A rapid and effecient method for the isolation of proteins from polyacrylamide cells.

A procedure is described for the rapid and efficient electrophoretic elution of protein from polyacrylamide gels which is then collected in a dialysis bag tied to the end of a tube containing the gel slices. To illustrate the method a heterogeneous preparation of alkaline phosphatase was used from which a single homogeneous component was isolated in six hours with a recovery of 86%. The eluted protein is collected in a volume which can easily be kept below 1.5 ml, thus eliminating the need for subsequent concentration. The method has also been used successfully in two other systems in which a human lung tumor-associated antigen and glycogen synthetase from yeast were isolated. Since the method utilizes a standard analytical gel electrophoresis apparatus with no modifications or accessories, it should be immediately applicable for the isolation of many different proteins from polyacrylamide gels.     

Pouring and Running a Protein Gel by reusing Commercial Cassettes

The evaluation of proteins using sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) analysis is a common technique used by biochemistry and molecular biology researchers^1-4. For laboratories that perform daily analyses of proteins, the cost of commercially available polyacrylamide gels (˜$10/gel) can be considerable over time. To mitigate this cost, some researchers prepare their own polyacrylamide gels. Traditional methods of pouring these gels typically utilize specialized equipment and glass gel plates that can be expensive and preclude pouring many gels and storing them for future use. Furthermore, handling of glass plates during cleaning or gel pouring can result in accidental breakage creating a safety hazard, which may preclude their use in undergraduate laboratory classes. Our protocol demonstrates how to pour multiple protein gels simultaneously by recycling Invitrogen Nupage Novex minigel cassettes, and inexpensive materials purchased at a home improvement store. This economical and streamlined method includes a way to store the gels at 4°C for a few weeks. By re-using the plastic gel cassettes from commercially available gels, labs that run frequent protein gels can save significant costs and help the environment. In addition, plastic gel cassettes are extremely resistant to breakage, which makes them ideal for undergraduate laboratory classrooms.     

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.     

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.     

Visualization of proteins in acrylamide gels using ultraviolet illumination.

Proteins in polyacrylamide gels can be rapidly visualized by soaking in trichloroacetic acid or chloroform followed by illumination with UV light. The UV-light-driven reaction of tryptophan in the presence of trichlorocompounds yields products that emit sufficiently in the visible region to identify the location of the protein bands on the gel. This method can be used to rapidly identify protein bands on a gel in less than 20 min. On thin polyacrylamide gels, 1.0 microg of protein can easily be detected for proteins with typical tryptophan percentages.     

Electrophoretic separation of large proteoglycans in large-pore polyacrylamide gradient gels (1.32-10.0% T) and a one-step procedure for simultaneous staining of proteins and proteoglycans.

A procedure is described for the preparation of 1.32-10% polyacrylamide gradient gels. Loose polyacrylamide gel on the top side of the gradient was stabilized with a layer of 0.4% agarose gel which also formed sample wells. The upper limit of separation achieved in these gels was estimated to be approximately 2 X 10(6) using globular protein standards. However, large aggregating proteoglycans from cartilage which have a molecular weight range of 1-4 X 10(6) penetrate and separate in these gels. A simple one-step procedure is also described for simultaneous staining of proteins and large proteoglycans in polyacrylamide gels.     

Visible fluorescent detection of proteins in polyacrylamide gels without staining

2,2,2-Trichloroethanol (TCE) incorporated into polyacrylamide gels before polymerization provides fluorescent visible detection of proteins in less than 5min of total processing time. The tryptophans in proteins undergo an ultraviolet light-induced reaction with trihalocompounds to produce fluorescence in the visible range so that the protein bands can be visualized on a 300-nm transilluminator. In a previous study trichloroacetic acid or chloroform was used to stain polyacrylamide gel electrophoresis (PAGE) gels for protein visualization. This study shows that placing TCE in the gel before electrophoresis can eliminate the staining step. The gel is removed from the electrophoresis apparatus and placed on a transilluminator and then the protein bands develop their fluorescence in less than 5min. In addition to being rapid this visualization method provides detection of 0.2microg of typical globular proteins, which for some proteins is slightly more sensitive than the standard Coomassie brilliant blue (CBB) method. Integral membrane proteins, which do not stain well with CBB, are visualized well with the TCE in-gel method. After TCE in-gel visualization the same gel can then be CBB stained, allowing for complementary detection of proteins. In addition, visualization with TCE in the gel is compatible with two-dimensional PAGE, native PAGE, Western blotting, and autoradiography.     

Peptide production from proteins separated by sodium dodecyl-sulfate polyacrylamide gel electrophoresis

The development of amino acid sequencers with subnanomolar sensitivities has increased the need for both selective and highly efficient methods for both protein and peptide isolation. In this paper, we describe a simple procedure that utilizes the high resolving capacity of polyacrylamide gel electrophoresis to isolate a single target polypeptide, which can subsequently be subjected to proteolytic digestion and sequencing. Polypeptides are visualized in polyacrylamide gels as dodecyl sulfate/protein complexes, which are passively diffused from gel slices. Free dodecyl sulfate eluted with the protein solution is removed by KCl precipitation, allowing protein digestion with small amounts of trypsin or other proteolytic enzymes. Following enzymatic digestion, the peptide solution is made 6 M guanidine-HCl to remove interfering contaminants and thereby improve resolution of the digest by reverse-phase high-performance liquid chromatography. The peptides generated by this method are suitable for amino acid sequencing with good overall yields, averaging 15-30% on a gas-phase sequenator. The method described is useful for obtaining multiple peptide sequences from a single polypeptide isolated from a complex protein mixture.     

