Silver staining method for DNA in polyacrylamide gels using eriochrome black T as a silver-ion sensitizer

A sensitive silver staining method using eriochrome black T as a silver-ion sensitizer for DNA detection in polyacrylamide gels was developed. The sensitivity of this staining method was significantly improved by the new silver-ion sensitizer containing a diazo group, which has reducing power. The staining method lasted a total of approximately 15 min following a fixing step for 2 x 20 min. The detection limit of this staining method was 1-4 pg for PhiX174 DNA/HaeIII in both nondenaturing and denaturing polyacrylamide gels. This staining method was especially effective in low-base pair DNA, with a sensitivity that was approximately ten-fold higher than previously published silver staining methods.     

Usefulness of visible dyes for the staining of protein or DNA in electrophoresis

Since 1993, we have studied visible organic dye stains for protein or DNA to improve methodologies and developed the counterion dye staining method. The method employs two oppositely charged dyes that form an ion-pair complex in the staining solution. The selective binding of free dye to protein or DNA in the staining solution improves detection sensitivity and speed. It is a rapid and sensitive procedure, involving fixing/staining or staining/quick destaining steps that are completed in 1-1.5 h. The lowest detection limits achieved are 4-8 ng of protein on polyacrylamide gels and approximately 10 ng of DNA on agarose gels. The focus of this review is to chronicle the development and current status of the counterion dye staining method for detection of protein or DNA. As an extended application of visible dyes, we also discuss the visible dye staining method for detecting protein on blotting membranes developed in our laboratory.     

An optimal method of DNA silver staining in polyacrylamide gels

DNA silver staining has widely been used to detect DNA fragments in polyacrylamide gels with high sensitivity. We developed an optimal method for DNA silver staining on polyacrylamide gels. The novel procedure can be completed within 10 min instead of over 20 min with the conventional methods. The sensitivity is significantly improved by the silver-ion sensitizer (Eriochrome black T (EBT)) and the minimum of 0.11 and 1.75 ng of DNA amount can be detected in denaturing and nondenaturing polyacrylamide gel, respectively. Compared with the conventional silver staining methods, the improved optimal method can save time and display high sensitivity, color uniformity, and long storage time of the staining gels.     

An optimal method of DNA silver staining in polyacrylamide gels

A silver staining technique has widely been used to detect DNA fragments with high sensitivity on polyacrylamide gels. The conventional procedure of the silver staining is tedious, which takes about 40-60 min and needs five or six kinds of chemicals and four kinds of solutions. Although our previous improved method reduced several steps, it still needed six kinds of chemicals. The objective of this study was to improve further the existing procedures and develop an optimal method for DNA silver staining on polyacrylamide gels. The novel procedure could be completed with only four chemicals and two solutions within 20 min. The steps of ethanol, acetic acid, and nitric acid precession before silver impregnation have been eliminated and the minimal AgNO3 dose has been used in this up-to-date method. The polyacrylamide gel of the DNA silver staining displayed a golden yellow and transparent background with high sensitivity. The minimum 0.44 and 3.5 ng of DNA amount could be detected in denaturing and nondenaturing polyacrylamide gel, respectively. This result indicated that our optimal method can save time and cost, and still keep a high sensitivity for DNA staining in polyacrylamide gels.     

Application of silver staining to the rapid typing of the polymorphism of HLA-DQ alleles by enzymatic amplification and allele-specific restriction fragment length polymorphism.

A rapid and highly sensitive silver staining method, originally developed for the detection of proteins, was slightly modified to detect nucleic acids in polyacrylamide gels. The second exons of the histocompatibility antigen HLA-DQA 1 and DQB 1 genes were selectively amplified from genomic DNA by the polymerase chain reaction (PCR). Digestion of the PCR products by endonucleases, followed by their size-separation on polyacrylamide gels and visualization by silver staining, allowed us to define the HLA-DQ alleles of the genomic DNA. The intensity of staining of digested PCR-amplified DNA is linear from at least 8 to 18 ng for fragments of lengths ranging from approximately 40 to 200 bp. Thus, silver staining in combination with PCR and allele-specific restriction fragment length polymorphism provides a simple, safe, and rapid method for accurate definition of HLA-DQ alleles at the nucleotide level in the clinical typing laboratory.     

