (with 712 IMPs). Nonredundant protein analysis demonstrated that in total from all experiments, 4195 proteins (with 1301 IMPs) could be identified with 1428 of these proteins unique to NR IPG strips with only 636 from BR IPG strips. With the use of label-free quantitation methods, 1659 proteins were used for quantitative comparison of which 319 demonstrated statistically significant increases in normalized spectral abundance factors (NSAF) in NR IPG strips compared to 364 in BR IPG strips. In particular, a selection of six highly hydrophobic transmembrane proteins was observed to increase in NSAF using NR IPG strips. These results provide evidence for the use of alternative pH gradients in combination to improve the shotgun proteomic analysis of the membrane proteome.     

A general method for the extraction of citrus leaf proteins and separation by 2D electrophoresis: a follow up

With the aim of studying differentially expressed proteins as a function of abiotic and biotic stress in citrus plants, we optimized a protocol for the extraction of total leaf proteins and their 2-DE separation using commercially available immobilized pH gradient strips (IPGs) in the first dimension. Critical factors for good reproducibility of citrus leaf protein separation were identified: trichloroacetic acid (TCA)/acetone precipitation after extraction in lysis buffer, sample fractionation on narrow range overlapping IPGs and sample-cup loading at the anodic or cathodic end of the strip. The use of thiourea and a strong detergent (C7BzO) in the solubilization/rehydration buffer, coupled with the increase to 10% of SDS in the equilibration buffer before the second dimension seemed to affect positively the resolution of basic proteins. Using our protocol we resolved about 30 basic proteins on 6.3-8.3 pH range strips. Further, our protocol was successfully applied reproducibly on the analysis of control and salt exposed leaf samples of Citrus reshni Hort. Ex Tan.     

Isoelectric point-based prefractionation of proteins from crude biological samples prior to two-dimensional gel electrophoresis

Two-dimensional gel electrophoresis (2-DE) is used to compare the protein profiles of different crude biological samples. Narrow pH range Immobilized pH Gradient (IPG) strips were designed to increase the resolution of these separations. To take full advantage of IPG strips, the ideal sample should be composed primarily of proteins that have isoelectric point (pI) values within the pH range of the IPG strip. Prefractionation of cell lysates from a human prostate cancer cell line cultured in the presence or absence of epigallocatechin-3-gallate was achieved in fewer than 30 min using an anion-exchange resin and two expressly designed buffers. The procedure was carried out in a centrifuge tube and standard instrumentation was used. The cell lysates were prefractionated into two fractions: proteins with pI values above 7 and between 4 and 7, respectively. The fractions were then analyzed by 2-DE, selecting appropriate pH ranges for the IPG strips, and the gels were compared with those of unprefractionated cell lysates. Protein loading capacity was optimized and resolution and visualization of the less abundant and differentially expressed proteins were greatly improved.     

The whereabouts of transmembrane proteins from rat brain synaptosomes during two-dimensional gel electrophoresis

Little is known about what happens to transmembrane proteins (TMP) in 2-DE. In order to obtain more insight into the whereabouts of these proteins we prepared membrane-enriched synaptosomes from rat frontal cortex and washed them with 7 M urea or Na(2)CO(3). From each preparation, 200 microg protein was loaded on 2-DE gels covering the 4-7 and 6-11 pH ranges, respectively. MALDI-MS/MS analysis detected only 3 TMP among 421 identified spots. However, when the samples had been washed with Na(2)CO(3), only few well-focused spots remained detectable on the gel covering the pH 6-11 range. Instead, a heavily ruthenium-stained smear became visible at the upper edge of the gel at the location where the samples had been applied by cup loading. LC-MS/MS analysis revealed that this smear contained 38 unfocused TMP with up to 12 transmembrane helices. After transfer to the second dimension, no major areas of protein staining were left on the IPG strips. This indicates that after extraction and denaturation the TMP may form high-molecular aggregates, due to their "hydrophobic interactions". These aggregates enter the IPG strips, but do not focus regularly. They are then transferred onto the 2-DE-gels, where they remain caught at the upper edge.     

