High resolution two-dimensional electrophoresis of basic as well as acidic proteins.

A previously described two-dimensional electrophoresis procedure (O'Farrell, 1975) combined isoelectric focusing and sodium dodecylsulfate slab gel electrophoresis to give high resolution of proteins with isoelectric points in the range of pH 4–7. This paper describes an alternate procedure for the first dimension which, unlike isoelectric focusing, resolves basic as well as acidic proteins. This method, referred to as nonequilibrium pH gradient electrophoresis (NEPHGE), involves a short time of electrophoresis toward the cathode and separates most proteins according to their isoelectric points. Ampholines of different pH ranges are used to optimize separation of proteins with different isoelectric points. The method is applied to the resolution of basic proteins with pH 7–10 Ampholines, and to the resolution of total cellular proteins with pH 3.5–10 Ampholines. Histones and ribosomal proteins can be readily resolved even though most have isoelectric points beyond the maximum pH attained in these gels. The separation obtained by NEPHGE with pH 3.5–10 Ampholines was compared to that obtained when isoelectric focusing was used in the first dimension. The protein spot size and resolution are similar (each method resolving more than 1000 proteins), but there is less resolution of acidic proteins in this NEPHGE gel due to compression of the pattern. On the other hand, NEPHGE gels extend the range of analysis to include the 15–30% of the proteins which are excluded from isoelectric focusing gels. The distribution of cell proteins according to isoelectric point and molecular weight for a procaryote (E. coli) was compared to that of a eucaryote (African green monkey kidney); the eucaryotic cell proteins are, on the average, larger and more basic.     

Two-dimensional polyacrylamide gel electrophoresis of membrane proteins

Two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) is one of the most powerful separation techniques for complex protein solutions. The proteins are first separated according to their isoelectric point, driven by an electric field across a pH gradient. The pH gradient necessary for the separation according to isoelectric point (pL) is usually established by electrophoresing carrier ampholytes prior to and/or concomitantly with the sample. The second dimension is usually a separation according to molecular size. Mostly this separation is performed after complete denaturation of the proteins by sodium dodecyl sulfate and 2-mercaptoethanol (SDS-PAGE). This standard method has considerable disadvantages when relatively hydrophobic membrane proteins are to be separated: cathodic drift, resulting in nonreproducible separation, and the denaturation of the protein, mostly making it impossible to detect native properties of the proteins after separation (e.g., enzymatic activity, antigenicity, intact multimers, and so on). The protocols presented here take care of most of these obstacles. However, there is probably no universal procedure that can guarantee success at first try for any mixture of membrane proteins; some experimentation will be necessary for optimization. Two procedures are each presented: a denaturing (with urea) and a nondenaturing method for IEF in immobilized pH gradient gels using Immobilines, and a denaturing (with SDS and 2-mercaptoethanol) and a nondenaturing technique (with CHAPS) for the second dimension. Essential tips and tricks are presented to keep frustrations of the newcomer at a low level.     

双向凝胶电泳技术进展

双向聚丙烯酰胺凝胶电泳按等电点和分子量对蛋白质进行分离,具有很高的分辨率,已经成为蛋白质组研究中的核心技术之一。目前的方法还难以满足真核生物蛋白质组研究的要求。自1975年O'Farrell提出该方法以来,针对应用中常见的一些问题,如样品的增溶及加载,样品的预分级分离,阴极漂移和凝胶上蛋白质的回收等,对这种技术进行了不断的改进。     

Highlights on the capacities of "Gel-based" proteomics

Gel-based proteomic is the most popular and versatile method of global protein separation and quantification. This is a mature approach to screen the protein expression at the large scale, and a cheaper approach as compared with gel-free proteomics. Based on two independent biochemical characteristics of proteins, two-dimensional electrophoresis combines isoelectric focusing, which separates proteins according to their isoelectric point, and SDS-PAGE, which separates them further according to their molecular mass. The next typical steps of the flow of gel-based proteomics are spots visualization and evaluation, expression analysis and finally protein identification by mass spectrometry. For the study of differentially expressed proteins, two-dimensional electrophoresis allows simultaneously to detect, quantify and compare up to thousand protein spots isoforms, including post-translational modifications, in the same gel and in a wide range of biological systems. In this review article, the limits, benefits, and perspectives of gel-based proteomic approaches are discussed using concrete examples.     

Protein staining and pH gradient determination on the same gel in isoelectric focusing.

