Approach to stationary two-dimensional pattern: influence of focusing time and immobiline/carrier ampholytes concentrations

Horizontal two-dimensional (2-D) electrophoresis with immobilized pH gradients (IPG) in the first dimension for buffer soluble proteins and for complex proteins solubilized in the presence of Nonidet P-40 (G?rg et al., Electrophoresis 1987, 8, 45-51), has been extended to analyze basic proteins of yeast cells focused under non-equilibrium and equilibrium conditions. Transient state isoelectric focusing (IEF) in IPG gels revealed sample smearing and background staining, displaying horizontal streaks in the resultant 2-D patterns. Inclusion of 0.5% carrier ampholytes (CA) to the IPG gel (IPG-CA), resulted in the formation of many sharp protein bands after transient state IEF with resultant distinct spots in the 2-D patterns; however, resolution was poor and the gel contained heavy background staining. With prolonged focusing time, background staining disappeared and there was less difference in the final steady state IEF patterns obtained with IPG and IPG-CA. Reduction of the Immobiline concentration to one third the manufacturer's recommended amount did not improve IEF resolution with respect to streaking and background staining under either transient state or equilibrium conditions. In general, spot intensities were less on 2-D gels using diluted IPG gels than with "standard" IPG gels. Optimization of 2-D electrophoresis with IPGs in the first dimension was strongly related to IEF conditions. The use of IPG gels focused to equilibrium should not only improve inter-gel reproducibility and resolution but also the quality of the final 2-D patterns with respect to background staining and horizontal streaking.     

Proteome analysis of rat polymorphonuclear leukocytes: a two-dimensional electrophoresis/mass spectrometry approach

The development of a two-dimensional (2-D) map of rat polymorphonuclear (PMN) leukocytes is here reported for the first time. The map is built up by utilizing a wide immobilized pH gradient (IPG), pH 3-10, in the first dimension and also a narrower IPG pH 4.5-8.5 gradient. In addition, the map is constructed by adopting the most recent protocols in 2-D mapping, which call for reduction and alkylation of the sample prior to the start of any electrophoretic step, including the IPG dimension. Fifty-two major protein spots have been so far identified by utilizing both matrix assisted laser desorption/ionization-time of flight (MALDI-TOF) and electrospray quadrupole (Q)-TOF mass spectrometry. A large number of house-keeping and cytoskeleton proteins were detected, together with proteins which are specific to PMN organelles or related to PMN functions such as phagocytosis and chemotaxis. The results obtained demonstrate the possibility of obtaining a single 2-D gel based proteomic map of PMN with representative proteins from different cellular compartments, also including membrane components, allowing the study of PMN protein expression on a proteome-wide scale. The aim of this project is to build an extensive database of such proteins, to be utilized for future studies where the expression of PMN proteins is used as a disease- or drug treatment marker.     

Two-dimensional electrophoresis with immobilized pH gradients of leaf proteins from barley (Hordeum vulgare): method, reproducibility and genetic aspects

Leaf proteins from 14 barley cultivars (Hordeum vulgare) were analyzed by two-dimensional electrophoresis with immobilized pH gradients (IPG 4-7 and IPG 6-10) in the first dimension. Highly reproducible two-dimensional patterns were obtained, owing to constant spot positions along the isoelectric focusing axis. A number of variety-specific protein spots were detected, allowing us to discriminate barley cultivars not only into main groups but into individual cultivars.     

Heterogeneity of cardiac rat and human elongation factor 2

Elongation factor 2 (EF-2) catalyses the last step of the elongation cycle, translocation, in the course of protein biosynthesis. A system for analyzing post-translational modifications of EF-2, which is a single polypeptide of 857 amino acids, is reported and its application to cytosolic extracts of cultured neonatal rat heart myocytes, neonatal and adult rat cardiac tissue, and extracts of human left ventricular myocardium is described. Comparing different pH ranges in immobilized pH gradient-isoelectric focusing (IPG-IEF), a range of pH 3 - 10 and 4 - 9 resulted in a highly defined and reproducible resolution of six different EF-2 variants of all extracts in the first dimension. These six variants were detected by the "imaging plate" (phosphor radiation image sensor) after specific labeling with Pseudomonas exotoxin A catalyzed [32P]ADP-ribosylation. This finding could be confirmed in Western blot analysis with a specific polyclonal rabbit antibody. Using two-dimensional polyacrylamide gel electrophoresis (2-D-PAGE), five to six EF-2 variants could be demonstrated in all extracts. By application of a second IPG indicator strip to the 2-D gel, they could be aligned with corresponding spots in a silver-stained 2-D separation of human myocardial tissue, revealing that the EF-2 variants belong to the group of low-abundance proteins.     

