Rapid re-amplification of PCR products purified in low melting point agarose gels

A rapid, simple method is described for performing sequential amplifications of purified products produced by the PCR. After the initial amplification, an aliquot of the reaction is run on a low melting point agarose gel. A Pasteur pipet is used to punch out a gel plug from the amplified band. The DNA in this plug is then used directly as the template for a second round of amplification. Relatively large amounts of agarose can be tolerated without noticeable effects on amplification. Use of a composite gel made from agarose and linear polyacrylamide increases the ease and utility of this technique. These gels are simple to cast, easier to handle and permit several replicate plugs to be obtained from a single band. This method is well suited to experiments which use "nested" primers to increase the sensitivity and specificity of amplification or any method in which PCR amplification follows DNA purification by electrophoresis in LMP agarose gels.     

The product-selective blot: a technique for measuring enzyme activities in large numbers of samples and in native electrophoresis gels

A method termed "product-selective" blotting has been developed for screening large numbers of samples for enzyme activity. The technique is particularly well suited to detection of enzymes in native electrophoresis gels. The principle of the method was demonstrated by blotting samples from glutaminase (EC 3.5.1.2) or glutamate synthase (EC 1.4.7.1) reactions into an agarose gel embedded with ion-exchange resin under conditions favoring binding of product (glutamate) over substrates and other substances in the reaction mixture. After washes to remove these unbound substances, the product was measured using either fluorometric staining or radiometric techniques. Glutaminase activity in native electrophoresis gels was visualized by a related procedure in which substrates and products from reactions run in the electrophoresis gel were blotted directly into a resin-containing "image gel." Considering the selective-binding materials available for use in the image gel, along with the possible detection systems, this method has potentially broad application.     

Modifications and additions to the ISO-DALT system for two-dimensional gel electrophoresis

Modifications of ISO-DALT devices that further enhance the efficiency and reproducibility of two-dimensional mapping of proteins are described. The principal changes in ISO system devices include the introduction of a gel casting trough with a removable panel to permit the removal of excess gel without introducing air into the electrofocusing gels and the introduction of an upper electrode compartment with a separate watertight septum for each electrofocusing tube to permit tube removal for cleaning and replacement. The principal changes in DALT system devices include the use of modified powder funnels to introduce acrylamide solutions into the slab gel gradient former without aeration; the introduction of a flexible outlet system for the gradient former to facilitate the removal of air bubbles; the introduction of an inexpensive two-part mixing chamber to permit disassembly for cleaning; the use of split gel holders to eliminate deformation and breakage of electrofocusing gels during loading onto slab gels; the introduction of an inexpensive integrated slab gel casting/rotating apparatus; and the introduction of a simple, water-cooled slab gel electrophoresis apparatus to reduce the volume of running buffer used in electrophoresis.     

Application of SYPRO Ruby- and Flamingo-stained polyacrylamide gels to Western blot analysis

Western blot analysis has been a useful method for analysis of expression levels of specific proteins and is conducted after sodium dodecyl sulfate (SDS) or native polyacrylamide gel electrophoresis without staining the gel. However, when it is necessary to analyze the gel, duplicate polyacrylamide gels usually must be prepared, one of which is stained, leading to the consumption of precious sample. Thus, we developed a convenient and efficient Western blotting method using a stained gel. This simple modification should be beneficial for analyzing samples that are limited in quantity and/or samples for which the stained gel serves as the loading control.     

The instantaneous monitoring of polyacrylamide gels during electrophoresis.

The advantages of being able to see protein zones in a gel during electrophoresis (and hence before staining) are pointed out, and a method is described which depends on local increments of refractive index in these zones. The use of local increments of refractive index in polyacrylamide gels for measuring protein concentrations in zones during electrophoresis is briefly considered; it is found that such increments are greater than would be expected from the amount of protein when sodium dodecyl sulphate is present. The enhancement depends on conditions and time of running. This makes quantitative estimates difficult, but the sensitivity of detection of protein zones by observations based on refractive-index changes is greatly increased by this property of sodium dodecyl sulphate. Methods are described for making optically uniform gels (both with uniform and with graded concentrations of polyacrylamide), necessary for observation of small changes in refractive index. A simple dark-field system of observation is described. Examples are given showing protein samples observed with the system during electrophoresis and compared with the same gel stained with Coomassie Blue after completion of the run. Under optimal conditions the optical method is comparable in sensitivity with staining. With the proteins of lower mol.wt. (approx. 15000), the optical method is not so sensitive, becoming less sensitive with longer running time. This loss of sensitivity is greatly decreased by using more concentrated polyacrylamide gels, and graded gels are therefore more suitable for optical observation than are uniform gels. The observation of protein zones during electrophoresis adds nothing to the time needed for making a stained gel and gives much information long before it can be obtained from the stained gel.     

White gels: an easy way to preserve methylene blue stained gels

Methylene blue can be used as a stain for visualizing nucleic acids in polyacrylamide gel electrophoresis. However, its relatively low sensitivity and reversible binding make it a temporary stain that diffuses from the gel relatively fast. Here we describe a very simple method for fixing methylene blue bands in nucleic acid polyacrylamide gels. The procedure makes the methylene blue stain permanent and increases the visibility of the bands, also contributing to increasing the sensitivity of methylene blue.     

