pH measurements in ultranarrow immobilized pH gradients

It is possible to measure pH values in immobilized pH gradients (IPG) when the polyacrylamide matrix is made to contain an additional, carrier ampholyte-generated pH gradient. After an IPG run, 5 mm gel segments, along the separation axis, are cut and eluted in 300 microliter of 10 mM KCl and the pH read with a standard pH meter. When using ultranarrow pH gradients, larger gel segments (ca. 265 microliter) are eluted in 900 microliter of 100 mM KCl and the pH assessed with a differential pH meter. In the latter case, either internal or external standards are used as a reference, or starting point, to convert delta pH values into an actual pH curve. The reproducibility of the system is better than +/- 0.05 pH units, with a ca. 15% error over a 0.3 pH unit span. In ultranarrow pH gradients, it is imperative to use mixtures of all commercially available carrier ampholytes, so as to smoothen conductivity and buffering capacity gaps. By the present method, it is also possible to convert a wide (2-3 pH unit) carrier ampholyte interval into a narrow (0.2-0.3 pH unit) one.     

Protein purification by Off-Gel electrophoresis

A novel free-flow protein purification technique based on isoelectric electrophoresis is presented, where the proteins are purified in solution without the need of carrier ampholytes. The gist of the method is to flow protein solutions under an immobilised pH gradient gel (IPG) through which an electric field is applied perpendicular to the direction of the flow. Due to the buffering capacity of the IPG gel, proteins with an isoelectric point (pI) close to pH of the gel in contact with the flow chamber stay in solution because they are neutral and therefore not extracted by the electric field. Other proteins will be charged when approaching the IPG gel and are extracted into the gel by the electric field. Both a demonstration experiment with pI markers and a simulation of the electric field distribution are presented to highlight the principle of the system. In addition, an isoelectric fractionation of an Escherichia coli extract is shown to illustrate the possible applications.     

G-electrode-loading method for isoelectric focusing, enabling separation of low-abundance and high-molecular-mass proteins

The G-electrode-loading method (GELM) is a technique enabling a large number of proteins from rat liver to enter an immobilized pH gradient (IPG) gel strip for isoelectric focusing (IEF). In this method, three slips containing the sample solution are placed on the cathodic edge of an IPG gel strip and a slip containing Chaps solution, a filtration membrane, and an electrode slip are placed on top. Finally, a G-electrode is placed on these slips. The Chaps solution (an amphoteric compound) is supplied gently to the sample solution during IEF and helps the proteins in the sample solution to enter the IPG gel strips with a high solubilization capacity. This method was compared with traditional slip-loading and in-gel rehydration, and it showed the best results for protein separation, including high-molecular-mass proteins.     

Evaluation of protocols used in 2-d electrophoresis for proteome analysis of young rice caryopsis

In order to obtain a high-resolution electrophorogram of rice young panicle proteome, we evaluated various protocols commonly used in two-dimensional (2D) polyacrylamide gel electrophoresis (PAGE) of proteins, including gel staining protocol, pH range of immobilized pH gradient (IPG) strips and sample loading quantity. Results showed that a silver staining protocol using sensitized solution containing glacial acetic acid, sodium acetate and sodium thiosulfate (reported by Heukeshoven and Dernick in 1988) and a Coomassie Brilliant Blue staining method using solution containing G-250, ammonium sulfate and phosphoric acid (reported by Pink et al in 2010) demonstrated the superior staining effect. In addition, we also showed that higher resolution was achieved when IPG gel strip with pH range of 5-8 was used, compared to that with pH range of 4-7. Finally, the optimal loading quantity was determined as 130 μg using the 17 cm-long nonlinear IPG strip with pH 5-8 in combination with the silver nitrate staining protocol. The evaluated results would be helpful in proteome analysis of young rice caryopsis.     

Soft immobilized pH gradient gels in proteome analysis: a follow-up

As a follow-up of a previous work on two-dimensional map analysis utilizing soft (< 4%T) immobilized pH gradient (IPG) matrices in the first dimension (Candiano et al., Electrophoresis 2002, 23, 292-297), we have further optimized the preparation of such dilute IPG gels. One important step for obtaining an even reswelling of the entire IPG strip along the pH 3-10 interval is a washing step in 100 mM citric acid. It appears as though after rinsing off the excess acid in distilled water, a gradient of this tricarboxylic acid remains trapped into the IPG matrix, from almost nil at the acidic gel region to substantially higher amounts in its basic counterpart. This gradient helps in obtaining a uniform reswelling of the IPG strip, since carboxyl groups are more heavily hydrated than amino groups. The combined effects of uniform reswelling and of diluting the gel matrix favor penetration of large macromolecules (> 200 kDa) and allow for better spot resolution and for the display of a substantially higher number of spots also in the 30-60 000 Da region. A delipidation step in tri-n-butylphosphate:acetone:methanol (1:12:1) appears to substantially improve spot focusing and greatly diminish streaking and smearing of spots in all regions of the pH gradient.     