Toward a high resolution 2-DE profile of the normal human liver proteome using ultra-zoom gels

The human liver is the largest organ in the body and has many important physiological functions. A global analysis of human liver proteins is essential for a better understanding of the molecular basis of the normal functions of the liver and of its diseases. As part of the Human Liver Proteome Project (HLPP), the goal of the present study was to visualize and detect as many proteins as possible in normal human livers using two-dimensional gel electrophoresis (2-DE). We have constructed a reference map of the proteins of human normal liver that can be used for the comprehensive analysis of the human liver proteome and other related research. To improve the resolution and enhance the detection of low abundance proteins, we developed and optimized narrow pH range ultra-zoom 2-DE gels. High resolution patterns of human liver in pH gradients 4.5–5.5, 5–6, 5.5–6.7, 6–9 and 6–11 are presented. To improve the poor resolution in the alkaline pH range of 2-DE gels, we optimized the isoelectric focusing protocol by including sample application using cup loading at the anode and incorporating 1.2% hydroxyethyl disulfide, 15% 2-propanol and 5% glycerol in the rehydration buffer. Using the optimized protocol, we obtained reproducibly better resolution in both analytical and preparative 2-DE gels. Compared with the 2386 and 1878 protein spots resolved in the wide range 3–10 and 4–7 pH gradients respectively, we obtained 5481 protein spots from the multiple (overlapping) narrow pH range ultra-zoom gels in the range of pH 4.5–9. The visualized reference map of normal human liver proteins presented in this paper will be valuable for comparative proteomic research of the liver proteome.     

Proteome analysis of Streptococcus suis serotype 2

Outbreaks in humans, caused by Streptococcus suis serotype 2 (SS2), were reported in 1998 and 2005 in China. However, the mechanism of SS2-associated infection remains unclear. For the first time, a 2-D gel approach combined with MS was used to establish a comprehensive 2-D reference map for aiding our understanding of the pathogenicity of SS2. The identification of 694 out of 834 processed spots revealed 373 proteins. Most of the identified proteins were located in the cytoplasm and were involved in energy metabolism, protein synthesis, and cellular processes. Proteins that were abundant in the 2-DE gels could be linked mainly to housekeeping functions in carbohydrate metabolism, protein quality control and translation. 2-DE of secretory proteins was performed using IPG strips of pH 4-7. Among the 102 protein spots processed, 87 spots representing 77 proteins were successfully identified. Some virulence-associated proteins of SS2 were found, including arginine deiminase, ornithine carbamoyl-transferase, carbamate kinase, muramidase-released protein precursor, extracellular factor, and suilysin. Enolase and endopeptidase have been proposed as putative virulence-associated factors in this study. The 2-D reference map might provide a powerful tool for analyzing the virulence factor and the regulatory network involved in the pathogenicity of this microorganism.     

Analyzing alkaline proteins in human colon crypt proteome

Normal human colon crypt protein extract was resolved by two-dimensional gel electrophoresis using pH 6-11 immobilized pH gradient strips in the first dimension. The optimized isoelectric focusing protocol includes cup-loading sample application at the anode and 1.2% hydroxyethyl disulfide (DeStreak), 15% 2-propanol and 5% glycerol in the rehydration buffer. Spots were well resolved across the entire pH range up to 11. A total of 311 protein spots were identified by mass spectrometry and peptide mass mapping. After combining isoforms, 231 nonredundant proteins were grouped into 16 categories according to their subcellular locations, and 17 categories according to their physiological functions. Histone proteins, ribosomal proteins and mitochondrial proteins were among the well-resolved highest p/ proteins. Application of this protocol to the analysis of normal and neoplastic colon crypts will contribute to the proteomic study of colorectal tumorigenesis since a significant portion of the human proteins is in basic pH range.     

Improvements to polar 2-D electrophoresis for proteomic applications

Recently, we reported a new way of performing 2-DE, called P-dimensional electrophoresis (2-PE). In this approach, the second dimension is achieved in a radial gel which can accommodate up to six 7 cm long IPG strips simultaneously, improving reproducibility and throughput power in respect to 2-DE. Nevertheless, 2-PE was up to now limited to the use of only short strips because of technical difficulties. Here, we describe how to load longer strips (e.g., 18–24 cm) on 2-PE and report some representative images for a qualitative assessment.     

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。     

果实蛋白质组学研究的实验方法

双向电泳技术是蛋白质组学研究的基本方法之一。果实由于富含糖、多酚、单宁和有机酸等物质,蛋白质的提取比其它植物组织更加困难。本文主要介绍不同果实蛋白质的提取、等电聚焦系统和凝胶染色技术,并建立了一套适用于桃、樱桃、苹果、芒果和冬枣等多种果实蛋白质组学的研究方法。结果表明,采用匀浆法和酚抽提法提取果实的蛋白质,裂解缓冲液2溶解蛋白质,并用固相pH梯度进行等电聚焦,可以获得背景清晰和分辨率高的凝胶图谱,具有较好的重复性,可用于果实蛋白质组学的研究。我们的研究结果显示,固相干胶条与IEF管胶相比,具有更加明显的优势。而不同的染色方法,对结果影响不大。     

产热凝胶土壤杆菌ATCC31749蛋白质组双向电泳图谱的构建

建立了热凝胶生产茵土壤杆茵茵体总蛋白的蛋白质提取方法和双向电泳方案,确定了使用蛋白质裂解液(7 mol/L尿素,2 mol/L硫脲,1%ASB-14去垢剂,40 mmol/L Tris,0.001%溴酚蓝,1 mmol/L EDTA,1%TBP和1%两性电解质)结合超声破碎法来提取茵体总蛋白的方案为最佳,选择17 cm...     

