Segregation of membrane components using isoelectric focusing in polyacrylamide gels

A method for efficiently fractionating human erythrocyte membranes into their individual components is presented. This procedure employs isoelectric focusing in polyacrylamide gels after solubilization of the membranes in 8M urea, 0.02M EDTA, 0.2% 2-Me. Electrofocusing of membranes affords higher resolution than previous membrane separation procedures. Also, this method is rapid, requiring 72 hours at most to separate, stain and destain the membrane components in the polyacrylamide gels.     

血清样本双向电泳操作条件的优化

为建立分辨率高、重复性好的血清样品双向电泳技术,本文从血清样品的水化、等电聚焦、胶条的平衡、胶条的染色等几个方面对双向电泳操作条件进行了分析。结果表明采用以下的操作过程可以获得分辨率高、重复性好的双向电泳结果：样品水化2小时（25℃);胶条泡涨12-16小时(25℃);17cm胶条的等点聚焦程序采用 250V线性1小时/1000V线性1小时/4000V线性2小时/8000V线性3小时/8000V线性10小时/500V快速0.5小时/,11cm的胶条的等点聚焦程序采用250V慢速4小时/1000V快速2小时/4000V快速1小时/8000V快速2.5小时/8000V快速7小时/500V快速30分钟;两次平衡各15-20分钟;银染条件为固定两小时或过夜,敏化50-60分钟,定影30-40分钟,显影10分钟左右,终止10分钟）。这一研究对利用双向电泳分析血清蛋白具有很好的参考价值。     

Separation of membrane proteins in an undenatured form by isoelectric focusing

Conditions are described which allow good resolution of membrane proteins in an undenatured form by isoelectric focusing in thin polyacrylamide gels in Triton X-100. High voltages and deionization of the acrylamide are essential. Streaking is grossly reduced by sample application in Bio-Gel P-60, by deionization of the Triton, and dialysis of membrane samples against low ionic strength buffer at slightly alkaline pH. The latter step also greatly improves solubilization of the membrane components. Reproducible isoelectric focusing patterns of proteins from red cell, thyroid, and lymphocyte membrane are presented.     

Improvement of plant protein solubilization and 2-DE gel resolution through optimization of the concentration of Tris in the solubilization buffer

It is important to solubilize acetone-precipitated proteins before isoelectric focusing (IEF) to achieve high resolution 2-DE gels. To resolve the maximum possible number of plant protein spots, we developed an improved solubilization buffer for plant proteins. We demonstrated that the resolution of 2-DE gels increased dramatically as the concentration of Tris-base increased, with maximum solubilization obtained at 200 mM Tris-base (Ly200T). The Ly200T buffer was more effective than the commonly used solubilization buffer containing 40 mM Tris at solubilizing acetone-precipitated plant proteins. Use of the Ly200T buffer to solubilize proteins resulted in an increase in intensity of approximately 30% of plant protein spots in the larger-than-40 kDa region of the gel. The Ly200T buffer also improved the resolution of abundant and basic proteins. Thus, the Ly200T buffer can be used to achieve greater resolution of protein spots in plant proteomics research.     

Separation and identification of 2',3'-cyclic nucleotide 3'-phosphodiesterase on isoelectric focusing gels

