India ink staining of proteins on nylon and hydrophobic membranes

India ink was found to be an acceptable stain for proteins blotted or dotted onto positively charged nylon or hydrophobic membranes. The hydrophobic membrane, Immobilon, was an outstanding matrix for binding proteins and displayed low levels of background staining. The least amount of protein detected by india ink staining was between 1.0 and 10 ng. India ink staining of proteins on nylon membranes is an easy, inexpensive, and quick method for the unequivocal detection of both standards and unknowns in the same blot. However, inks, ink concentrations, fixing conditions, staining times, pH, washing conditions, and membrane lots all need to be controlled to achieve maximum sensitivity for protein detection following india ink staining.     

A luminescent ruthenium complex for ultrasensitive detection of proteins immobilized on membrane supports

SYPRO Ruby protein blot stain provides a sensitive, gentle, fluorescence-based method for detecting proteins on nitrocellulose or polyvinylidene difluoride (PVDF) membranes. SYPRO Ruby dye is a permanent stain composed of ruthenium as part of an organic complex that interacts noncovalently with proteins. Stained proteins can be excited by ultraviolet light of about 302 nm or with visible light of about 470 nm. Fluorescence emission of the dye is approximately 618 nm. The stain can be visualized using a wide range of excitation sources utilized in image analysis systems including a UV-B transilluminator, 488-nm argon-ion laser, 532-nm yttrium-aluminum-garnet (YAG) laser, blue fluorescent light bulb, or blue light-emitting diode (LED). The detection sensitivity of SYPRO Ruby protein blot stain (0.25-1 ng protein/mm(2)) is superior to that of amido black, Coomassie blue, and india ink staining and nearly matches colloidal gold staining. SYPRO Ruby protein blot stain visualizes proteins more rapidly than colloidal gold stain and the linear dynamic range is more extensive. Unlike colloidal gold stain, SYPRO Ruby protein blot stain is fully compatible with subsequent biochemical applications including colorimetric and chemiluminescent immunoblotting, Edman-based sequencing and mass spectrometry.     

A silver stain for the rapid quantitative detection of proteins or nucleic acids on membranes or thin layer plates

A relatively simple silver stain which takes less than 15 min to perform has been developed for the detection of nanogram quantities of proteins and DNA on cellulose membranes and thin layer plates. This stain demonstrates a reproducible curvilinear relationship between silver density and the amount of protein or DNA, over an averaged concentration range from 1 to 300 ng for proteins and 10 to 710 ng for DNA. The ease of staining proteins and DNA on membranes, combined with the stain's sensitivity and reproducibility, permits the use of this procedure for the quantitative determination of nanogram amounts of proteins and DNA. The simplicity of this silver stain has also permitted a survey of the staining properties of individual amino acids, purine and pyrimidine bases, nucleosides, nucleotides, homopolymers, and small peptides of known sequence. This survey demonstrated the importance of the basic amino acids, particularly lysine and histidine, and the sulfur-containing amino acids in the detection of proteins. It also indicated that the purine bases may play an important role in the detection of DNA.     

Protein blotting with direct blotting electrophoresis

Direct blotting electrophoresis, a method designed to be of general application for the separation and electroblotting of macromolecules, has been adapted to produce protein blots suitable for subsequent processing by standard techniques such as dye staining or immunological detection. After their separation in a very short gel the protein bands are electrophoresed out of the gel onto an immobilizing matrix. The matrix which is moved across the bottom of the gel by a conveyor belt binds these proteins with high affinity. Once the protein samples have been loaded onto the gel and electrophoresis has been started, no further intervention is needed until the blot is completed. The total expenditure of time for such a direct blot is less than 4 h for a mixture of proteins in the molecular weight range of 14-70 kDa. The staining sensitivity of directly blotted proteins is about 200 ng protein per band as revealed by India ink staining.     

Quantification of proteins in the low nanogram range by staining with the colloidal gold stain AuroDye

A simple assay for proteins in the low nanogram range is described. Proteins are bound to nitrocellulose paper in a band, stained with the commercially available colloidal gold stain AuroDye (a registered trademark of Jansen Life Sciences Products), and quantified by scanning densitometry: 1.25 to 20 ng of protein can be consistently measured. Variation in the staining intensity of different proteins is discussed. DNA, RNA, polyvinylpyrrolidone, Ficoll, and 6 M urea do not affect the assays, and samples from cellular material in a simple lysis buffer containing 0.1% of sodium dodecyl sulfate can be assayed.     