Affinity electrophoresis: New simple and general methods of preparation of affinity gels

Two simple and generally applicable methods of preparation of affinity gels for affinity electrophoresis in agarose and polyacrylamide gels are described. In the first method, amino ligands are coupled to periodate-oxidized agarose gel beads (Sepharose 4B), and homogeneous affinity gels are obtained after mixing the melted substituted beads with either melted agarose solution or with the polymerization mixture used for the preparation of polyacrylamide gels. This type of affinity gel was used for affinity electrophoresis of lectins (immobilized p-aminophenyl glycosides), ribonuclease (immobilized uridine 3′,5′-diphosphate 5′-p-aminophenyl ester), trypsin (immobilized p-aminobenzamidine), and double-stranded phage DNA fragments (immobilized acriflavine). Alternatively, heterogeneous affinity gels are prepared from the suspension of ligand-substituted agarose, dextran, or polyacrylamide gel beads in the polymerization solution normally used for preparation of polyacrylamide electrophoretic gels. This technique was used for affinity electrophoresis of lectins, ribonuclease, and trypsin on affinity gels containing appropriate ligands coupled to the gel beads “activated” by various methods. Applicability of affinity gels prepared by the two methods described above for affinity isoelectric focusing is demonstrated.     

Preparations of continuous gradient gel slabs: a simple technique.

A simple technique is described which allows casting of continuous-pore gradient gel slabs without any special equipment. The gels are not linear but satisfactory for all practical purposes. These gels compare favorably with gels made with gradient mixers and with gels obtained commercially, as has been shown by electrophoresis of standard proteins.     

Some improvements in two-dimensional gel electrophoresis of proteins. Protein mapping of eukaryotic tissue extracts.

In the course of adapting O'Farrell's (1975, J. Biol. Chem.250, 4007–4021) two-dimensional separation technique for proteins to eukaryotic material, we have made some modifications. During sample preparation, sodium dodecyl sulfate (SDS) can be included, with a resulting enhancement in reproducibility of gel patterns. However, heating in the presence of SDS leads to artifactual spots in the gels, probably as a result of protein charge modifications. Ultracentrifugation reduces the clogging at the top of the isoelectric focussing gel. For electrophoresis, some modifications of apparatus and technique are suggested. For the analysis of gels, a simple high-efficiency method for the counting of radioactivity in spots from dried gel slabs is described. In addition, an inexpensive microdensitometer option is described for the analysis of the autoradiographs. Patterns of proteins obtained from superior cervical sympathetic ganglia of rats and from other eukaryotic tissues are illustrated. Finally, a few of the proteins commonly found in mammalian tissue are identified on the gels.     

Erratum to “Application of SYPRO Ruby- and Flamingo-stained polyacrylamide gels to Western blot analysis”

Western blots are widely used for analysis of the expression levels of specific proteins. Blotting is conducted after sodium dodecyl sulfate or native polyacrylamide gel electrophoresis without staining the gel. However, when it is necessary to analyze the gel, duplicate polyacrylamide gels (one of which is stained) usually must be prepared, leading to the consumption of precious sample. Thus, we have developed a convenient and efficient Western blot method using a stained gel. This simple modification should be beneficial for the analysis of samples that are limited in quantity and/or samples for which the stained gel serves as the loading control.     

Polar electrophoresis: shape of two-dimensional maps is as important as size

The performance of two-dimensional electrophoresis in conventional gels in Cartesian coordinates (2-DE) vs. polar coordinates (2-PE) is here evaluated. Although 2-DE is performed in much longer Immobiline gels in the first dimension (17 cm) vs. barely 7-cm in 2-PE, an equivalent resolving power is found. Moreover, due to the possibility of running up to seven Immobiline strips in the radial gel format, the reproducibility of spot position is seen to be higher, this resulting in a 20% higher matching efficiency. As an extra bonus, strings of "isobaric" spots (i.e. polypeptides of identical mass with different pI values) are more resolved in the radial gel format, especially in the 10 to 30 kDa region, where the gel area fans out leaving extra space for spot resolution. In conclusion, this novel gel format in the second dimension of 2D gels is seen as an important improvement of this technique, still one of the most popular in proteome analysis.     

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.     

Synthesis and quantitation of glucitollysine, a glycosylated amino acid elevated in proteins from diabetics

A conceptually simple method of vertical gel electrophoresis is presented. It involves the use of pliable plastic envelopes to house individual gels and their constituent buffer reservoirs and electrical systems completely submersed in coolant separate from other gels. In conjunction with a common cooling tank this envelope technique provides unusual versatility for running a variety of different type gels simultaneously.     