The apparent isoelectric point of a component focused on polyacrylamide gels is normally estimated by extrapolating a pH gradient determined on one gel to another gel which has been stained for protein in order to locate the position of the component (1). The pH gradient is determined by slicing the gel transversely and reading the pH of the eluate after soaking the segments for 1–2 hr in a small amount of degassed water. It is assumed that the gradients in both gels are identical. Alternatively, an antimony microelectrode has been used to measure pH gradients directly in unsectioned gels (2). Similar techniques have been applied to polyacrylamide gel slabs and are reviewed by Vesterberg (3). Righetti and Drysdale (4) have recently reviewed these and other aspects of isoelectric focusing in gels.I report here a very precise method for the determination of a protein “isoelectric point” that can be accomplished with a single gel. The technique is demonstrated with yeast phosphoglycerate kinase and the very low density lipoprotein (VLDL) fraction from human plasma.     

Fast method for two-dimensional electrophoresis of proteins from biological samples

The method for two-dimensional gel electrophoresis of J. Klose and M. Feller [(1981) Electrophoresis 2, 12-24] has been simplified by reducing the thickness of the gels from 3.5 to 1.1 mm for isoelectric focusing gels and from 3.5 to 0.84 mm for sodium dodecyl sulfate slab gels. Thin gels need less reagents and smaller sample volumes. Cooling of the thin gels during electrophoresis is more effective, which allows the use of higher electric power. Therefore, less time is required for an electrophoretic run (approx 4 h). The resolution increases due to the smaller size of the spots. The time required for staining the gels is reduced from at least 3 days to about 1 h. The method has been tested with a protein sample from the filamentous fungus Fusarium solani.     

Isoelectric focusing of high-molecular-weight protein complex under native conditions using agarose gel

The isolation and characterization of protein complexes are essential steps toward understanding cellular functions. A method for separating and characterizing high-molecular-weight protein complexes using two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) with native agarose gel isoelectric focusing (IEF) is described. Using this method, fractions containing high-molecular-weight protein complexes were analyzed. The advantages of using native agarose gel IEF include the ability to concentrate the protein complexes and the ease of handling when performing 2D separations. Although limited with respect to the size of molecules and particles that may be separated, this method is useful for the isolation and characterization of high-molecular-weight protein complexes.     

Poly-N-acryloyl-Tris gels as anticonvection media for electrophoresis and isoelectric focusing

We describe in detail the synthesis of an acrylic monomer, N-acryloyl-tris(hydroxy-methyl)aminomethane (NAT), which was successfully used for the preparation of gels for electrophoresis and isoelectric focusing. The polymerization kinetics and transparency of the poly(NAT) gels crosslinked by N,N'-methylenebisacrylamide (Bis) are also shown. Poly(NAT)-Bis gradient (4-24%) gel resolves proteins according to their size. The exclusion limit of this gel is slightly over 3 X 10(6), which is more than threefold higher than the exclusion limit of the polyacrylamide gradient gel of the same concentration. The gel made of 6% NAT and 3% Bis represents a suitable matrix for isoelectric focusing. These results demonstrate that poly(NAT)-Bis gels could be advantageously used in those applications where the extensive sieving by the polyacrylamide matrix is not desir desirable.     

A multiple high-resolution mini two-dimensional polyacrylamide gel electrophoresis system: imaging two-dimensional gels using a cooled charge-coupled device after staining with silver or labeling with fluorophore.

A multiple mini two-dimensional electrophoretic method which results in three two-dimensional protein spot patterns being positioned side by side in an individual gel has been developed. Preparation time has been minimized by employing disposable capillary tubes for the isoelectric focusing gels and reducing the number of second-dimensional gels required. Commercially available vertical slab units were used for the second-dimensional electrophoresis. The protein spot patterns were visualized either by staining the second-dimensional gel with silver or fluorescently labeling the focused proteins while present in the isoelectric focusing gel and subsequently electrophoresing them into the second-dimensional gel. The fluorescently labeled second-dimensional gel was imaged while still present in the glass mold immediately following electrophoresis. Two fluorophores were compared: 2-methoxy-2,4-diphenyl-3(2H)-furanone and 5-(4,6-dichlorotriazin-2-yl)aminofluorescein hydrochloride. A rapid imaging system based on a cooled charge-coupled device was used to view both the silver-stained and fluorescently labeled two-dimensional spot patterns. The sensitivity of detection of protein spots in the mini two-dimensional gels was similar for the two types of fluorescently labeled gels and the silver-stained gels.     