Native gel activity stain and preparative electrophoretic method for the detection and purification of pyridine nucleotide-linked dehydrogenases

An activity stain for the detection of pyridine nucleotide-linked dehydrogenases in polyacrylamide gels is described. Following incubation of the gel with substrate and cofactor, bands are visualized under ultraviolet light, where reduced cofactors fluoresce and oxidized cofactors appear black. The methods described are useful for any NAD- or NADP-linked dehydrogenase; the enzymes can be assayed in either the oxidative or the reductive direction. Also described is a preparative polyacrylamide gel system using the activity stain, which can be used as a general purification method for dehydrogenases. The preparative gels are crosslinked with bisacrylylcystamine. These crosslinks can be broken by the addition of thiols after the bands of interest have been located and excised. The protein of interest is then separated from the solubilized acrylamide by adsorption to a suitable resin.     

Destaining of Coomassie Brilliant Blue R-250-stained polyacrylamide gels with fungal laccase

An enzyme-based method for destaining polyacrylamide gels stained with Coomassie Brilliant Blue R-250 is described. Distilled water supplemented with diluted fermentation broth of a laccase-producing white-rot fungus, Cerrena sp., was used for gel destaining, and a clear gel background was obtained in 2 h at 37 °C. Sensitivity of protein detection was 10 ng. The method did not require organic solvents or changing the destaining solution. Due to simultaneous gel destaining and dye decolorization, the colorless destaining solution can be disposed of directly. Laccase destaining of polyacrylamide gels was simple, efficient, and environmentally friendly.     

Isolation and characterization of vitellin from the fruitfly,Dacus oleae

Vitellin was isolated from mature eggs of Dacus oleae. A combination of anion-exchange chromatography and gel filtration was used for purification of the protein. The molecular weight of isolated vitellin, as determined by Sephacryl S-300 chromatography, was approximately 300,000. Electrophoresis on SDS-polyacrylamide gels demonstrated the presence of vitellin subunits with molecular weight of 47,000 and 49,000. Isoelectric focusing on polyacrylamide gels revealed a series of polypeptides with isoelectric points covering an acidic pH region of 5.7 to 6.2. Immunodiffusion, immunoelectrophoresis, and immunoblotting were used for further characterization of vitellin.     

Electrophoretic elution of macromolecules from polyacrylamide or agarose gels

A method for elution of micrograms of macromolecules from polyacrylamide and agarose gels is described. The recoveries were greater than 90% with three different macromolecules tested (28 to 360 kDa). An amount as small as 1 microgram of human serum albumin was eluted from polyacrylamide gel with 90% recovery. The eluted material is collected into a small chamber the size of which can be changed as required. Elution and concentration are achieved simultaneously and in one step under mild conditions. Sterile eluates can be obtained, if the apparatus is constructed under sterile conditions.     

Isolation of messenger RNA coding for eggshell protein of the DNA-eliminating nematode Ascaris lumbricoides

Poly(A)-containing RNA from polyploid uterine epithelial cells of Ascaris lumbricoides has been isolated by poly(U)-Sepharose chromatography. The bulk of poly(A)-containing RNA migrates as 18-S RNA in formamide/polyacrylamide gels. In a cell-free wheat germ system, this RNA directs the synthesis of a polypeptide with identical migration behavior in dodecylsulphate/urea/polyacrylamide gels as the polypeptide isolated from the proteinaceous eggshell. The two proteins reveal almost identical peptide patterns in fingerprint analysis. The authentic eggshell protein has been identified as a glycoprotein with a molecular weight of about 10000, as determined by dodecylsulphate/polyacrylamide gel electrophoresis. The apparent discrepancy between mRNA length and the required coding length for the protein is discussed.     

Protein purification from polyacrylamide gels by sonication extraction

A protein purification procedure using sonication extraction from polyacrylamide gels (PAGE), which involves identification of a particular protein band and its excision, homogenization, sonication, and subsequent passage through a Sephadex G-25 minicolumn, is reported. Our results show a high degree of recovery regardless of the nature of the protein (soluble or membrane bound) or the characteristics of the gel (SDS-PAGE, native gels, or Tricine-SDS-PAGE). The percentage of recovery was dependent on the protein concentration applied in the gel. This technique is fast, gives high yield, provides good resolution, and can be used without any specialized equipment. The method was tested with a wide variety of membranes and soluble proteins and was found to give good results and to be applicable to different studies. The amino acid sequence of one of the purified proteins (Rf 0.45 stallion ejaculated sperm protein) was determined successfully.     

Peptide mapping by limited proteolysis in sodium dodecyl sulfate and analysis by gel electrophoresis.