Vitamin C-silver: an environmentally benign choice for DNA visualization on polyacrylamide gels

A practical, sensitive and environment-benign protocol for the detection of DNA on polyacrylamide gels was described. In this method, the most commonly used formaldehyde-based developer in DNA silver stain, which poses potential hazards to the health of operators, is firstly replaced by vitamin C (Vc) in sodium thiosulfate solution. This allows user-friendly and efficient visualization of DNA that takes about 20 min to complete all the procedures, and provides comparable sensitivity (8 pg of single band) to the most sensitive formaldehyde-based silver staining method developed before.     

A simple system for staining protein and nucleic acid electrophoresis gels

Researchers in molecular biology spend a significant amount of time tending to the staining and destaining of electrophoresis gels. Here we describe a simple system, costing approximately $100 and taking approximately 1 h to assemble, that automates standard nucleic acid and protein gel staining protocols. Staining is done in a tray or, with DNA gels, in the electrophoresis chamber itself following automatic detection of the voltage drop. Miniature pumps controlled by a microcontroller chip exchange the necessary solutions at programmed time intervals. We demonstrate efficient and highly reproducible ethidium bromide and methylene blue staining of DNA in agarose gels and Coomassie blue and silver staining of proteins in polyacrylamide gels.     

Counterion-dye staining method for DNA in agarose gels using crystal violet and methyl orange

Sensitive and safe methods for visualization of DNA in agarose gels are described. 0.001% crystal violet dissolved in distilled water was used for DNA staining on agarose gels and it could detect as little as 16 ng of DNA (3 kb, pGem-7Zf/EcoRI) without destaining procedure. The detection limit is four times lower than that of ethidium bromide. To improve the sensitivity, we studied a counterion-dye staining method using methyl orange as a counterion-dye which contributes to reduce excessive background staining by crystal violet. Dye concentration, pH of staining solution, mixing molar ratio of two dyes, and staining times were optimized for the counterion-dye staining. By the staining with a mixed solution of 0.0025% crystal violet and 0.0005% methyl orange in distilled water, 8 ng of the 3 kb DNA in an agarose gel was detected within 30 min.     

Improved conditions for silver–ammonia staining of DNA in polyacrylamide gel

An improved silver–ammonia staining method for DNA on polyacrylamide gels is described. In this method, staining of DNA using silver–ammonia complex allows high sensitivity, low cost, low toxicity, and simple protocol without requiring fixation and sensitization steps. The protocol takes less than 40 min to complete, with a detection limit of 1.5 pg of single DNA band on polyacrylamide gels, approximately 30‐fold higher than that of original silver–ammonia staining method. Furthermore, this novel technique not only exhibits high sensitivity for large DNA fragment, but also shows a better trend to detect low‐base‐pair DNA compared with other silver staining methods.     

High‐throughput negative detection of SDS‐PAGE separated proteins and its application for proteomics

A negative detection method for proteins on SDS‐PAGE is described. In this method, Eosin Y (EY) was selectively precipitated in the gel background, which is absent from those zones where proteins are located through the formation of a stable water‐soluble protein–dye complex. Negative staining of proteins using EY, allows high‐sensitivity, low‐cost, and simple protocol. The new described method takes less than an hour to complete all the protocol, with a detection limit of 0.5 ng of single protein band. Comparing with imidazole‐zinc negative stain, EY dye provides broader linear dynamic range, higher sensitivity and reproducibility, and better obvious contrast between the protein bands or spots and background. Furthermore, the novel technique developed here presented a real practical method for simultaneous processing of multiple gels, which makes it possible to perform high‐throughput staining for proteome research. Additionally, we have also compared the influence of staining method on the quality of mass spectra by PMF.     

A thin-layer multistrip polyacrylamide gel electrophoresis apparatus for Ferguson plot analysis at the submicrogram load level

A procedure was developed for casting thin-layer multistrip polyacrylamide gels and using them for the simultaneous gel electrophoresis at several gel (Ferguson plot analysis) at the sub-microgram load level, using silver staining, autoradiography and, potentially, blotting for detection. The lower viscosity of polymerization mixtures, compared to agarose gelation mixtures, required the redesign of the multistrip cassette with separation of channels by rubber gaskets and the application of a cassette press. The lowered viscosity also required addition of 35% sucrose and an increased rate of polymerization in application to multistrip gels formed on a common NetFix backing. The present design allows one to obtain Ferguson plots exemplified by those of 32P-labeled DNA followed by autoradiographic detection.     