Large-scale electrophoresis for protein purification: exploiting isoelectricity

Preparative electrophoresis methods (including isoelectric focusing in immobilized pH gradients) in gel phases are characterized by low loadings barely a few mg protein per ml matrix), low recoveries (rarely exceeding 70%), and heavy contamination from neurotoxic gel materials (the unreacted gel monomers and ungrafted oligomers). These drawbacks can be minimized by a version of isoelectric focusing in which the need for protein of interest to pass the gel is eliminated: only the contaminants traverse the gel. This is achieved by circulating a liquid sample between two gels held at controlled pHs. The method can provide: (1) high rate of sample processing (up to 1 g h⁻¹); (2) high purification (in general to charge homogeneity); and (3) high recoveries (>95%). A large-scale membrane apparatus has been built, with a cross- sectional diameter of 9 cm. Large Pt electrode disks provide even current flow. In this electrolyser, 10 g of Eglin C (produced by recombinant DNA technology) have been purified to homogeneity in around 10 h from 1 l of a partially enriched preparation.     

HPLC analysis of discrete haptoglobin isoform N-linked oligosaccharides following 2D-PAGE isolation

Glycosylation is a common but variable modification that regulates glycoprotein structure and function. We combined small format 2D-PAGE with HPLC to analyse discrete human haptoglobin isoform N-glycans. Seven major and several minor haptoglobin isoforms were detected by 2D-PAGE. N-Glycans released from Coomassie-stained gel spots using PNGase were labeled at their reducing termini with 2-aminobenzamide. HPLC analysis of selected major isoform N-glycans indicated that sialic acid composition determined their separation by isoelectric focussing. N-Glycans from two doublets of quantitatively minor isoforms were also analysed. Although separation of each pair of doublets was influenced by sialylation, individual spots within each doublet contained identical N-glycans. Thus, heterogeneity in minor haptoglobin isoforms was due to modifications distinct from N-glycan structure. These studies describe a simple method for analysing low abundance protein N-glycans and provide details of discrete haptoglobin isoform N-glycan structures which will be useful in proteomic analysis of human plasma samples.     

Capillary isoelectric focusing coupled with dynamic imaging detection: A one-dimensional separation for two-dimensional protein characterization

Here, we devised a novel approach for two-dimensional (2D) protein characterization using a single one-dimensional separation followed by a second characterization in the same instrument. The approach combines capillary isoelectric focusing (CIEF), which separates proteins according to pI, with dynamic imaging detection, which permits monitoring of protein diffusion in real time and thereby allows estimation of molecular weight from diffusion coefficient. Compared with classical 2D gel electrophoresis, the approach provided several significant advantages including speed and ease in operation and automation, while yielding comparable accuracy. The approach was applicable for protein samples of low to moderate complexity.     

Plant protein isolation and stabilization for enhanced resolution of two-dimensional polyacrylamide gel electrophoresis

Two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) is the common method of choice for proteomic analysis. By introducing several small changes, a method was developed that not only improved the resolution and reproducibility of 2D-PAGE but also shortened the time of analysis. Precipitation by alkaline phenol and methanol/ammonium acetate was the choice for protein extraction. However, instead of precipitating the proteins overnight at -20 °C, it was carried out for 2 to 3 h at -80 °C. Ethanol was used for the final wash of the protein precipitate instead of routinely used acetone. Dithiothreitol (DTT) was used in all solutions from the beginning, considerably improving the solubilization of precipitated proteins. Solubilization was further improved by using a mixture of detergents and denaturants at high concentrations along with large amounts of DTT. Both in-gel rehydration and cup-loading methods were used for isoelectric focusing (IEF). For in-gel rehydration, samples reduced with DTT were diluted with sample buffer containing 2-hydroxyethyl disulfide (2-HED) (1:3) or were cup-loaded on a strip rehydrated with sample buffer containing 2-HED. Glycerol (5%) was used in the sample buffer, and the focusing was performed at 15 °C. The applicability of the method was demonstrated using several soybean tissues.     

Two-dimensional fluorescence difference gel electrophoresis for comparative proteomics profiling

Quantitative proteomics is the workhorse of the modern proteomics initiative. The gel-based and MuDPIT approaches have facilitated vital advances in the measurement of protein expression alterations in normal and disease phenotypic states. The methodological advance in two-dimensional gel electrophoresis (2DGE) has been the multiplexing fluorescent two-dimensional fluorescence difference gel electrophoresis (2D-DIGE). 2D-DIGE is based on direct labeling of lysine groups on proteins with cyanine CyDye DIGE Fluor minimal dyes before isoelectric focusing, enabling the labeling of 2-3 samples with different dyes and electrophoresis of all the samples on the same 2D gel. This capability minimizes spot pattern variability and the number of gels in an experiment while providing simple, accurate and reproducible spot matching. This protocol can be completed in 3-5 weeks depending on the sample size of the experiment and the level of expertise of the investigator.     