Detection of low-molecular weight allergens resolved on two-dimensional electrophoresis with acid-urea polyacrylamide gel

Two-dimensional electrophoresis with immobilized pH gradient (IPG) followed by acetic acid/urea-polyacrylamide gel electrophoresis (AU-PAGE) was developed for the detection of low-molecular weight food allergens. Wheat proteins were used to test the applicability of AU-PAGE for the analysis of food allergens. Isoelectric focusing (IEF) for first dimension was performed with IPG pH 3-10. AU-PAGE was performed as a second-dimensional electrophoresis and high resolution was obtained, especially for proteins below 15 kDa. For immunodetection, the proteins resolved on AU gel were transferred to a polyvinylidene difluoride membrane. The assembly of semidry electroblotting for AU gel was set reversed as for sodium dodecyl sulfate (SDS)-PAGE gel. The electroblotted membrane was immunolabeled with serum from a radio-allergosorbent test-positive individual for wheat to identify allergenic proteins. Protein spots strongly recognized by the patient's serum were chosen for further analysis. Mass spectrometry analysis revealed that these proteins were alpha-amylase/trypsin inhibitors and lipid transfer protein. The system developed in this study was shown to be useful as a standard protocol for the separation of low-molecular weight proteins. Moreover, the IPG strips on which IEF was performed could be used either for SDS-PAGE or AU-PAGE by only changing equilibrating conditions, allowing for a wide range of allergen analysis.     

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.     

High-sensitivity analysis of human plasma proteome by immobilized isoelectric focusing fractionation coupled to mass spectrometry identification

Immobilized pH gradients isoelectric focusing (IPG-IEF) is the first dimension typically used in two-dimensional gel electrophoresis (2-DE). It can also be used on its own in conjunction with tandem mass spectrometry (MS/MS) for the analysis of proteins. Here, we described a strategy combining isoelectric focusing in immobilized pH gradient strips, and mass spectrometry to create a new high-throughput and sensitive detection method. Protein mixture is separated by in-gel IEF, then the entire strip is cut into a set of gel sections. Proteins in each gel section are digested with trypsin, and the resulted peptides are subjected to reversed-phase high performance liquid chromatography followed by electrospray-linear ion-trap tandem mass analysis. Using this optimized strategy, we have identified 744 distinct human proteins from an IPG strip loaded only 300 microg of plasma proteins. When compared with other works in published literatures, this study offered a more convenient and sensitive method from gel to mass spectrometry for the separation and identification proteins of complex biological samples.     

A comparison of immobilized pH gradient isoelectric focusing and strong-cation-exchange chromatography as a first dimension in shotgun proteomics

Recently, we have developed a high-resolution two-dimensional separation strategy for the analysis of complex peptide mixtures. This methodology employs isoelectric focusing of peptides on immobilized pH gradient (IPG) gels in the first dimension, followed by reversed-phase chromatography in the second dimension, and subsequent tandem mass spectrometry analysis. The traditional approach to this mixture problem employs strong-cation-exchange (SCX) chromatography in the first dimension. Here, we present a direct comparison of these two first-dimensional techniques using complex protein samples derived from the testis of Rattus norvegicus. It was found that the use of immobilized pH gradients (narrow range pH 3.5-4.5) for peptide separation in the first dimension yielded 13% more protein identifications than the optimized off-line SCX approach (employing the entire pI range of the sample). In addition, the IPG technique allows for a much more efficient use on mass spectrometer analysis time. Separation of a tryptic digest derived from a rat testis sample on a narrow range pH gradient (over the 3.5-4.5 pH range) yielded 7626 and 2750 peptides and proteins, respectively. Peptide and protein identification was performed with high confidence using SEQUEST in combination with a data filtering program employing pI and statistical based functions to remove false-positives from the data.     