Microwave-enhanced ink staining for fast and sensitive protein quantification in proteomic studies

A novel microwave-enhanced ink staining method was developed for rapid and sensitive estimation of protein content in sample buffers containing chaotropes, dyes, detergents, and reducing agents. Dye-based Blue-Black ink was used to quantitatively visualize proteins spotted on a nitrocellulose membrane. The total staining time was greatly reduced to 3 min by brief exposure to microwave radiation. The stained membrane was washed with distilled water, baked in a microwave oven for complete desiccation, transparentized with mineral oil, and documented by a desktop scanner or densitometer. Only 1 microL of protein sample (protein solubilized in SDS-PAGE sample buffer or IEF rehydration buffer) was used for protein spotting. The novel solid-phase protein assay gives a 500-fold dynamic range from 19.5 to 10000 ng/microL and can be scaled up for high-throughput protein quantification analysis. The fast, sensitive and low-cost microwave-enhanced ink staining procedure is ideal for protein quantification in proteomic analysis.     

Fixation increases sensitivity of India ink staining of proteins and peptides on nitrocellulose paper

The detectability by India ink staining of proteins and peptides dot-blotted on nitrocellulose paper was assessed before and after fixation. Fixation considerably increased the detectability of proteins and peptides. Denaturation by KOH treatment or baking at 100 degrees C for 15 min gave the best results. Precipitation by isopropanol/acetic acid gave intermediate results, whereas crosslinking with glutaraldehyde improved the detectability of small peptides, but not of proteins. Ferridye and Aurodye were also tested after baking. Both dyes were more sensitive and stained more proteins and peptides than India ink. In all cases the detectability of peptides smaller than Mr 1500 was poor.     

FerriDye: colloidal iron binding followed by Perls' reaction for the staining of proteins transferred from sodium dodecyl sulfate gels to nitrocellulose and positively charged nylon membranes

A staining method for proteins on (positively charged) nylon and nitrocellulose membranes is described. The two-step method uses cationic cacodylate iron colloid which is substituted with Tween 20 at an OD460 nm = 0.5, followed by Perls' reaction with acid potassium ferrocyanide. It stains transferred proteins deep blue with low background. The sensitivity is intermediate between that of conventional stains and AuroDye, the colloidal gold stain. This is the first sensitive staining method for proteins transferred on (positively charged) nylon membranes. These membranes have documented advantages in immunoblotting. It will therefore be a useful tool for correlating the position of bands or spots of proteins detected with overlay assays with the complete electropherogram in a duplicate protein blot.     

Colloidal Silver Staining of Electroblotted Proteins for High Sensitivity Peptide Mapping by Liquid Chromatography–Electrospray Ionization Tandem Mass Spectrometry

Mass spectrometric techniques for the identification of proteins either by amino acid sequencing or by correlation of mass spectral data with sequence databases are becoming increasingly sensitive and are rapidly approaching the limit of detection achieved by the staining of proteins in gels or, after electroblotting, on membranes. Here we present a technique for the sensitive staining of proteins electroblotted onto nitrocellulose or polyvinylidene difluoride membranes and enzymatic cleavage conditions for such proteins to achieve optimal recovery of peptides. The technique is based on the deposition of colloidal silver on the membrane-bound proteins. Peptide mixtures generated by proteolysis on the membrane were recovered at high yields and were compatible with analysis by reverse-phase chromatography and on-line electrospray ionization mass spectrometry. This simple and rapid colloidal silver staining procedure allowed the visualization of less than 5 ng of protein in a band and thus approached the sensitivity of silver staining in gels. We demonstrate that this method allows the detection of subpicomole amounts of electroblotted proteins and their identification by high-performance liquid chromatography–electrospray ionization tandem mass spectrometry.     

India ink staining of proteins on nitrocellulose paper

India ink staining of proteins that have been electrotransfer blotted onto nitrocellulose paper is described. This stain proved to be a useful adjunct to the enzyme-linked immunoelectrotransfer blot technique. It is more sensitive than Coomassie blue, amido black, and fast green stains and is simple to use.     