Two-dimensional gel electrophoresis pattern (pH 6-11) and identification of water-soluble barley seed and malt proteins by mass spectrometry

A protocol was established for two-dimensional gel electrophoresis (2-DE) of barley seed and malt proteins in the pH range of 6-11. Proteins extracted from flour in a low-salt buffer were focused after cup-loading onto IPG strips. Successful separation in the second dimension was achieved using gradient gels in a horizontal SDS-PAGE system. Silver staining of gels visualized around 380 (seed) and 500 (malt) spots. Thirty-seven different proteins from seeds were identified in 60 spots, among these 46 were visualized also in the malt 2-D pattern. Proteins were identified by peptide mass fingerprinting and by tandem MS sequencing after in-gel digestion by trypsin. In addition, the N-terminal sequence of 10 different proteins from 11 spots was determined after electroblotting to a polyvinylidene difluoride (PVDF) membrane. Five identified proteins (in 9 spots) are involved in glycolysis, 12 in defence against pathogens (21 spots), 4 in storage, folding, and synthesis of proteins, and in nitrogen metabolism (5 spots), 6 in carbohydrate metabolism (11 spots), and 4 in stress and detoxification (9 spots). Six proteins (7 spots) were not grouped in these categories, and 3 were not ascribed a function. The presented 2-D patterns and identifications will be used to describe proteome differences between cultivars and changes during malting.     

果实蛋白质组学研究的实验方法

双向电泳技术是蛋白质组学研究的基本方法之一。果实由于富含糖、多酚、单宁和有机酸等物质,蛋白质的提取比其它植物组织更加困难。本文主要介绍不同果实蛋白质的提取、等电聚焦系统和凝胶染色技术,并建立了一套适用于桃、樱桃、苹果、芒果和冬枣等多种果实蛋白质组学的研究方法。结果表明,采用匀浆法和酚抽提法提取果实的蛋白质,裂解缓冲液2溶解蛋白质,并用固相pH梯度进行等电聚焦,可以获得背景清晰和分辨率高的凝胶图谱,具有较好的重复性,可用于果实蛋白质组学的研究。我们的研究结果显示,固相干胶条与IEF管胶相比,具有更加明显的优势。而不同的染色方法,对结果影响不大。     

Comparative 2-DE protein analysis in a 3-D geometry gel

Two-dimensional gel electrophoresis (2-DE) separation has not been considered suitable for large-scale comparative protein expression studies due to its limited throughput. We present a high-throughput analysis method based on three-dimensional (3-D) geometry gel electrophoresis. Following conventional isoelectric focusing (IEF), up to 36 immobilized pH gradient (IPG) strips are arrayed on the top surface of a 3-D gel body, and the samples transferred electrokinetically to the gel. A specific thermal management ensures that sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) occurs under identical electrophoretic and thermal conditions, avoiding gel-to-gel variations and thereby providing immediate comparability of the separation patterns. Proteins are Cy3-labeled for online detection of laser-induced fluorescence (LIF). Images are acquired by a digital camera and recorded as a 3-D image stack during electrophoresis. Image processing software decomposes the 3-D image stack into vertical sections representing conventional 2-DE slab gels, making results immediately accessible without further gel processing. The large number of simultaneously analyzed samples (n = 36) allows treating the sample index as a quasi-continuous experimental parameter (e.g., concentration, time, dose). The method offers a wide range of applications in molecular discovery, clinical diagnosis, pharmacology, and toxicology, like protein monitoring during disease development and screening of drug candidates for their effect on protein expression.     

Entamoeba histolytica: analysis of the trophozoite proteome by two-dimensional polyacrylamide gel electrophoresis

The Entamoeba histolytica genome project carried out at TIGR and the Sanger Institute has produced a near-complete set of deduced open reading frame sequences. These data provide strong support for the identification of signals from proteomic analyses such as two-dimensional electrophoresis by protein sequencing and/or mass spectrometric methods. To carry out an initial investigation of the E. histolytica proteome, appropriate sample preparation and silver staining protocols were adapted. After preparation of protein extracts from E. histolytica HM-1:IMSS trophozoites, solubilized proteins were separated in the first dimension in IPG (immobilized pH gradient) strips depending on their pI and subsequently in the second dimension according to their molecular weight by SDS-polyacrylamide gel electrophoresis. Of the more than 1500 protein spots visualized, several landmark spots were isolated from the gels and identified by either tryptic cleavage and subsequent MALDI-TOF mass spectrometry or by protein sequencing.