Immobilized pH gradients for isoelectric focusing. III. Preparative separations in highly diluted gels

A further improvement on the preparative aspects of immobilized pH gradients (IPG) (J. Biochem. Biophys. Methods (1983) 8, 135–172) is described, based on the use of soft (highly diluted) polyacrylamide gels. While in conventional IPGs in 5%T gels an upper load limit of 40–45 mg protein/ml gel volume is found, in 2.5%T gels, containing the same amount of Immobiline, as much as 90 mg protein/ml gel can be applied, without overloading effects. This is an extraordinary amount of material to ba carried by a gel phase, and renders IPG by far the leading technique in any electrophoretic fractionation. A new, two-step casting technique, based on the formation of a %T step and a pH plateau around the application trench, is described. A new method for electrophoretic protein recovery from IPG gel strips, based on embedding on low-gelling agarose (37°C), is reported. The physico-chemical properties of highly diluted gels, in relation to their protein loading ability, are evaluated and discussed. It is recommended that diluted gels (e.g. 3.5%T) be used also in analytical runs, since sharper protein zones are obtained, due to the increased charge density on the polymer coil.     

缺铁逆境胁迫下水稻叶片蛋白的双向电泳及其蛋白质组图谱分析

水稻幼苗经缺铁胁迫诱导分别处理1、3、5天后,用酚法和TCA/丙酮法提取叶片中的可溶性蛋白进行双向电泳分析,从而研究在缺铁条件下叶片中蛋白表达的动态变化规律.结果显示1.不同pH IPG胶条分离蛋白的效果不同.用pH3-10的IPG胶条进行双向电泳,经考马斯亮蓝染色后,可在胶面上检测到大约450个蛋白点,其中约有89%的蛋白是酸性蛋白.如果用pH4-7的IPG胶条进行双向电泳,则可检测到大约600个蛋白点,其中有29个蛋白是上调表达,1个蛋白是下调表达,5个蛋白是诱导特异表达.2.不同方法提取的可溶性蛋白质量不同.TCA法简单易操作,似乎对于碱性蛋白的抽提效果更好,在2-DE图像上,减性端显示的蛋白点多;但此方法所得蛋白的再溶性差.酚法提取的蛋白再溶性好,所抽提的蛋白量较大,纯度较高.     

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.     

人肺巨细胞癌蛋白质组的二维电泳和计算机图象分析

为优化用于蛋白质组研究的二维电泳技术和计算机图象分析技术 ,以及初步分析比较与肿瘤细胞转移相关的蛋白质 ,以人肺巨细胞癌 (PLA- 80 1 - D、C)高、低转移株作为研究对象 ,应用 IPG-phor进行第一向等电聚焦 ,随后 ,在 Protein IPG conversion Kit上进行垂直 SDS- PAGE的分离 .利用光密度仪对银染的凝胶扫描 ,通过 PDQuest软件进行蛋白斑点检测和配比 .结果表明 :(1 )应用 IPGphor,采用样品直接加入重泡胀溶液的形式 ,增大了溶解性 ,缩短聚焦时间、增大样品负荷量 (分析型 ) ,提高了分辨率 .(2 )比较宽 (p H=3～ 1 0 L)、窄 (p H=4～ 7L)范围 IPG胶条 ,窄 p H范围的 IPG胶条具有较高的分辨率 .(3)比较 PLA- 80 1 - C、D细胞蛋白图谱之间的差异 ,其相关系数为 0 .7339± 0 .0 2 91 ;仅在 PLA- 80 1 - C株出现的蛋白为 1 79个 .     

No peptide left behind: the “out of range” recovery in IPG–IEF fractionation

IEF is often used in multidimensional shotgun proteomics and the narrow range of 3.5–4.5 is the recommended pH interval for the fractionation of tryptic peptides. Usually, even if IEF is performed in IPG strip with a narrow range pH, the entire sample must be loaded onto the strip, including the “out of IPG range” peptides. We describe a simple protocol to recover at least a part of these missing peptides and show that this recovery significantly influences the overall fractionation result, increasing the number of the identified proteins and the protein coverage.     

A simplified 2-D electrophoresis protocol with the aid of an organic disulfide

2-DE is still a relatively cumbersome and labor intensive method. Given the successful cysteinyl protection concept with hydroxyethyl disulfide (specific oxidation) during the first dimension separation, the possibility for a simplified equilibration procedure was investigated. This was achieved by maintaining the S-mercaptoethanol modified cysteinyls throughout the 2-D workflow including second dimension separation, spot handling, protein digestion, and protein identification. The traditional equilibration protocol encompassing thiol reduction and alkylation was compared with a one-step protocol employing continuous exposure to hydroxyethyl disulfide. Both equilibration protocols gave equally well-resolved spot maps with analytical protein loads regardless of IPG strip pH range. Using preparative protein loads, narrow range IPG strips gave comparable results for the two protocols while preparative load on wide range IPG strips was the only condition where classical reduction/alkylation outperformed hydroxyethyl disulfide equilibration. Moreover, with analytical protein loads, the hydroxyethyl disulfide equilibration time could be significantly reduced without apparent loss of spot map quality or quantitative protein transfer from the first- to the second dimension gel. MALDI-TOF mass spectrometric protein identification was successfully performed with either iodoacetamide or hydroxyethyl disulfide as the cysteine modifier, yielding comparable identification results with high confidence in protein assignment, sequence coverage, and detection of cysteine-containing peptides. The results provide a novel and simplified protocol for 2-DE where the concept of hydroxyethyl disulfide as the cysteinyl protecting agent is extended to cover the entire 2-D work flow.     