Sensitive, quantitative, and fast modifications for Coomassie Blue staining of polyacrylamide gels

In spite of the high sensitivity of silver staining and the wide dynamic range of various fluorescent detection methods, Coomassie Brilliant Blue staining is still the most widely used protein detection technique for proteins separated by polyacrylamide gel electrophoresis. There are several reasons: Low price, Visible with the eye, Desk top scanners can be employed for image acquisition, Better for quantitative analysis than silver staining, Possible modifications for fast or highly sensitive staining, Mass spectrometry compatible.     

Antibody probing of western blots which have been stained with india ink

India ink can be used to stain proteins bound to nitrocellulose. Subsequently, specific proteins can be identified with antibodies and 125I-protein A. In most cases, india ink did not significantly inhibit detection with antibody, nor was the ink washed off during the antibody incubation steps. Using this method, a direct comparison of antibody-reactive protein and total protein can be made with the same replica.     

Coomassie blue is sufficient for specific protein detection of aptamer-conjugated chips

An aptamer-based biochip for protein detection and quantitation which combines the recent biochip technology and the conventional staining methods, is described. Using a model system comprising His-tagged proteins as the analyte and single-stranded RNA aptamers specific for His-tagged proteins as immobilized ligands on chips, we could demonstrate that aptamers were equivalent or superior to antibodies in terms of specificity and sensitivity, respectively. The sensor has the characteristics of good stability, reproducibility and reusability, with detection limit as low as 85 ng/mL His-tagged protein. It has been demonstrated that the sensor can be stored for at least 4 weeks and reused with reasonable reduction rate of staining intensity. In conclusion, we could show the suitability of nucleic acid aptamers as low molecular weight receptors on biochips for sensitive and specific protein detection and quantitation.     

In-gel detection of urease with nitroblue tetrazolium and quantification of the enzyme from different crop plants using the indophenol reaction

Two methods for measurement of urease activity are described and demonstrated on extracts from several crop plants. With an in-gel staining method based on the principle of Fishbein's noninhibitory stain for urease as little as 25 microU of jackbean urease can be detected within 2 h following electrophoresis. A comparison with published in-gel staining methods shows that the sensitivity is improved by at least two orders of magnitude. The second method allows quantification of urease activity from small amounts of plant material without the need for special laboratory equipment. It employs the detection of ammonium by the indophenol reaction. To eliminate reducing agents which are often necessary to maintain urease activity during extraction, but which interfere with ammonium detection, a simple spin-column procedure is used. The quantification of less than 5 mU/ml extract is possible.     

Polyacrylamide lamination enables mass spectrometry compatible staining and in-gel digestion of proteins separated by agarose IEF

Agarose IEF enables the separation of large proteins and protein complexes. A complication of agarose gels attached onto polyester support is the lack of sensitive protein staining methods compatible with protein analysis and identification protocols. In this study, agarose IEF gels were used to separate the proteins, followed by layering the agarose with polyacrylamide. The formed laminate gels were seamless and durable and they were readily detached from the polyester. The gels were amenable to MS compatible staining. The sensitivity obtained with the acidic silver staining method was 20-50 ng/band of myoglobin. Laminated agarose was a suitable matrix for in-gel digestion based generation of tryptic peptides for MALDI-MS.     

Advancing the sensitivity of selected reaction monitoring-based targeted quantitative proteomics

Selected reaction monitoring (SRM) - also known as multiple reaction monitoring (MRM) - has emerged as a promising high-throughput targeted protein quantification technology for candidate biomarker verification and systems biology applications. A major bottleneck for current SRM technology, however, is insufficient sensitivity for, e.g. detecting low-abundance biomarkers likely present at the low ng/mL to pg/mL range in human blood plasma or serum, or extremely low-abundance signaling proteins in cells or tissues. Herein, we review recent advances in methods and technologies, including front-end immunoaffinity depletion, fractionation, selective enrichment of target proteins/peptides including posttranslational modifications, as well as advances in MS instrumentation which have significantly enhanced the overall sensitivity of SRM assays and enabled the detection of low-abundance proteins at low- to sub-ng/mL level in human blood plasma or serum. General perspectives on the potential of achieving sufficient sensitivity for detection of pg/mL level proteins in plasma are also discussed.     