A simple method to remove contaminating salt from IPG strips prior to IEF

In this study, Saccharomyces cerevisiae yeast lysate is used to demonstrate how a simple wash procedure can improve IEF of IPG strips passively rehydrated in the presence of NaCl. By performing three 10 min washes after IPG strip rehydration and before IEF, corresponding second-dimensional gels from strips containing NaCl look similar to control strips while the second-dimensional gels of unwashed strips contains streaks and spaces devoid of protein. Up to 500 mM NaCl was added to the yeast lysate and successfully focused following this wash regime. Protein loss due to the washes was determined to be minimal by comparing replicates of washed and unwashed strips and analyzing the densities of their corresponding second-dimensional gel spots. In the event of unknown salt contamination, indicated by low voltage during focusing, it is possible to stop focusing, wash the strips, and then continue focusing with acceptable second dimension results.     

Two-dimensional gel electrophoresis using immobilized pH gradient tube gels

An apparatus for the preparation of gels for immobilized pH gradient isoelectric focusing (IPG) in glass tubes was developed. Using this apparatus, the highly reproducible immobilized pH gradient can be formed with Immobilines in polyacrylamide gels, and IPG gels at all possible pH ranges can be easily prepared at low cost. The IPG tube gels in the first dimension in two-dimensional gel electrophoresis was used to separate and identify a number of rice embryo proteins in the proteome analysis. There was no difference in resolution of proteins between the tube gels and the commercially available slab gels; after electrophoresis, however, we could efficiently obtain a larger amount of the purified proteins from the tube gels than from the slab gels.     

Revisiting electroblotting of immobilized pH gradient gels: a new protocol for studying post-translational modification of proteins

Currently, one of the most important techniques in proteome analysis is two-dimensional electrophoresis that is widely used for separation of thousands of different protein spots. Nevertheless, characterization of special aspects in protein patterns, e.g., separation of protein isoforms generated by post-translational modifications, requires individual detection methods, e.g., immunoblotting. Blotting of proteins after fractionation in immobilized pH gradients has always caused some problems. In this paper we present an optimized protocol for immunoblotting after isoelectric focusing using immobilized pH gradient (IPG) strips cast on Net-Fix as an internal support that is permeable to electric current. The focusing procedure can be carried out in commonly used IPG systems, e.g., the IPGphor by Amersham Biosciences, where electrically assisted rehydration can be performed. This may be of interest for many laboratories, because the same system as used for the first dimension of two-dimensional polyacrylamide gel electrophoresis (2-D PAGE) is involved. As an example, we describe separation and detection of up to seven isoforms of recombinant erythropoietin beta using semidry blotting of IPG strips and visualization by chemiluminescence detection.     

Isoelectric Focusing with Immobilized pH Gradients

Abstract

The technique of isoelectric focusing (IEF) via immobilized pH gradients (IPG) was first announced to the scientific community at a meeting of the International Electrophoresis Society in Athens, April 1982, as the result of an intensive collaborative effort [1]. In five years, the technique has been extensively developed in three fundamental aspects: analytical, preparative and as a first dimension of two-dimensional (2-D) maps. The merits and, recently, the flaws of the IPG technique have been evaluated and recognized, so that at the present writing we feel it is ready for successful introduction in most life-science laboratories.     

An optimized procedure for detection of proteins on carrier ampholyte isoelectric focusing and immobilized pH gradient gels with imidazole and zinc salts: its application to the identification of isoelectric focusing separated isoforms by in-gel proteolysis and mass spectrometry analysis.

A method for the characterization of proteins separated by isoelectric focusing in carrier ampholytes (CA-IEF) or immobilized pH gradient (IPG) gels by in-gel digestion and mass spectrometry is described. Proteins are detected by an improved imidazole-Sodium dodecyl sulfate (SDS)-zinc staining adapted for IEF and IPG gels. Sensitivity is close to that of mass spectrometry-compatible silver staining, but simpler and faster. Proteins were digested in imidazole-SDS-zinc stained CA-IEF and IPG gels in the presence of a zinc-chelating agent. Mass spectra were clearly interpretable as carrier ampholytes which were efficiently removed before digestion; high-sequence coverage that allowed isoform characterization was obtained by analyzing both the aqueous and the organic phase extracts.     