A rapid and convenient method for peptide mapping of proteins has been developed. The technique, which is especially suitable for analysis of proteins that have been isolated from gels containg sodium dodecyl sulfate, involves partial enzymatic proteolysis in the presence of sodium dodecyl sulfate and analysis of the cleavage products by polyacrylamide gel electrophoresis. The pattern of peptide fragments produced is characteristic of the protein substrate and the proteolytic enzyme and is highly reproducible. Several common proteases have been used including chymotrypsin, Staphylococcus aureus protease, and papain.     

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.     

Bulk and micropatterned conjugation of extracellular matrix proteins to characterized polyacrylamide substrates for cell mechanotransduction assays

Increasing numbers of cell mechanotransduction studies are currently utilizing elastic substrates fabricated from polyacrylamide in the form of thin gels. Their versatility depends on the ability to ensure the appropriate gel stiffness and control the uniformity and geometry of extracellular matrix protein coating of the gel. Beginning with a brief quantitative emphasis on the elastic properties of polyacrylamide gels, we present an inexpensive and highly reproducible method for uniform coating with a wide variety of extracellular matrix proteins. We used a reducing agent, hydrazine hydrate, to modify nonreactive amide groups in polyacrylamide to highly reactive hydrazide groups that can form covalent bonds with aldehyde or ketone groups in oxidized proteins. This simple conjugation method overcomes the limitations of previously used photoactivatable cross-linkers: nonuniform coating due to nonuniformity of irradiation and technically challenging procedures for micropatterning. As demonstrated in our study of cell polarity during constrained migration, this conjugation method is especially effective in gel micropatterning by manual microcontact printing of protein patterns as small as 5 microm and enables numerous studies of constrained cell attachment and migration that were previously unfeasible due to high cost or difficulty in controlling the protein coating.     

Dodecyl maltoside-sodium dodecyl sulfate two-dimensional polyacrylamide gel electrophoresis of chloroplast thylakoid membrane proteins

A two-dimensional electrophoretic system has been developed for the separation of chloroplast thylakoid membrane proteins. This system incorporates nondenaturing polyacrylamide gel electrophoresis in the presence of the nonionic detergent dodecyl-beta-D-maltoside in the first dimension and sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the second dimension. Thylakoid membranes isolated from Spinacia oleracea were solubilized in 1.0% dodecyl-beta-D-maltoside and separated in 4-7% linear acrylamide gradient tube gels which contained 0.05% dodecyl-beta-D-maltoside. After electrophoresis, the tube gels were equilibrated with a sodium dodecyl sulfate-containing equilibration buffer and applied to a 12.5-20% acrylamide linear gradient gel. The Lammelli buffer system was used in both dimensions. The two-dimensional gels were analyzed by staining sequentially with 3,3',5,5'-tetramethylbenzidine-H2O2, Coomassie blue, and silver staining. A number of protein components were identified on "Western blots" of these two-dimensional gels by immunological localization. Membrane protein complexes such as the light-harvesting chlorophyll a/b protein complex, photosystem I, photosystem II, the cytochrome b6/f complex and ribulose bisphosphate carboxylase appear to migrate as essentially intact complexes in the first dimension and appear as vertical series of resolved subunits in the second dimension. This technique complements isoelectric focusing/sodium dodecyl sulfate-polyacrylamide gel electrophoresis in providing additional information concerning the subunit composition of membrane protein complexes and may prove to be of general utility for studying the protein composition of other membrane systems.     

作用于pNPP的磷酸酶在凝胶中的特异性染色

本方法能在聚丙烯酞胺凝胶中快速,简便,灵敏和特异地染能以对硝基苯磷酸盐（pNPP）为底物的磷酸酶．它是根据Goren等人在凝胶中特异性染色环核苷酸磷酸二酯酶的方法[1]改进而成．这是基于pNPP被对硝基苯磷酸酶（pNPPase）作用后释放出的Pi在凝胶中结合铅离子形成磷酸铅,沉淀在胶中形成白色区带,再用硫化铰处理凝胶,将磷酸铅转变为硫化铅,从而使白色区带转变为棕黑色区带．它可同时分析和比较不同动物或细胞以及用不同药物处理的同一来源的动物或细胞的细胞粗提物中pNPPase的生化性质,还可在纯化此类酶的过程中,提前测定在粗提…     

Scanning of polyacrylamide gel electrophoresis columns for detection of unstained protein zones and for their localization relative to enzyme activities.

Background disturbances which often confuse 280-nm scans of polyacrylamide gels, can be distinguished from true protein peaks by scanning also at a wavelength where the proteins do not absorb (for instance 310 nm).A scanning technique has been used also for precise localization of spectrophotometrically detectable enzyme activities relative to protein zones. After electrophoresis the gel is transferred to a specially designed quartz cuvette and scanned at 280 nm for protein detection. The substrate is then allowed to diffuse into the gel and the activity is located by scanning at a wavelength absorbed by the product.Scanning of polyacrylamide gel electrophoresis columns can be used for the study of solute-solute interactions, as illustrated by a simple model experiment on the binding of bilirubin to albumin.