Factors affecting polyacrylamide gel electrophoresis and electroblotting of high-molecular-weight myofibrillar proteins

Electrophoresis of the high-molecular-mass proteins (greater than 500 kDa) of muscle myofibrils is difficult using conventional procedures. The mobility of these proteins was influenced by the heating time in sample buffer, the use of 2-mercaptoethanol in the upper reservoir buffer, and the pH of the resolving gel in a stacking sodium dodecyl sulfate gel system. Heating samples for 4 min (versus shorter times), addition of 2-mercaptoethanol to the upper reservoir buffer, and reducing the pH of the resolving gel to 8.6 all enhanced the mobility and resolution of the high-molecular-weight proteins on polyacrylamide gels. The sulfhydryl reducing agents commonly used in protein sample buffers (2-mercaptoethanol and dithiothreitol) were found to migrate at the electrophoretic dye front. Inclusion of 10 mM 2-mercaptoethanol in the upper reservoir buffer or blocking free sulfhydryl groups with N-ethylmaleimide prevented intermolecular disulfide bond formation during electrophoresis. The addition of 10 mM 2-mercaptoethanol to the buffer used for electroblotting also improved efficiency of protein transfer to nitrocellulose.     

Gel electrophoresis of protein-dodecyl sulfate complexes in a pH gradient and improved resolution of poliovirus polypeptides.

Electrophoresis of poliovirus capsid polypeptides and of nonviral test proteins was carried out in 12.5% acrylamide gels in the presence of sodium dodecyl sulfate. The gels were prepared at pH 7.2. The electrode buffers were (i) both at pH 7.2 (normal conditions), (ii) both at pH 9, 10, or 11, or (iii) the catholyte was at pH 11 and the anolyte was at pH 6.5. The VP1 = 3 group of poliovirus polypeptides yielded the classical three bands under the first (i) set of conditions, except that VP2 and VP3 each yielded two bands in protracted runs; up to six bands were obtained under the second (ii) and third (iii) sets of conditions. When the catholyte was pH 11, there was a molecular weight-dependent, progressive deceleration of the migration of all proteins. In addition, a pH gradient was formed in the gels, and these expanded markedly. The improved resolution of the poliovirus polypeptides is discussed in the light of these observations.     

Factors affecting polyacrylamide gel electrophoresis and electroblotting of high-molecular-weight myofibrillar proteins myofibrillar proteins

Electrophoresis of the high-molecular-mass proteins (>500 kDa) of muscle myofibrils is difficult using conventional procedures. The mobility of these proteins was influenced by the heating time in sample buffer, the use of 2-mercaptoethanol in the upper reservoir buffer, and the pH of the resolving gel in a stacking sodium dodecyl sulfate gel system. Heating samples for 4 min (versus shorter times), addition of 2-mercaptoethanol to the upper reservoir buffer, and reducing the pH of the resolving gel to 8.6 all enhanced the mobility and resolution of the high-molecular-weight proteins on polyacrylamide gels. The sulfhydryl reducing agents commonly used in protein sample buffers (2-mercaptoethanol and dithiothreitol) were found to migrate at the electrophoresic dye front. Inclusion of 10 mm 2-mercaptoethanol in the upper reservoir buffer or blocking free sulfhydryl groups with N-ethylmaleimide prevented intermolecular disulfide bond formation during electrophoresis. The addition of 10 mm 2-mercaptoethanol to the buffer used for electroblotting also improved efficiency of protein transfer to nitrocellulose.     

Ribulose diphosphate carboxylase/oxygenase. III. Isolation and properties.

Similarities in properties of ribulose diphosphate carboxylase and oxygenase activities further substantiate the hypothesis that the same protein catalyzes both reactions. The Km (ribulose diphosphate) is 0.33 mM for the ribulose diphosphate oxygenase, when assayed in air with an oxygen electrode. Maximum activity is obtained with 10 to 35 mM MgCl2. Higher MgCl2 concentrations are inhibitory, but they shift the pH optimum from 9.3 or 9.4 to 8.7 or 9.0. MnCl2 is an effective cofactor of the oxygenase and some activity is obtained with CoCl2. Both the ribulose diphosphate carboxylase and oxygenase activity of the purified protein from spinach leaves are slowly inactivated by storage at 0 degrees and reactivated in 10 min at 50 degrees, provided both 25 mM MgCl2 and 1 mM dithiothreitol are present. The sulfhydryl groups of the enzyme which react rapidly with 5,5'-dithiobis(2-nitrobenzoic acid) are approximately 4 at pH 7.8 and 11 at pH 9.4. At both pH values ribulose diphosphate prevents two of these sulfhydryl groups from reacting with this reagent. About 50% inhibition of the oxygenase activity at pH 9.0 occurs with 50 mM bicarbonate in the presence of 3 mM ribulose diphosphate, and from variations in these parameters the inhibition is attributed to the CO2 species. The purified enzyme of acrylamide gels prevented the reduction of nitroblue tetrazolium in the presence of the superoxide radical, but the enzyme in solution did not react as a superoxide dismutase.     