The effect of protease inhibitors on the two-dimensional electrophoresis pattern of red blood cell membranes

The last few years have brought dramatic improvements for sample preparation and solubilization of protein for electrophoretic analyses. The use of reagents such as thiourea and novel sulfobetaine surfactants increases the total number of proteins able to be visualized from a complex mixture such as a cell lysate and also allows more hydrophobic membrane proteins to be resolved. As the red blood cell (RBC) contain no organelles, it is an ideal source of relatively pure plasma membrane for protein solubilization studies. In addition, there are a number of diseases related to abnormalities of RBCs proteins, thus it is of medical relevance as well as a test sample for technology development. However, the procedure for purifying RBC membranes is rather time-consuming and is normally carried out under almost physiological conditions, which can be conducive to proteolytic degradation of the membrane proteins. Significant differences in two-dimensional (2-D) patterns with and without protease inhibitors in sample preparation are demonstrated. In addition, is shown that preparation of RBC membranes with sodium carbonate, pH 11, leads to multimeric complexes of hemoglobin and causes hemoglobin to be irreversibly attached to the membrane. When using immobilized pH gradients (IPG) as the first dimension, it is demonstrated that the spectrins (large, filamentous proteins of 280 kDa) are lost from the 2-D map unless active, instead of passive, sample hydration into the IPG strip is adopted.     

A human myocardial two-dimensional electrophoresis database: protein characterisation by microsequencing and immunoblotting.

This communication briefly describes how a human heart two-dimensional electrophoresis (2-DE) protein database is being established in our laboratory. The database contains more than 1500 polypeptides and approximately fifty proteins from 2-DE gels of human myocardial tissue have been characterised. Information about the proteins has been compiled including molecular weight (M(r)), isoelectric point (pI), sample spot (SSP) number, protein name, partial sequence, and antibody reacting with the protein. The first stage of this project involves the investigation of protein with pIs in the range pH 4-7. Future studies will employ immobilised pH gradient (IPG) gels as the first dimension of the 2-DE to examine basic proteins. The ultimate goal of this project is to establish a global picture of human heart protein expression in both normal and disease conditions.     

Autoimmune pancreatic disease: preparation of pancreatic juice for proteome analysis

The identification of pancreatic proteins is generally hampered by the high content and activity of proteases produced by this organ. The aim of this work was the development of a protocol for the analysis of pancreatic juice by two-dimensional (2-D) gel electrophoresis allowing consistent and reproducible protein analysis encompassed by high-resolution protein 2-D maps and subtle protein spot recognition without substantial losses due to proteases. Immobilized pH gradient (IPG) strips were used for the first dimension, the second dimension was performed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). However, the key step was the sample preparation technique. Improvements were achieved by using several protease inhibitors (phenylmethylsulfonyl fluoride, aprotinin, L-1-chloro-3-[4-tosyl-amido]-7-amino-2-heptanine (TLCK)-HCI, Complete) to prevent degradation of the proteins. The application of different pH-ranges was a valuable step for getting an overview of the expressed protein pattern. These investigations resulted in well-resolved 2-D maps with a high reproducibility.     

Isoenzyme analysis of lichen algae in immobilized pH gradients

A base for a modern species' concept of chlorococcal algae can be obtained not by morphological analysis, but by biochemical characters, e.g. isoenzyme banding patterns. From isolated lichen algae of the genus Trebouxia de Puymaly a set of five such enzymes has been studied by isoelectric focusing in immobilized pH gradients (IPG): phosphoglucomutase, phosphoglucose isomerase, malate dehydrogenase, mannitol dehydrogenase and leucine aminopeptidase. The first four are resolved into isoforms in a pH 4-7 IPG interval, while the last one is analyzed in an IPG pH 3.5-5 span. The patterns are specific for distinct populations, inter- and intraspecifically varying in dependence from their geographical distribution or the lichen species from which they have been isolated. Their limited heterogeneity (one to four isoforms) suggests that they are the products of specific genes rather than artefacts of the extraction procedure or the IPG analysis. Sharp isozyme patterns can only be obtained in a mixed-bed, carrier-ampholyte (CA)-IPG gel and by anodic application, suggesting that the recently proposed mechanism of hydrophobic protein-IPG matrix interaction (Electrophoresis, 1987, 8, 62-70) is fully operative here. As an additional mechanism, it is proposed that, in some cases, CA might simply act, when added to an IPG gel, by buffering, in the transient state, the sample zone before the protein migrates from the liquid phase into the IPG matrix.     