A method is presented for the separation and detection of the myelin marker enzyme 2',3'-cyclic nucleotide 3'-phosphodiesterase on isoelectric focusing gels and by immunoblotting. The gel staining procedure is a modification of a method used to demonstrate enzyme activity on blots after sodium dodecyl sulfate-polyacrylamide gel electrophoresis and two-dimensional polyacrylamide gel electrophoresis. The results show that immunologically active 2',3'-cyclic nucleotide 3'-phosphodiesterase can be separated under equilibrium conditions on isoelectric focusing gels with an expanded alkaline pH range after solubilization in a mixture of nonionic/zwitterionic detergents and urea. Enzymatically active 2',3'-cyclic nucleotide 3'-phosphodiesterase focused as two closely spaced bands at pIapp 8.1 and 8.8, respectively, while 2',3'-cyclic nucleotide 3'-phosphodiesterase immunoreactivity was detected as four distinct bands at pIapp 4.2, 7.4, 8.8, and 9.3 and a diffuse band at pIapp 7.9-8.2. By two-dimensional separation these five bands showed molecular weights of about 43-47 kDa, i.e., corresponding to reported values for immunologically active 2',3'-cyclic nucleotide 3'-phosphodiesterase. Since enzyme activity is associated with only two of the bands, nonspecific and artifactual banding due to, e.g., detergent micelle formation, is unlikely.     

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.     

Protein patterns obtained from support-bound gels by combining the images at different stages of destaining

A more informative method for the visualization of proteins on thin-layer gels, based on combining the images of the gel at different stages of destaining, is presented. It is useful whenever important information seems to be lost after prolonged destaining. The method, which makes it unnecessary to run different loads in different channels, has been developed utilizing isoelectric focusing on polyester film-bound agarose gels. The strongly destained gel is superimposed on a negative image of the same gel made at an earlier phase of destaining, thus showing white spots on a gray background for minor components and dark bands in a white field surrounded by the grey background for the abundant ones. In general, the method may be applied to gel images obtained by different staining procedures.     

A procedure for the immunoblotting of proteins separated on isoelectric focusing gels

A method has been devised for performing Western blot assays on proteins resolved by isoelectric focusing. Electrophoretic transfer of proteins directly from isoelectric focusing (IEF) tube gels to nitrocellulose sheets allowed their immunoassay without conventional second dimension SDS gel electrophoresis. The same method can also be used for IEF slab gels. For the immunostaining of nonmuscle actin isoforms in extracts of cultured cells, the resolution of this technique was much improved over that of Western blots of two-dimensional gels.     

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.     

A universal method for two-dimensional polyacrylamide gel electrophoresis of membrane proteins using isoelectric focusing on immobilized pH gradients in the first dimension.

Two-dimensional gel electrophoresis with immobilized pH gradients in the first dimension, initially applied for the separation of soluble and total cellular proteins, has been extended to the analysis of membrane proteins. We show that the usual procedures lead to artifacts and irreproducible results due to aggregation and precipitation of proteins and protein-phospholipid complexes during isoelectric focusing (first dimension) and sodium dodecyl sulfate (SDS) gel electrophoresis (second dimension). Optimized solubilization procedures for hydrophobic membrane proteins are presented and the use of dilute samples is shown to be essential to overcome the major problems in isoelectric focusing. Increased volumes of samples dissolved in rehydration buffer are applied by direct rehydration of dry immobilized pH gradient (IPG) gels. Isoelectric focusing in 2% 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS) without urea gives good results as does 2% Nonidet-P40 with 8 M urea. Heat denaturation should be avoided. An optimized equilibration procedure for IPG gel strips in SDS sample buffer prior to separation in the second dimension was developed that minimizes loss of proteins and results in high-resolution two-dimensional electropherographic maps with a minimum of streaking. The gel strips are partially dehydrated at 40 degrees C and shortly reswollen in situ on the SDS slab gel in SDS-sample buffer containing agarose.     