Polymerization of acrylamide at acid pH using uranyl nitrate

A new photopolymerizing reagent, uranyl nitrate, is used for the polymerization of acrylamide gels at low pH. The amount of uranyl nitrate (0.2 mg/ml) required for the polymerization of gels at pH 3.0 is considerably less than that of persulfate (7 mg/ml). Use of this reagent obviates the need for the removal of excess of persulfate by preelectrophoresis. The electrophoretic separation of basic proteins in uranium-polymerized gels showed faster movement and better resolution of proteins and proved the gels to be versatile, uniform, and reproducible. Electrophoresis of trypsin in these gels does not affect the enzymatic activity. The catalyst can also be used for the polymerization of gels containing 3 M urea.     

Problems encountered in measuring erythrocyte pyrimidine 5'-nucleotidase activity

An improved method of two-dimensional electrophoresis that allows unequilibrated first-dimension gels to be loaded and electrophoresed on second-dimension gels twice the length used in the O'Farrell technique has been developed. Normally, the electrophoresis of unequilibrated first-dimension gels on long second-dimension gels with the resolving gel set at pH 8.8 results in poor resolution of low-molecular-weight proteins. Adjusting the pH of the resolving gel to pH 8.3 maintains the low-molecular-weight proteins in a stacked configuration during their migration through the length of the 10% acrylamide gel. Utilization of a 10 to 20% exponential polyacrylamide gradient in a resolving gel set at pH 8.3 separates these low-molecular-weight proteins with excellent resolution. Electrophoretic resolution of protein spots in resolving gels set at pH 8.8 is not as sharp as in gels set at pH 8.3, and resolution progressively deteriorates in gels set at higher pH values.     

Tricine-sodium dodecyl sulfate-polyacrylamide gel electrophoresis for the separation of proteins in the range from 1 to 100 kDa

A discontinuous sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) system for the separation of proteins in the range from 1 to 100 kDa is described. Tricine, used as the trailing ion, allows a resolution of small proteins at lower acrylamide concentrations than in glycine-SDS-PAGE systems. A superior resolution of proteins, especially in the range between 5 and 20 kDa, is achieved without the necessity to use urea. Proteins above 30 kDa are already destacked within the sample gel. Thus a smooth passage of these proteins from sample to separating gel is warranted and overloading effects are reduced. This is of special importance when large amounts of protein are to be loaded onto preparative gels. The omission of glycine and urea prevents disturbances which might occur in the course of subsequent amino acid sequencing.     

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.     

Sulfhydryl oxidase-catalyzed formation of disulfide bonds in reduced ribonuclease

Sulfhydryl oxidase isolated from bovine skim milk membrane vesicles catalyzes de novo formation of disulfide bonds with the substrates cysteine, cysteine-containing peptides, and reduced proteins using molecular oxygen as the electron acceptor. Initial rates for sulfhydryl oxidase-catalyzed oxidation of reduced ribonuclease exhibited typical Michaelis-Menten kinetics at low substrate concentrations. Substrate inhibition of the oxidative activity was observed at ribonuclease concentrations greater than 40 microM, similar to that observed with reduced glutathione or other small thiol substrates. The inhibition was more pronounced when ribonuclease activity was used to monitor the rates, presumably due to concentration-dependent formation of nonnative disulfide bonds. Thus, a maximum in the rate of regain of ribonuclease activity was observed at a 40 microM concentration, while optimum recovery was observed at 30 microM. The Michaelis constant obtained with reduced ribonuclease is 17.4 microM which corresponds to a sulfhydryl concentration of 0.14 mM, a value that compares favorably with the best small thiol substrate, reduced glutathione. Disulfide-containing intermediates in the oxidation pathway, as determined by ion-exchange chromatography of alkylated reaction mixtures, appeared to be similar for air oxidation and enzyme-catalyzed oxidation of the protein. The pH optimum, tissue location, and kinetic characteristics of sulfhydryl oxidase are compatible with a suggested physiological function of direct catalysis of disulfide bond formation in secretory proteins or indirect participation through provision of oxidized glutathione for protein disulfide-isomerase-catalyzed thiol/disulfide interchange.     