适于双向电泳分析的苹果叶片蛋白质提取方法

为了探索适用于双向电泳(2-DE)分析的苹果叶片蛋白质提取方法,比较了三氯乙酸(TCA)/丙酮沉淀法、二硫苏糖醇(DTT)/丙酮法、Tris-HCl提取法和改良的Tris-HCl提取法等4种蛋白质提取方法。以7 cm、pH 3～10的线性固相pH梯度(immobilized pH gradient,IPG)胶条作为第一向电泳,以十二烷基硫酸钠-聚丙烯酰胺凝胶电泳(SDS-PAGE)(12.5%的分离胶)作为第二向电泳,对提取物进行2-DE分离,采用银染显色。结果表明,上述4种方法在2-DE图谱上分别得到140,215,181和616个蛋白质点。其中以改良的Tris-HCl提取法得到的蛋白质点数最多,且背景清晰、图谱上没有明显的横纵条纹。为了进一步验证改良的Tris-HCl提取法的有效性,用18 cm、pH 3～10的线性IPG胶条和12.5%的分离胶对提取的苹果叶片蛋白质进行2-DE分离,考马斯亮蓝R-250染色,共检测到455个蛋白质点,其相对分子质量主要分布在14000～66000范围内,图谱背景清晰,再次证明应用该方法制备的样品适用于双向电泳分析,可用于苹果叶片的蛋白质组学分析。     

Immobilized pH gradients: effect of salts, added carrier ampholytes and voltage gradients on protein patterns

Salts formed from strong acids and bases (e.g. NaCl, Na2SO4, Na2HPO4), present in a protein sample applied to an immobilized pH gradient (IPG) gel, induce protein modification (oxidation of iron moiety in hemoglobin) already at low levels (5 mM) and irreversible denaturation (precipitation) at higher levels (greater than 50 mM). This effect is due to production of strongly alkaline cationic and strongly acidic anionic boundaries formed by the splitting of the salt's ion constituents, as the protein zone is not and can not be buffered by the surrounding gel until it physically migrates into the gel matrix. Substitution of "strong" salts in the sample zone with salts formed by weak acids and bases, e.g.. Tris-acetate, Tris-glycinate, Good's buffers such as (N-[2-acetamido]-2-iminodiacetic acid (ADA), (2-[(2-amino-2-oxoethyl)-amino] ethanesulfonic acid (ACES), (3-[N-morpholino]propane sulfonic acid (MOPS), essentially abolishes both phenomena, oxidation and irreversible denaturation. Suppression of "strong" salt's effects is also achieved by adding, to the sample zone, carrier ampholytes in amounts proportional to the salt present (e.g. by maintaining a salt: carrier ampholytes molar ratio of at least 1:1). This suppression is due to the strong buffering power of the added carrier ampholytes, able to counteract drastic pH changes in the two moving boundaries. A reduction of these deleterious effects of strong salts is also achieved when the IPG run is performed at low voltage for a prolonged time (4 h at 500 V instead of only 1 h at 500 V, before switching to high-voltage settings). Guidelines are given for trouble-free IPG operations.     

Proteome analysis of human liver tumor tissue by two-dimensional gel electrophoresis and matrix assisted laser desorption/ionization-mass spectrometry for identification of disease-related proteins

Hepatocellular carcinoma (HCC) is a common malignancy worldwide and is a leading cause of death. To contribute to the development and improvement of molecular markers for diagnostics and prognostics and of therapeutic targets for the disease, we have largely expanded the currently available human liver tissue maps and studied the differential expression of proteins in normal and cancer tissues. Reference two-dimensional electrophoresis (2-DE) maps of human liver tumor tissue include labeled 2-DE images for total homogenate and soluble fraction separated on pH 3-10 gels, and also images for soluble fraction separated on pH 4-7 and pH 6-9 gels for a more detailed map. Proteins were separated in the first dimension by isoelectric focusing on immobilized pH gradient (IPG) strips, and by 7.5-17.5% gradient sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gels in the second dimension. Protein identification was done by peptide mass fingerprinting with delayed extraction-matrix assisted laser desorption/ionization-time of flight-mass spectrometry (DE-MALDI-TOF-MS). In total, 212 protein spots (117 spots in pH 4-7 map and 95 spots in pH 6-9) corresponding to 127 different polypeptide chains were identified. In the next step, we analyzed the differential protein expression of liver tumor samples, to find out candidates for liver cancer-associated proteins. Matched pairs of tissues from 11 liver cancer patients were analyzed for their 2-DE profiles. Protein expression was comparatively analyzed by use of image analysis software. Proteins whose expression levels were different by more than three-fold in at least 30% (four) of the patients were further analyzed. Numbers of protein spots overexpressed or underexpressed in tumor tissues as compared with nontumorous regions were 9 and 28, respectively. Among these 37 spots, 1 overexpressed and 15 underexpressed spots, corresponding to 11 proteins, were identified. The physiological significance of the differential expressions is discussed.     