Scanning isoelectric focusing of cholera enterotoxin in polyacrylamide gels

Scanning isoelectric focusing has been employed for continuous monitoring of the isoelectric spectrum of highly purified cholera enterotoxin in 4% polyacrylamide gels containing 2% ampholytes pH 3–10. The resolution obtained by this technique is of high order because at no instance during focusing interruption of current occurs and thus diffusion of the isolated protein moieties is suppressed. An added aspect of scanning isoelectric focusing was that it allowed estimation of the minimal focusing time of cholera enterotoxin. Thus under the standard assay procedure, the main basic component of cholera enterotoxin was focused in 5800 sec, while the other at least 3 minor acidic and anodic components were focused in approximately 19000 sec. Focusing of cholera enterotoxin in the presence of 6m urea allowed the visualization of 5 well defined and about equal components. The proteinaceous nature of the observed peaks was verified by scanning at wavelengths other than 280 nm, staining of gels for protein, and varying the concentration of the enterotoxin. The design of scanning isoelectric focusing equipment is presented. Reproducibility, economy of sample, and ampholytes and simplicity of experimental technique were some of the features of this apparatus. The resolution of scanning isoelectric focusing was found to be superior to that of ordinary disc and SDS gel electrophoresis.     

Rapid isoelectric focusing in a vertical polyacrylamide minigel system

A rapid method is described for the resolution of proteins employing isoelectric focusing in a vertical polyacrylamide minigel system. Isoelectric focusing can be performed in only 3 h, utilizing low voltage, under either native conditions or denaturing conditions in the presence of 8 M urea. The procedure permits the application of larger sample volumes containing more protein than other isoelectric focusing procedures, and provides the additional advantages of slab gels over tube gels for analytical purposes. The procedure is also well adapted for use in two-dimensional electrophoretic techniques, making it possible to complete a two-dimensional gel in 1 day.     

Use of "submarine" gel electrophoresis for running multiple two-dimensional protein gels

An apparatus commonly used for the electrophoresis of submerged agarose gels was used to separate proteins in the second dimension, after isoelectric focusing in the first dimension. Multiple second-dimension gels were stacked one above the other and run horizontally, submerged in the sodium dodecyl sulfate-containing Laemmli buffer system. The reproducibility of the gels run under these conditions is remarkable and eliminates the need for individual vertical electrophoresis units for routine analysis. The units for submerged horizontal gel electrophoresis are easily made or are inexpensively available commercially.     

Procedure for simultaneous phenotyping of genetic variants in cow's milk by isoelectric focusing

A method is described which allows the simultaneous separation of all polymorphic protein fractions in cow's milk in one single run. The separation could be achieved by isoelectric focusing in ultrathin-layer polyacrylamide gels. The method is especially suitable for screening purposes because it combines low costs, high resolution and short separation time.     

Procedure for simultaneous phenotyping of genetic variants in cow's milk by isoelectric focusing*

A method is described which allows the simultaneous separation of all polymorphic protein fractions in cow's milk in one single run. The separation could be achieved by isoelectric focusing in ultrathin-layer polyacrylamide gels. The method is especially suitable for screening purposes because it combines low costs, high resolution and short separation time.     

Evaluation of an effective sample prefractionation method for the proteome analysis of breast cancer tissue using narrow range two-dimensional gel electrophoresis

One method of improving the protein profiling of complex mammalian proteomes is the use of prefractionation followed by application of narrow pH range two dimensional (2-D) gels. The success of this strategy relies on sample solubilization; poor solubilization has been associated with missing protein fractions and diffuse, streaked, and/or trailing protein spots. In this study, I sought to optimize the solubilization of prefractionated human cancer cell samples using isoelectric focusing (IEF) rehydration buffers containing a variety of commercially available reducing agents, detergents, chaotropes, and carrier ampholytes. The solubilized proteins were resolved on 2-D gels and compared. Among five tested IEF rehydration buffers, those containing 3-[(3-cholamidopropyl)dimethylamino]-1-propane sulfonate (CHAPS) and dithiothreitol (DTT) provided superior resolution, while that containing Nonidet P-40 (NP-40) did not significantly affect protein resolution, and the tributyl phosphine (TBP)-containing buffer yielded consistently poor results. In addition, I found that buffers containing typically high urea and ampholyte levels generated sharper 2-D gels. Using these optimized conditions, I was able to apply 2-D gel analysis successfully to fractionated proteins from human breast cancer tissue MCF-7, across a pH range of 4-6.7.     