Which electrodic solutions for immobilized pH gradients?

Carrier ampholytes covering a pH range corresponding to, or narrower than, the span of the immobilized pH gradient (IPG) are a most suitable electrodic solution for IPGs. They are able to collect, and completely remove from the gel, much higher amounts of non-buffering ions than are solutions of acidic and basic amino acids. This makes it possible to directly run IPGs just after their polymerization, without the need of a washing step to remove catalysts and unreacted Immobiline monomers. The same applies most advantageously when the gel formulation includes urea and/or detergents. Ions contributed by the sample solution are also prevented from casting high-conductivity ridges around the electrodes, without any need either of a dialysis step or of an increased slab size with pH plateaus. The migration of the sample proteins toward their equilibrium position is faster in the presence of carrier ampholytes. The effective concentrations of the latter are in the range 0.3-1%.     

Preparative two-dimensional gel electrophoresis at alkaline pH using narrow range immobilized pH gradients

A reproducible high-resolution protein separation method is the basis for a successful differential proteome analysis. Of the techniques currently available, two-dimensional gel electrophoresis is most widely used, because of its robustness under various experimental conditions. With the introduction of narrow range immobilized pH gradient (IPG) strips (also referred to as ultra-zoom gels) in the first dimension, the depth of analysis, i.e. the number of proteins that can be resolved, has increased substantially. However, for poorly understood reasons isoelectric focusing on ultra-zoom gels in the alkaline region above pH 7 has suffered from problems with resolution and reproducibility. To tackle these difficulties we have optimized the separation of semipreparative amounts of proteins on alkaline IPG strips by focusing on two important phenomena: counteracting water transport during isoelectric focusing and migration of dithiothreitol (DTT) in alkaline pH gradients. The first problem was alleviated by the addition of glycerol and isopropanol to the focusing medium, leading to a significant improvement in the resolution above pH 7. Even better results were obtained by the introduction of excess of the reducing agent DTT at the cathode. With these adaptations together with an optimized composition of the IPG strip, separation efficiency in the pH 6.2-8.2 range is now comparable to the widely used acidic ultra-zoom gels. We further demonstrated the usefulness of these modifications up to pH 9.5, although further improvements are still needed in that range. Thus, by extending the range covered by conventional ultra-zoom gels, the depth of analysis of two-dimensional gel electrophoresis can be significantly increased, underlining the importance of this method in differential proteomics.     

Two-dimensional maps in the most extended (pH 2.5-11) immobilized pH gradient interval

In conventional isoelectric focusing in soluble, amphoteric buffers, it has been quite difficult to produce two-dimensional (2-D) separations in pH intervals greater than pH 4-8. In general more alkaline proteins were analyzed by non-equilibrium IEF in the first dimension. Even with the advent of immobilized pH gradients (IPG), separations could be extended to pH gradients not wider than pH 3-10, due to a lack of suitable buffers. Since more acidic and more alkaline acrylamido buffers have recently been synthesized, we have been able to optimize what is believed to be the widest possible immobilized pH gradient, a pH 2.5-11 span. We report here for the first time 2-D separations of total tissue lysates in such extended pH 2.5-11 gradients. It appears that, with the IPG technique, close to 100% of all possible cell products can be displayed in a single 2-D map.     

Peptide mapping of basic proteins by proteolysis in acetic acid/urea-minislab polyacrylamide gels

A method to obtain peptide maps of basic proteins on acetic acid/urea (AU) -polyacrylamide minislab gels is presented. Basic proteins such as the histones are digested with Staphylococcus aureus V8 protease in the stacking gel (pH 4) of an AU-polyacrylamide minislab gel. As the peptides are resolved in the AU minislab gel on the basis of charge and size, it is possible to separate peptides containing modified amino acids from the unmodified, parent peptide. The peptide(s) containing the modified residue may be identified following electrophoresis on a second-dimension sodium dodecyl sulfate-polyacrylamide minislab gel. This procedure will be useful for comparing histone variants and for the study of histone modifications.     

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.