Protein alkylation in the presence/absence of thiourea in proteome analysis: a matrix assisted laser desorption/ionization-time of flight-mass spectrometry investigation

Although it is highly recommended that reduction and alkylation of free -SH groups in proteins should be performed prior to any electrophoretic step (including the first isoelectric focusing/immobilized pH gradient (IEF/IPG) dimension), it is here reported that one component of the sample solubilization cocktail adopted recently (namely thiourea) strongly quenches such alkylation process (as typically carried out with iodoacetamide, IAA).The present matrix assisted laser desorption/ionization-time of flight-mass spectrometry (MALDI-TOF-MS) analysis demonstrates that thiourea is an effective scavenger of IAA, since its sulfur atom reacts as efficiently as the ionized, free -SH group of Cys in proteins at alkaline pH values (pH 8.5-9.0). As a result of this reaction, free IAA is quickly depleted by thiourea, via the formation of an intermediate adduct, which is rapidly deamidated to form the cyclic compound thiazolinidone monoimine. This reaction strongly competes with the direct addition reaction of IAA onto the -SH group in proteins, resulting in poorly alkylated proteins. It is, therefore, recommended that, whenever possible and compatible with the type of sample, thiourea should be omitted from the solubilizing cocktail in proteome analysis. However, after proper sample reduction and alkylation, thiourea can be incorporated into the IEF/IPG gel, where it will have the beneficial effect of augmenting protein solubility at their pI values and scavenging the excess of free IAA.     

Quantitative evaluation of protein recoveries in two-dimensional electrophoresis with immobilized pH gradients

In this study, metabolically radiolabeled Escherichia coli cell extracts were used to systematically evaluate protein recoveries at each step of two-dimensional (2-D) electrophoresis and using different sample application methods. Sample application using sample cups resulted in better protein recovery compared with sample loading by rehydration when the Multiphor system was used. At least 50% or more of an E. coli extract was lost when high protein amounts (500 microg) were loaded by rehydration using this system, which employs separate holders for rehydration and isoelectric focusing (IEF). In contrast, when the IPGphor system was used, rehydration sample loading consistently yielded the highest overall protein recoveries. These improved protein recoveries were due to integration of rehydration and electrophoretic separation in a single unit. Even at high protein loads (500 microg), less than 15-20% of the proteins were lost when proteins were loaded by rehydration using sample buffer containing 2% carrier ampholytes in the ceramic immobilized pH gradient (IPG) strip holders used for both rehydration and IEF. Regardless of the loading conditions used, carrier ampholytes in the sample buffer increased protein recoveries. Use of thiourea did not significantly affect protein recoveries but did improve protein resolution in 2-D gels as expected. In summary, these results show the best protein recoveries are obtained for all protein loads when samples are applied to IPG strips during rehydration using a single device for both rehydration and IEF. In contrast, the poorest recoveries are obtained when rehydration and IEF are performed in separate devices, and losses increase dramatically with increasing protein loads using this approach.     

Towards higher resolution: two-dimensional electrophoresis of Saccharomyces cerevisiae proteins using overlapping narrow immobilized pH gradients

The rising number of proteome projects leads to new challenges for two-dimensional electrophoresis with immobilized pH gradients and different applications of this technique. Not only wide pH gradients such as 4-12 or 3-12 (G?rg et al., Electrophoresis 1999, 20, 712-717) which can give an overview of the total protein expressions of cells are in demand but also overlapping narrow immobilized pH gradients are to be used for more specialized and detailed research and micropreparative separations. The advantage of overlapping narrow pH gradients is the gain in higher resolution by stretching the protein pattern in the first dimension. This simplifies computer-aided image analysis and protein identification (e.g., by mass spectrometry). In this study the protein patterns of yeast cells in pH gradients 4-5, 4.5-5.5, 5-6, 5.5-6.7 and 6-9 are presented and compared to the pH 4-7 and 3-10 gradients. This combination allowed us to reveal a total of 2286 yeast protein spots compared to 755 protein spots in the pH 3-10 gradient.