Efficient and sensitive method of DNA silver staining in polyacrylamide gels

DNA silver staining is widely used to detect DNA fragment in polyacrylamide gel with high sensitivity. Conventional procedures of the silver staining involve several steps, which take about 40 min to 2 h in total. To improve the efficiency of DNA silver staining, a more efficient protocol is developed in this study. The procedure comprises only four steps including impregnating, rinsing, developing, and stopping, and could be completed within 20 min. Nitric acid and ethanol in the silver-impregnation step of the new procedure eliminates the need for prior treatment of gels with a fixing solution and following rinse prior to impregnation with silver. The procedure has high sensitivity and long storage lifetime. The minimum detectable mass of DNA is 0.44 and 3.5 ng in denaturing and nondenaturing polyacrylamide gel, respectively.     

Improved detection of lymphocyte membrane proteins in purified form and as a crude mixture using native and denaturing polyacrylamide gel electrophoresis by optimisation of coomassie brilliant blue and silver staining.

Optimised silver staining protocols were devised for the detection of membrane proteins in purified form and as a crude mixture. These were adduced in both sodium dodecyl sulphate (SDS) and native polyacrylamide gel electrophoresis and consisted of ethanol-acetic acid-formaldehyde fixation, Coomassie Brilliant Blue prestaining, Rapidfix pretreatment, formaldehyde enhancement and finally ammoniacal silver staining. With these modifications, numerous staining problems of membrane proteins were overcome. These included reduction in background staining, enhanced detection sensitivity in native gels, elimination of negative staining and the avoidance of metallic silver deposition on the gel surface. In overcoming these problems, some factors determining the colour and stainability of membrane proteins in their native state were determined. Both the anionic Coomassie Brilliant Blue dye and SDS detergent improved the sensitivity of silver staining in native gels, and ammoniacal silver was more sensitive than neutral silver, suggesting silver staining to be a charge dependent process.     

Counterion-dye staining for DNA in electrophoresed gels using indoine blue and methyl orange

In this study, we describe a sensitive staining method for DNA in agarose and polyacrylamide gels using organic visible dyes, indoine blue (IB) and methyl orange (MO). The counterion-dye staining method uses two oppositely charged dyes to form a hydrophobic ion pair complex in the staining solution. A decrease in the number of free forms of dyes in staining solution can enhance the selectivity of binding between the dye and DNA, and can reduce nonspecific background staining. As a result, the sensitivity of counterion-dye staining was significantly improved compared with other dye-based staining. This method uses a staining solution consisting of 0.008% IB, 0.002% MO, 10% ethanol and 0.2 M sodium acetate at pH 4.7, and can detect 5 ng of lambda DNA/HindIII within 60 min in agarose gels and 10 ng of PhiX174 DNA/HaeIII within 20 min in polyacrylamide gels.     

A rapid and effective method for silver staining of PCR products separated in polyacrylamide gels

With the development of molecular quantitative genetics, particularly, genetic linkage map construction, quantitative trait loci mapping or genes fine mapping and association analysis etc., more and more PCR products separated in polyacrylamide gels need to be silver‐stained. However, conventional silver‐staining procedures are complicated and time‐consuming as they require a lot of preparation and handling of several solutions prior to use. In this study, a simple and rapid protocol for silver staining of PCR products was developed. The number of steps was reduced compared to conventional protocols, thus achieving detection of PCR products in 7 min, saving time and resources. Fixation and staining solution and developing solution in present staining procedure allowed a reutilization for 12 and 8 times, respectively, reducing the cost greatly. Meanwhile, the sensitivity was significantly improved with the improved method and the minimum of 0.097 ng/μL of DNA amount can be detected in denaturing polyacrylamide gel. The protocol developed in this study will facilitate the development of molecular quantitative genetics.     