Effect of pH and acrylamide concentration on the separation of lipopolysaccharides in polyacrylamide gels

The technique of sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was used to separate the O-antigen of three strains ofPseudomonas aeruginosa, two strains, ofSalmonella typhimurium, and one strain ofEscherichia coli. No significant difference in separation and migration rate of sample was seen at the various acrylamide gel concentrations used. However, samples electrophoresed through acrylamide running gels at pH 6.8 migrated faster and the resolution of the high-molecular-weight O-antigen bands was greater than of the samples separated in gels at pH 8.8. On the basis of our observations, we could conclude that separation of the heterogeneous O-antigen in SDS-PAGE is probably due to differences in their charge densities and their molecular sizes. Also, pH 6.8 resolving gels are especially useful in the separation of high-molecular-weight O-antigen for epitope mapping by reaction with monoclonal antibodies in Western immunoblotting.     

Detection of arylsulfatase A activity after electrophoresis in polyacrylamide gels: problems and solutions.

When arylsulfatase extracted from normal human skin fibroblasts was electrophoresed in polyacrylamide gels with a Tris-glycine buffer at pH 8.4–8.6, two problems occurred. First, no arylsulfatase A activity was detected. Second, an artifactual fluorescent spot was generated when the gels were stained for arylsulfatase activity with 4-methylumbelliferyl sulfate as substrate. The artifact simulated arylsulfatase A activity in mobility but also appeared when 4-methylumbelliferyl substrates for other enzymes were used. It can be eliminated by prerunning or prolonged storage of the gets before use. The arylsulfatase A activity, however, could be recovered only when a low pH buffer system (pH 58–68) was used for electrophoresis. The highest percentage recovery (70%) of activity was obtained in acrylamide gels polymerized with ammonium persulfate, prerun for 0.5 h before use and electrophoresed with an anode buffer of acetic acid-triethanolamine at pH 5.8.     

Efficient transfer of proteins from acetic acid-urea and isoelectric-focusing gels to nitrocellulose membrane filters with retention of protein antigenicity

A method which facilitates the rapid and quantitative electrophoretic transfer of proteins from gels not containing sodium dodecyl sulfate (SDS) to nitrocellulose membranes is described. The equilibration of non-SDS-polyacrylamide gel electrophoretic gels in a buffer containing SDS confers a net negative charge to the proteins present, presumably as a result of the formation of SDS-protein complexes. Proteins from gels equilibrated in the SDS buffer and then electroblotted in a Tris-glycine buffer at pH 8.3 are transferred with much greater efficiency than are proteins from untreated gels. The method has been shown to significantly enhance the electrophoretic transfer of polyoma viral proteins resolved in either acetic acid-urea or isoelectric-focusing gels to nitrocellulose membranes, and it is suggested that the method should have universal applicability to all gel electrophoresis systems currently employed. The proteins from isoelectric-focusing gels treated with SDS and transferred to nitrocellulose membranes were found to retain antigenicity to antisera prepared against either denatured or native viral proteins.     

Sample prefractionation with Sephadex isoelectric focusing prior to narrow pH range two-dimensional gels

