Recovery of biologically active proteins detected with imidazole-sodium dodecyl sulfate-zinc (reverse stain) on sodium dodecyl sulfate gels

Analytical purification of a 60-kDa target protein of artemisinin detected in Trypanosoma brucei brucei

Here we describe the isolation and purity determination of Trypanosoma brucei (T. b.) brucei candidate target proteins of artemisinin. The candidate target proteins were detected and purified from their biological source (T. b. brucei lysate) using the diazirine-free biotinylated probe 5 for an affinity binding to a streptavidin-tagged resin and, subsequently, the labeled target proteins were purified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). We herein showed the electrophoresis gel and the immunoblotting film containing the 60-kDa trypanosomal candidate target protein of artemisinin as a single band, which was visualized on-gel by the reverse-staining method and on a Western blotting film by enhanced chemiluminescence. The data provided in this article are related to the original research article "Biotinylated probes of artemisinin with labeling affinity toward Trypanosoma brucei brucei target proteins", by Konziase (Anal. Biochem., vol. 482, 2015, pp. 25-31. http://dx.doi.org/10.1016/j.ab.2015.04.020).

Purification and characterization of a novel earthworm DNase

A new deoxyribonuclease (DNase), referred to as EWDNase, was isolated from earthworm tissues. The purification protocol included acetone precipitation, chromatography on CM-Sepharose, and gel electrophoresis. The overall purification was 73-fold with a recovery rate of 2.3% and a final specific activity of 2039 U/mg. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) analysis suggested a molecular mass of 30 kD for EWDNase, with an isoelectric point of approximately 7.0. Maximum activity was detected at a pH of 5.6 and a temperature of 40°C. Addition of Mg(2+) and Ca(2+) ions promoted enzyme activity strongly, while Zn(2+) and ethylenediamine tetraacetic acid (EDTA) acted as inhibitors. Liquid chromatography-tandem mass spectroscopy (LC-MS/MS) analysis indicated that there was no known matching sequence. The properties of EWDNase were sufficiently different from previously reported enzymes to suggest that it is a new enzyme requiring further confirmation and characterization.

Quantitative proteomics: assessing the spectrum of in-gel protein detection methods

Proteomics research relies heavily on visualization methods for detection of proteins separated by polyacrylamide gel electrophoresis. Commonly used staining approaches involve colorimetric dyes such as Coomassie Brilliant Blue, fluorescent dyes including Sypro Ruby, newly developed reactive fluorophores, as well as a plethora of others. The most desired characteristic in selecting one stain over another is sensitivity, but this is far from the only important parameter. This review evaluates protein detection methods in terms of their quantitative attributes, including limit of detection (i.e., sensitivity), linear dynamic range, inter-protein variability, capacity for spot detection after 2D gel electrophoresis, and compatibility with subsequent mass spectrometric analyses. Unfortunately, many of these quantitative criteria are not routinely or consistently addressed by most of the studies published to date. We would urge more rigorous routine characterization of stains and detection methodologies as a critical approach to systematically improving these critically important tools for quantitative proteomics. In addition, substantial improvements in detection technology, particularly over the last decade or so, emphasize the need to consider renewed characterization of existing stains; the quantitative stains we need, or at least the chemistries required for their future development, may well already exist.

Detection of PEGylated proteins in polyacrylamide gels by reverse staining with zinc and imidazole salts

The reverse staining, with imidazole-SDS-zinc, of PEG-linked proteins separated by SDS-PAGE was studied. Using model conjugates (interferon-alpha 2b (IFN-alpha2b) reacted with either a branched-chain (40,000) PEG (PEG2,40) or a linear monomethoxy PEG polymer (Mr of 12,000) and chromatographically purified monoPEG2,40-IFN-alpha2b), conventional small-format analytical gels (<1 mm thick) showed typical detection patterns (i.e., transparent, colorless bands clearly discernible against a zinc imidazolate-generated white gel background), in less than 20 min. Nonreacted (free) PEG was almost undetected, as expected. The reverse-stained PEGylated IFN-alpha2b patterns were qualitatively indistinguishable from those of parallel gels stained with iodine (I2). The LOD was estimated in the low nanogram range (e.g., at about 7 ng for mono- or bi-PEG2,40 IFN-alpha2b per lane on gradient (4-17%) gels). Also, this stain allowed the visualization of Coomassie blue-undetected PEG-IFN bands, and could be restained with I2. PEGylated species of lysozyme, a low-molecular-weight peptide, ovalbumin, and chymotrypsin were used to demonstrate the generality of this stain. We also show (i) how to counteract the adverse effect of some parameters (e.g., gel thickness above 1 mm, long gel length, low (e.g., 4-6%) acrylamide concentration) on the reverse staining process and (ii) that the properties of the reverse-stained PEGylated proteins remain unchanged, as judged by analyzing both the ion exchange chromatography-based positional isomer separation profile and enzyme-linked immunosorbent response of PEG-IFN recovered from gels. Consequently, this technique may be useful for the rapid analysis or the small-scale preparation of PEGylated proteins.