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.     

Sensitive single-molecule protein quantification and protein complex detection in a microarray format

Single-molecule protein analysis provides sensitive protein quantitation with a digital read-out and is promising for studying biological systems and detecting biomarkers clinically. However, current single-molecule platforms rely on the quantification of one protein at a time. Conventional antibody microarrays are scalable to detect many proteins simultaneously, but they rely on less sensitive and less quantitative quantification by the ensemble averaging of fluorescent molecules. Here, we demonstrate a single-molecule protein assay in a microarray format enabled by an ultra-low background surface and single-molecule imaging. The digital read-out provides a highly sensitive, low femtomolar limit of detection and four orders of magnitude of dynamic range through the use of hybrid digital-analog quantification. From crude cell lysate, we measured levels of p53 and MDM2 in parallel, proving the concept of a digital antibody microarray for use in proteomic profiling. We also applied the single-molecule microarray to detect the p53-MDM2 protein complex in cell lysate. Our study is promising for development and application of single-molecule protein methods because it represents a technological bridge between single-plex and highly multiplex studies.     

Interlaboratory evaluation of automated, multiplexed peptide immunoaffinity enrichment coupled to multiple reaction monitoring mass spectrometry for quantifying proteins in plasma

The inability to quantify large numbers of proteins in tissues and biofluids with high precision, sensitivity, and throughput is a major bottleneck in biomarker studies. We previously demonstrated that coupling immunoaffinity enrichment using anti-peptide antibodies (SISCAPA) to multiple reaction monitoring mass spectrometry (MRM-MS) produces Immunoprecipitation MRM-MS (immuno-MRM-MS) assays that can be multiplexed to quantify proteins in plasma with high sensitivity, specificity, and precision. Here we report the first systematic evaluation of the interlaboratory performance of multiplexed (8-plex) immuno-MRM-MS in three independent labs. A staged study was carried out in which the effect of each processing and analysis step on assay coefficient of variance, limit of detection, limit of quantification, and recovery was evaluated. Limits of detection were at or below 1 ng/ml for the assayed proteins in 30 μl of plasma. Assay reproducibility was acceptable for verification studies, with median intra- and interlaboratory coefficients of variance above the limit of quantification of 11% and <14%, respectively, for the entire immuno-MRM-MS assay process, including enzymatic digestion of plasma. Trypsin digestion and its requisite sample handling contributed the most to assay variability and reduced the recovery of target peptides from digested proteins. Using a stable isotope-labeled protein as an internal standard instead of stable isotope-labeled peptides to account for losses in the digestion process nearly doubled assay accuracy for this while improving assay precision 5%. Our results demonstrate that multiplexed immuno-MRM-MS can be made reproducible across independent laboratories and has the potential to be adopted widely for assaying proteins in matrices as complex as plasma.     

High sensitivity detection of plasma proteins by multiple reaction monitoring of N-glycosites

The detection and quantification of plasma (serum) proteins at or below the ng/ml concentration range are of critical importance for the discovery and evaluation of new protein biomarkers. This has been achieved either by the development of high sensitivity ELISA or other immunoassays for specific proteins or by the extensive fractionation of the plasma proteome followed by the mass spectrometric analysis of the resulting fractions. The first approach is limited by the high cost and time investment for assay development and the requirement of a validated target. The second, although reasonably comprehensive and unbiased, is limited by sample throughput. Here we describe a method for the detection of plasma proteins at concentrations in the ng/ml or sub-ng/ml range and their accurate quantification over 5 orders of magnitude. The method is based on the selective isolation of N-glycosites from the plasma proteome and the detection and quantification of targeted peptides in a quadrupole linear ion trap instrument operated in the multiple reaction monitoring (MRM) mode. The unprecedented sensitivity of the mass spectrometric analysis of minimally fractionated plasma samples is the result of the significantly reduced sample complexity of the isolated N-glycosites compared with whole plasma proteome digests and the selectivity of the MRM process. Precise quantification was achieved via stable isotope dilution by adding (13)C- and/or (15)N-labeled reference analytes. We also demonstrate the possibility of significantly expanding the number of MRM measurements during one single LC-MS run without compromising sensitivity by including elution time constraints for the targeted transitions, thus allowing quantification of large sets of peptides in a single analysis.