Due to their heterogeneity and huge differences in abundance, the detection and identification of all proteins expressed in eukaryotic cells and tissues is a major challenge in proteome analysis. Currently the most promising approaches are sample prefractionation procedures prior to narrow pH range two-dimensional gel electrophoresis (IPG-Dalt) to reduce the complexity of the sample and to enrich for low abundance proteins. We recently developed a simple, cheap and rapid sample prefractionation procedure based on flat-bed isoelectric focusing (IEF) in granulated gels. Complex sample mixtures are prefractionated in Sephadex gels containing urea, zwitterionic detergents, dithiothreitol and carrier ampholytes. After IEF, up to ten gel fractions alongside the pH gradient are removed with a spatula and directly applied onto the surface of the corresponding narrow pH range immobilized pH gradient (IPG) strips as first dimension of two-dimensional (2-D) gel electrophoresis. The major advantages of this technology are the highly efficient electrophoretic transfer of the prefractionated proteins from the Sephadex IEF fraction into the IPG strip without any sample dilution, and the full compatibility with subsequent IPG-IEF, since the prefactionated samples are not eluted, concentrated or desalted, nor does the amount of the carrier ampholytes in the Sephadex fraction interfere with subsequent IPG-IEF. Prefractionation allows loading of higher protein amounts within the separation range applied to 2-D gels and facilitates the detection of less abundant proteins. Also, this system is highly flexibile, since it allows small scale and large scale runs, and separation of different samples at the same time. In the current study, this technology has been successfully applied for prefractionation of mouse liver proteins prior to narrow pH range IPG-Dalt.     

Enhanced analysis of human breast cancer proteomes using micro-scale solution isoelectrofocusing combined with high resolution 1-D and 2-D gels

Current methods for quantitatively comparing proteomes (protein profiling) have inadequate resolution and dynamic range for complex proteomes such as those from mammalian cells or tissues. More extensive profiling of complex proteomes would be obtained if the proteomes could be reproducibly divided into a moderate number of well-separated pools. But the utility of any prefractionation is dependent upon the resolution obtained because extensive cross contamination of many proteins among different pools would make quantitative comparisons impractical. The current study used a recently developed microscale solution isoelectrofocusing (musol-IEF) method to separate human breast cancer cell extracts into seven well-resolved pools. High resolution fractionation could be achieved in a series of small volume tandem chambers separated by thin acrylamide partitions containing covalently bound immobilines that establish discrete pH zones to separate proteins based upon their pIs. In contrast to analytical 2-D gels, this prefractionation method was capable of separating very large proteins (up to about 500 kDa) that could be subsequently profiled and quantitated using large-pore 1-D SDS gels. The pH 4.5-6.5 region was divided into four 0.5 pH unit ranges because this region had the greatest number of proteins. By using very narrow pH range fractions, sample amounts applied to narrow pH range 2-D gels could be increased to detect lower abundance proteins. Although 1.0 pH range 2-D gels were used in these experiments, further protein resolution should be feasible by using 2-D gels with pH ranges that are only slightly wider than the pH ranges of the musol-IEF fractions. By combining musol-IEF prefractionation with subsequent large pore 1-D SDS-PAGE (>100 kDa) and narrow range 2-D gels (<100 kDa), large proteins can be reliably quantitated, many more proteins can be resolved, and lower abundance proteins can be detected.     

Detection of myofibrillar proteins using a step gradient minigel with an ambiguous interface

Myosin heavy chain (MHC), actin, titin, and nebulin are four major myofibrillar proteins that interact with each other. However, it is difficult to analyze the four proteins simultaneously on the same minigel due to their broad range of molecular weights. Numerous gradient gels are normally used to detect these myofibrillar proteins. The conventional step gradient gel provides better separation of the four major proteins, but several proteins accumulate at the interfaces between different gradient layers. To eliminate the obvious interfaces, we employed a plastic syringe filled with 12 and 4% acrylamide solutions simultaneously and then established an improved step gradient minigel with an ambiguous interface. It was determined by blue dextran in-gel visualization and scanning densitometry that the acrylamide concentration at the ambiguous interface gradually changed. Coomassie blue staining and immunoblotting revealed that the four proteins were successfully separated and transferred for analysis. This gel system is simple to prepare and easy to use, and it is a reliable method for analyzing myofibrillar proteins or other protein mixtures with broad molecular masses.     

The removal of exogenous thiols from proteins by centrifugal column chromatography