Green-light transilluminator for the detection without photodamage of proteins and DNA labeled with different fluorescent dyes

The excitation spectra of Nile red and SYPRO red, two currently used dyes for the fluorescent staining of protein bands in sodium dodecyl sulfate (SDS)-polyacrylamide gels, show an excitation peak in the UV region and another in the visible region (maximum at about 550 nm). Ethidium bromide and other intercalating dyes, e.g. propidium iodide, ethidium dimers, and benzoxazolium-4-quinolinium dimer-3 (YOYO), used for the fluorescent staining of DNA bands in agarose gels also show an excitation peak in the same region of the visible spectrum. We have designed and constructed a green-light transilluminator with an emission maximum at 542 nm. This visible transilluminator allows the detection of protein bands stained with Nile red and SYPRO red with the same sensitivity obtained with a 300 nm UV transilluminator. The green-light transilluminator also allows the detection of about 2 ng of DNA per band in gels stained with ethidium bromide and the other intercalating dyes indicated above. In contrast to the UV transilluminators, the green-light transilluminator does not produce photodamage of DNA even after long exposures (10 min). This makes this transilluminator very useful for preparative work. Furthermore, the green-light transilluminator does not require UV safety equipment and, consequently, it can be very convenient for teaching laboratories.     

Quality of assurance considerations for use of the Fluorlmager SI and fragmeNT analysis software

The Fluorlmager SI (FSI) from Molecular Dynamics is one of several scanning instruments available for the detection of fluorescent emissions associated with DNA samples in a variety of matrices (agarose and polyacrylamide gels, membranes and microplates). In our laboratory, we measured the electrophoretic mobility of randomly amplified polymorphic DNA (RAPD) fragments stained with ethidium bromide in agarose using the FSI to scan gels and the associated Molecular Dynamics software (ImageQuaNT, and FragmeNT Analysis) for analysis. Initial scans and analyses resulted in inconsistent band detection across the same gel and across several scans of the same gel. To determine the best types of calibration for the instrument, several factors were considered and then evaluated. Tests of calibration acceptability were also evaluated. Band detection by FragmeNT Analysis was improved following optimization of matrices and parameters used in calibration and experimental scans. In addition, use of software templates for analysis and modifications in the staining procedure, which have resulted in decreased instrument associated variance, are discussed.     

Ultrasensitive polychromatic silver staining of sodium dodecyl sulfate-polyacrylamide gels with the Gelcode system using the PhastSystem Development Unit

The Gelcode color-based silver staining system, an improved formulation based on the original publication by Sammons et al. (Electrophoresis 1981, 2, 141-147) has been adapted to automated rapid staining in the PhastSystem Development Unit. The use of elevated temperatures in the fixation, washing, staining, and stabilization steps of the protocol reduces the total time of the process from 18 h to 1 h. The limit of detection, which is at least tenfold more sensitive than the silver staining protocol recommended for the PhastSystem, corresponds to 0.05-0.1 ng of protein per band. The method is applicable to both one- and two-dimensional polyacrylamide gels.     

Stabilization of thin-layer agarose gels after isoelectric focusing with polyacrylamide enables reverse imidazole-zinc staining and facilitates two-dimensional gel electrophoresis

Large-pore-size agarose gels provide excellent resolving capacity for high molecular weight biomolecules. Thin-layer agarose isoelectric focusing (IEF) gels on polyester support films are especially useful for the separation of large proteins based on their pI in native conformation, but the method has suffered from the lack of detection methods compatible with agarose gels in hydrated form. Recently, an acrylamide copolymerization method was reported to enable mass-spectrometry-compatible silver staining and in-gel digestion of proteins. In this study, the method was further applied by demonstrating successful reverse imidazole-zinc staining of thin-layer agarose IEF gels copolymerized with acrylamide. The sensitivity of the reverse staining method on the composite gel at its best equaled the sensitivity of the traditional dried agarose silver staining method. Owing to the increased durability and reversible detection, the reverse-stained first-dimension gel could be conveniently prepared for the second-dimension sodium dodecyl sulfate polyacrylamide gel electrophoresis by reduction and alkylation. In addition, the micropreparative generation of tryptic peptides of Coomassie brilliant blue R-250 stained proteins in the composite gel is demonstrated.     

Improved staining of proteins in polyacrylamide gels including isoelectric focusing gels with clear background at nanogram sensitivity using Coomassie Brilliant Blue G-250 and R-250

An improved procedure for staining of proteins following separation in polyacrylamide gels is described which utilizes the colloidal properties of Coomassie Brilliant Blue G-250 and R-250. The new method is based on addition of 20% v/v methanol and higher concentrations of ammonium sulfate to the staining solution previously described. The method combines the advantage of much shorter staining time with high sensitivity, a clear background not requiring destaining, stepwise staining, and stable fixation after staining. The method has been applied to staining of polyacrylamide gels after sodium dodecyl sulfate-electrophoresis and isoelectric focusing in carrier ampholyte-generated pH gradients.