Detection of proteolytic enzymes in polyacrylamide gels

Aminopeptidases (1), dipeptidyl aminopeptidases (2), pyrrolidonyl peptidases (3), and carboxypeptidases (4,5) can be detected in polyacrylamide gels with appropriate-β-naphthylamide or carbonaphthoxyamino acid substrates while dipeptidases, tripeptidases (6), carboxypeptidases (7), and aminopeptidases can be detected by the coupled l-amino acid oxidase-peroxidase method of Lewis and Harris (6).In contrast, fewer methods are available for the detection of proteinases in gels. Trypsin-like (8,9) and chymotrypsin-like (5,10) proteinases can be detected with chromogenic β-naphthylamide and β-naphthol ester substrates, but proteinases such as thermolysin (11) and other bacterial neutral metal chelator-sensitive proteinases (12) cannot. For these latter proteinases, whose specificities are directed towards the amino acid residue containing the amino group of the bond to be hydrolyzed, and for proteinases, whose specificities remain to be determined, other methods of detection have to be employed.Uriel and Avrameas (13) detected proteinases in agarose gels by overlaying these gels with a second agarose gel mixture containing the substrate and a suitable pH indicator. However, the method suffers from interference by gel buffers and the instability of the pattern developed. Another procedure is to bring the gel in contact with a gelatinous layer of film material (14,15). This has been done successfully with tissue sections (16), paper electrophoretograms (17) and agarose gel separations (18).The most suitable approach is to diffuse an appropriate protein substrate into the gel after electrophoresis and detect the proteinase activity directly. Several variations of this method have been published (19–22), each with its own advantages and disadvantages. In this report a simple, sensitive method using cytochrome c as substrate, and requiring no staining, is described. This report describes its application to the detection of thermolysin and trypsin in anionic and cationic gel systems, respectively. The method has also been routinely used to locate bacterial and insect proteinases after electrophoresis.     

Simultaneous phenotyping of pig plasma α-protease inhibitors (PI1, PO1A, PO1B, PI2) and four other proteins (PO2, TF, CP, HPX) by a simple method of 2D horizontal electrophoresis

A simple and rapid method of 2D agarose gel (pH 5.4)-horizontal polyacrylamide gel (pH 9.0) electrophoresis was developed for the simultaneous phenotyping of pig plasma alpha-protease inhibitors (protease inhibitor-1 and -2; postalbumin-1A and -1B), postalbumin-2, transferrin, ceruloplasmin and haemopexin. These eight plasma proteins were clearly visible on gels stained with Coomassie Brilliant Blue G250. The 2D patterns and mobilities of several variants of alpha-protease inhibitors were described. By using two agarose gels and 10 polyacrylamide gels, 120 samples were easily analysed in a day. Since alpha-protease inhibitors show extensive polymorphism and as the gene for postalbumin-2 is closely linked to the halothane sensitivity locus Hal, this method is a useful tool for conducting parentage control and for predicting Hal genotypes of individual pigs.     

COST-EFFECTIVE AND EFFICIENT APPARATUS FOR ELECTROELUTION OF MICRO- AND MACROGRAM QUANTITIES OF PROTEINS FROM POLYACRYLAMIDE GELS

Protein recovery from gel electrophoresis plays a significant role in functional genomics and proteomics. To assist in this, a simple, cost-effective, and efficient apparatus for electroelution of proteins has been designed. The performance of the apparatus was demonstrated using the proteins bovine serum albumin (BSA), phosphorylase, ovalbumin, pepsin, and trypsinogen. In all the cases the yield of elution was found to be consistently greater than 85% and the proteins could be eluted without degradation in less than 15 min. The utility of this method can be extended to protein elution from denatured and native polyacrylamide gels, DNA purification from agarose gels, and oligomeric primers purification from polyacrylamide gels. In addition to this, the method offers an effortless purification and characterization of microbial extracellular proteins. The eluted proteins can be directly used in N-terminal amino acid sequencing, and in amino acid and proteomics analyses.     

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.     

One-step casting of Laemmli discontinued sodium dodecyl sulfate-polyacrylamide gel electrophoresis gel

A modified Laemmli sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) protocol is described. The new method saves 30 min for gel casting without loss of the resolution power of Laemmli gel. In this method, both the upper and lower gels can be cast at the same time because the lower gel contains 10% glycerol, which generates higher density in the lower gel than in the upper gel.     

A gel electrophoresis method for quantifying the binding of proteins to specific DNA regions: application to components of the Escherichia coli lactose operon regulatory system.

The use of gel electrophoresis for quantitative studies of DNA-protein interactions is described. This rapid and simple technique involves separation of free DNA from DNA-protein complexes based on differences in their electrophoretic mobilities in polyacrylamide gels. Under favorable conditions both unbound DNA and DNA associated with protein can be quantified. This gel method is applied to the study of the E. coli lactose operon regulatory system. At ionic strengths in the physiological range, the catabolite activator protein (CAP) is shown to form a long-lived complex with the wild type lac promotor, but not with a CAP-insensitive mutant. Formation of a stable "open" or "melted-in" complex of RNA polymerase with the wild type promoter requires the participation of CAP and cyclic AMP. Further, it is demonstrated that even when pre-formed in the presence of CAP-cAMP, the polymerase-promoter open complex becomes unstable if CAP is then selectively removed.