A comparison of silver staining methods for detecting proteins in ultrathin polyacrylamide gels on support film after isoelectric focusing

The application of silver staining methods to the detection of proteins on ultrathin isoelectric focusing gel systems requires the optimization of many steps in the procedure in order to obtain reproducible staining of proteins with acceptable levels of background. Three different methods which have been reported for detecting proteins by silver staining in sodium dodecyl sulfate-polyacrylamide gel systems were investigated. A major problem with staining ultrathin isoelectric focusing gels was found to be surface staining that was associated with gels cast on support films. A modification of the method of Poehling and Neuhoff (H.-M. Poehling and V. Neuhoff, 1981, Electrophoresis 2, 141-147) was found to give the best results.     

Isoelectric focusing of proteins in rewetted ultrathin polyacrylamide gel layers

Ultrathin layers of polyacrylamide gel bound to glass can be washed, air-dried, and stored for at least 1 year before rewetting in ampholyte solutions for isoelectric focusing. Short-term drying affects neither fluorescent banding of the ampholytes (not evident in conventional gels) nor resolution of complex protein mixtures while prolonged storage seems to have no deleterious effects. Layers are fully functional after soaking for 10 min in solutions that may contain 8 M urea and 10% sorbitol. Rewetting allows the rapid survey of different ampholytes, gradient stabilizers, separator compounds, or protein reagents and is adaptable to concentration modification of the pH gradient (alone or with a gel overlay), to focusing in a transverse urea gradient, and to electrophoresis across a preformed pH gradient. The procedure avoids protein modification by residual polymerizing reagents while adding to the convenience and economy of using ultrathin layers in relatively small formats.     

Gel Electrophoresis of Chloroplast Polypeptides: Comparison of One-Dimensional and Two-Dimensional Gel Analyses of Chloroplast Polypeptides From Euglena gracilis

Euglena chloroplast polypeptides are resolved by an adaptation of the two-dimensional gel electrophoretic technique of O'Farrell (1975 J Biol Chem 250: 4007-4021). The present results are compared with those obtained by our earlier two-dimensional gel analyses as well as those obtained by one-dimensional gel analyses. Up to 75 micrograms of Euglena chloroplast polypeptides are resolved on one-dimensional sodium dodecylsulfate linear gradient 7.5 to 15% polyacrylamide gels into 43 stained polypeptide bands compared to only 33 bands resolved on a similar gel containing only 10% polyacrylamide. In contrast, two-dimensional gel electrophoresis (isoelectric focusing for the first dimension, sodium dodecylsulfate gel electrophoresis for the second dimension) further improves the resolution of the chloroplast polypeptides and especially so when a linear gradient gel is used for the second dimension. Delipidation of Euglena chloroplasts with acetone-ether and subsequent solubilization of polypeptides with Triton X-100 followed by sonication are all necessary for successful resolution of chloroplast polypeptides on two-dimensional gels. Up to 300 micrograms of chloroplast polypeptides can be clearly resolved into 56 to 59 stainable spots by the present two-dimensional gel technique when a linear gradient gel is used for the second dimension. Thus, about 30% of the polypeptide bands on a one-dimensional gel are separated into multiple polypeptides on a two-dimensional gel. The use of two-dimensional gels to separate labeled polypeptides with subsequent detection of labeled spots by autoradiography or fluorography again improves the resolution of the chloroplast polypeptides. For example, when ³⁵S-labeled chloroplast polypeptides are separated by the present two-dimensional gel technique with a linear gradient polyacrylamide gel in the second dimension, autoradiography or fluorography detects over 80 individual polypeptide spots. This is about twice the number resolved by our previous analyses which used a 10% polyacrylamide gel in the second dimension. Polypeptides detected range in molecular weight from about 8.5 to about 145 kilodaltons with apparent isoelectric points from pH 4.5 to 8.0. Fluorography provides rapid detection of labeled polypeptides and is 10 times more sensitive than autoradiography.     

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.