Centrifugal column chromatography was shown to provide a rapid, efficient, and useful means of separation of various low molecular weight thiols from proteins. The single chromatographic step procedure employed standard 5 ml plastic syringes containing Sephadex G-25 as the bed matrix and required less than 5 min to produce average dilutions of 5000-, 980-, and 25-fold, respectively, from 5 to 200 mM initial concentrations of 2-mercaptoethanol, dithiothreitol, and reduced glutathione in the sample as measured by titration with 5,5'-dithiobis-(2-nitrobenzoic acid). Dihydrofolate reductase solutions of 0.07-0.08 mM were separated from 50 mM 2-mercaptoethanol, dithiothreitol, or reduced glutathione with a minimum 16,500-fold dilution of the thiol after centrifugal chromatography on two consecutive columns. Thymidylate synthase solutions of 0.06 mM were effectively separated from 50 mM 2-mercaptoethanol or dithiothreitol with a minimum average 5900-fold dilution of the thiol after consecutive column chromatography. There was no change in either the physical or chemical properties of the enzyme throughout the course of the experiments as determined by activity, active site sulfhydryl group titration, and binding assays. Recoveries of protein obtained in the load fraction were usually in excess of 70% of the protein loaded with virtually no dilution from the initial concentration. This method was developed in order to facilitate the study of the active site sulfhydryl groups in enzymes.     

Optimization of paper bridge loading for 2-DE analysis in the basic pH region: application to the mitochondrial subproteome

Separation of basic proteins with 2-DE presents technical challenges involving protein precipitation, load limitations, and streaking. Cardiac mitochondria are enriched in basic proteins and difficult to resolve by 2-DE. We investigated two methods, cup and paper bridge, for sample loading of this subproteome into the basic range (pH 6-11) gels. Paper bridge loading consistently produced improved resolution of both analytical and preparative protein loads. A unique benefit of this technique is that proteins retained in the paper bridge after loading basic gels can be reloaded onto lower pH gradients (pH 4-7), allowing valued samples to be analyzed on multiple pH ranges.     

Polyacrylamide gel electrophoresis: reaction of acrylamide at alkaline pH with buffer components and proteins

The chemical reaction of monomeric acrylamide with primary, secondary, and tertiary amines, used as buffer components in polyacrylamide gel electrophoresis systems, was investigated in the basic pH range. Adduct formation proceeded for several minutes up to weeks, depending on the reactivity of the amino groups. A pH shift in the reaction mixture due to an altered pK value of the reaction product was observed. However, a few primary amines (tris(hydroxymethyl)aminomethane, 2-amino-2-methyl-1,3-propanediol) and secondary amines 3-([2-hydroxy-1,1-bis(hydroxymethyl)ethyl]amino)-1-propanesulfonic acid, 3-(dimethyl(hydroxymethyl)methylamino)-2-hydroxypropanesulfonic acid) showed negligible shifts of pH. They are, therefore, useful as components in the polymerization mixture; whereas some tertiary amines showing complete pH stability as well (e.g., triethanolamine) are not suitable, as they acted as accelerators of gel polymerization. Acrylamide can also covalently bind to proteins by reacting with the epsilon-amino group of lysine residues, especially. Bovine serum albumin, having an acidic isoelectric point, and the basic protein cytochrome c were treated with different acrylamide concentrations at alkaline pH yielding modified protein molecules with altered electrophoretic mobilities in different polyacrylamide gel electrophoresis systems. This reaction gave rise to artifacts in alkaline polyacrylamide gels and isoelectric focusing systems when residual acrylamide monomers were still present in the gel matrix after the polymerization process ceased.     

Sulfhydryl oxidase from egg white. A facile catalyst for disulfide bond formation in proteins and peptides.

Both metalloprotein and flavin-linked sulfhydryl oxidases catalyze the oxidation of thiols to disulfides with the reduction of oxygen to hydrogen peroxide. Despite earlier suggestions for a role in protein disulfide bond formation, these enzymes have received comparatively little general attention. Chicken egg white sulfhydryl oxidase utilizes an internal redox-active cystine bridge and a FAD moiety in the oxidation of a range of small molecular weight thiols such as glutathione, cysteine, and dithiothreitol. The oxidase is shown here to exhibit a high catalytic activity toward a range of reduced peptides and proteins including insulin A and B chains, lysozyme, ovalbumin, riboflavin-binding protein, and RNase. Catalytic efficiencies are up to 100-fold higher than for reduced glutathione, with typical K(m) values of about 110-330 microM/protein thiol, compared with 20 mM for glutathione. RNase activity is not significantly recovered when the cysteine residues are rapidly oxidized by sulfhydryl oxidase, but activity is efficiently restored when protein disulfide isomerase is also present. Sulfhydryl oxidase can also oxidize reduced protein disulfide isomerase directly. These data show that sulfhydryl oxidase and protein disulfide isomerase can cooperate in vitro in the generation and rearrangement of native disulfide pairings. A possible role for the oxidase in the protein secretory pathway in vivo is discussed.