Differential radioactive proteomic analysis of microdissected renal cell carcinoma tissue by 54 cm isoelectric focusing in serial immobilized pH gradient gels

We present a proof of principle study, using laser microdissection and pressure catapulting (LMPC) of two clinical tissue samples, each containing approximately 3.8 microg renal cell carcinoma protein and 3.8 microg normal kidney protein respectively from one patient. The study involved separate radio-iodination of each sample with both (125)I and (131)I, dual inverse replicate sample loading to high resolution 54 cm "daisy chain" serial immobilized pH gradient isoelectric focusing (IPG-IEF) 2D-PAGE gels, co-electrophoretic separation of cross-labeled proteins from different samples, and precision multiplex differential radioactive imaging to obtain signals specific for each sample coelectrophoresed within single gels but labeled with different isotopes of iodine, providing extremely precise intra-gel estimates of the abundance ratio for protein spots from both samples. Twelve multiplexed analytical radioactive SDS-gels from 4 serial IPG-IEF gels provided 24 individual radioactive images for a comprehensive analytical protein multiplex quantification study. A further 12 SDS gels containing (125)I-labeled sample were coelectrophoresed with preparative protein amounts obtained from whole tissue sections for the mass spectrometric identification of comigrating proteins. This consumed <40% of the (125)I-labeled sample, and <20% of the (131)I-labeled sample from the respective original 3.8 microg samples. Twenty-nine proteins were identified by mass spectrometry with PMF scores >70 that were >2-fold differentially abundant between the samples and t-test probabilities <0.05. We conclude that this combination of technologies provides excellent quality protein multiplex data for the differential abundance analysis of large numbers of proteins from extremely small samples, and is applicable to a broad range of clinical and related applications.     

Decoding 2D-PAGE complex maps: relevance to proteomics

This review describes two mathematical approaches useful for decoding the complex signal of 2D-PAGE maps of protein mixtures. These methods are helpful for interpreting the large amount of data of each 2D-PAGE map by extracting all the analytical information hidden therein by spot overlapping. Here the basic theory and application to 2D-PAGE maps are reviewed: the means for extracting information from the experimental data and their relevance to proteomics are discussed. One method is based on the quantitative theory of statistical model of peak overlapping (SMO) using the spot experimental data (intensity and spatial coordinates). The second method is based on the study of the 2D-autocovariance function (2D-ACVF) computed on the experimental digitised map. They are two independent methods that are able to extract equal and complementary information from the 2D-PAGE map. Both methods permit to obtain fundamental information on the sample complexity and the separation performance and to single out ordered patterns present in spot positions: the availability of two independent procedures to compute the same separation parameters is a powerful tool to estimate the reliability of the obtained results. The SMO procedure is an unique tool to quantitatively estimate the degree of spot overlapping present in the map, while the 2D-ACVF method is particularly powerful in simply singling out the presence of order in the spot position from the complexity of the whole 2D map, i.e., spot trains. The procedures were validated by extensive numerical computation on computer-generated maps describing experimental 2D-PAGE gels of protein mixtures. Their applicability to real samples was tested on reference maps obtained from literature sources. The review describes the most relevant information for proteomics: sample complexity, separation performance, overlapping extent, identification of spot trains related to post-translational modifications (PTMs).     

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.     

Resolution of DNA topoisomerase II by two-dimensional polyacrylamide gel electrophoresis and western blotting.

Eukaryotic DNA Topoisomerase II (Topo II) has been studied using high-resolution two-dimensional polyacrylamide electrophoresis (2D-PAGE) and immunodetection of resolved proteins using specific antisera (Western blotting). Traditional methods of 2D-PAGE failed to resolve Topo II and neither nonequilibrium nor equilibrium pH gradients allowed Topo II to enter the first dimension gel. Exhaustive nuclease digestion and alternate protein solubilization strategies also produced negative results. We have developed altered first dimension pH gradient profiles and employed a more aggressive protein solubilization procedure which resulted in the resolution of Topo II. The 170-kDa polypeptide focuses with an apparent isoelectric point of approximately 6.5.