Negative detection of biomolecules separated in polyacrylamide electrophoresis gels

Here we describe the protocols for negative or reverse detection of proteins, nucleic acids and lipopolysaccharides separated in polyacrylamide electrophoresis gels. These protocols are based on the selective synthesis and precipitation of a white imidazole-zinc complex in the gel, which is absent from those zones where biomolecules are located. These methods are highly sensitive (1-10 ng of biomolecules per band), very cheap as they use inexpensive, common laboratory reagents (imidazole and a Zn II salt), rapid (less than 20 min after gel washing), robust and simple (two steps). Reverse-stained biomolecules are reversibly fixed in the gel. After brief incubation in a zinc chelating agent, biomolecules can be recovered from the gel with the same efficiency as from unstained gels. In consequence, they are procedures of choice for micropreparative applications. References covering typical applications are included.

"Reverse-staining" of biomolecules in electrophoresis gels: analytical and micropreparative applications

Negative or reverse staining using imidazole and zinc salts for protein detection in electrophoresis gels was originally introduced in 1990. The method is based on the selective precipitation of zinc imidazolate in the gel except in the zones where proteins are located. The method was later adapted to allow high-sensitivity negative detection of nucleic acids and bacterial lipopolysaccharides. It provides a practically quantitative recovery of intact biomolecules and is a method of choice for micropreparative applications of gel electrophoresis to proteomics and similar structural studies. Zinc-mediated protein fixation in the gel is fully reversible and the eluted biomolecules are neither chemically modified nor contaminated with organic dyes. Here we present a detailed compilation of practical methods for implementing these techniques with emphasis in their analytical or micropreparative applications.

Generation of a candidate live marker vaccine for equine arteritis virus by deletion of the major virus neutralization domain

Equine arteritis virus (EAV) is an enveloped plus-strand RNA virus of the family Arteriviridae (order Nidovirales) that causes respiratory and reproductive disease in equids. Protective, virus-neutralizing antibodies (VNAb) elicited by infection are directed predominantly against an immunodominant region in the membrane-proximal domain of the viral envelope glycoprotein G(L), allowing recently the establishment of a sensitive peptide enzyme-linked immunosorbent assay (ELISA) based on this particular domain (J. Nugent et al., J. Virol. Methods 90:167-183, 2000). By using an infectious cDNA we have now generated, in the controlled background of a nonvirulent virus, a mutant EAV from which this immunodominant domain was deleted. This virus, EAV-G(L)Delta, replicated to normal titers in culture cells, although at a slower rate than wild-type EAV, and caused an asymptomatic infection in ponies. The antibodies induced neutralized the mutant virus efficiently in vitro but reacted poorly to wild-type EAV strains. Nevertheless, when inoculated subsequently with virulent EAV, the immunized animals, in contrast to nonvaccinated controls, were fully protected against disease; replication of the challenge virus occurred briefly at low though detectable levels. The levels of protection achieved suggest that an immune effector mechanism other than VNAb plays an important role in protection against infection. As expected, infection with EAV-G(L)Delta did not induce a measurable response in our G(L)-peptide ELISA while the challenge infection of the animals clearly did. EAV-G(L)Delta or similar mutants are therefore attractive marker vaccine candidates, enabling serological discrimination between vaccinated and wild-type virus-infected animals.

Detection technologies in proteome analysis

Common strategies employed for general protein detection include organic dye, silver stain, radiolabeling, reverse stain, fluorescent stain, chemiluminescent stain and mass spectrometry-based approaches. Fluorescence-based protein detection methods have recently surpassed conventional technologies such as colloidal Coomassie blue and silver staining in terms of quantitative accuracy, detection sensitivity, and compatibility with modern downstream protein identification and characterization procedures, such as mass spectrometry. Additionally, specific detection methods suitable for revealing protein post-translational modifications have been devised over the years. These include methods for the detection of glycoproteins, phosphoproteins, proteolytic modifications, S-nitrosylation, arginine methylation and ADP-ribosylation. Methods for the detection of a range of reporter enzymes and epitope tags are now available as well, including those for visualizing beta-glucuronidase, beta-galactosidase, oligohistidine tags and green fluorescent protein. Fluorescence-based and mass spectrometry-based methodologies are just beginning to offer unparalleled new capabilities in the field of proteomics through the performance of multiplexed quantitative analysis. The primary objective of differential display proteomics is to increase the information content and throughput of proteomics studies through multiplexed analysis. Currently, three principal approaches to differential display proteomics are being actively pursued, difference gel electrophoresis (DIGE), multiplexed proteomics (MP) and isotope-coded affinity tagging (ICAT). New multiplexing capabilities should greatly enhance the applicability of the two-dimensional gel electrophoresis technique with respect to addressing fundamental questions related to proteome-wide changes in protein expression and post-translational modification.

Detection of biomolecules in electrophoresis gels with salts of imidazole and zinc II: a decade of research

The proven ability of gel electrophoresis to simultaneously resolve, in a single experiment, many components from complex biological samples, has determined its preference over a variety of well-established chromatographic methods. Therefore, procedures placed at the interface between gel separation and microanalysis have earned increasing significance with respect to the overall success of the microanalytical strategy. The first of these procedures is the detection technique. The most important requirement for compatibility with further analysis or bioapplications is that the staining method does not compromise the chemical integrity and the biological properties of micropurified biomolecules. Procedures for negative detection of proteins with metal salts that have been proven to comply with this condition have been known for about 15 years. Only recently have these procedures been extended to the field of nucleic acids and lipopolysaccharides. The focus of this review is to chronicle the development and current status of the negative or reverse stain procedure based on the in-gel reaction of imidazole with zinc salts and its applications forthe micropurification and analysis of unmodified proteins, nucleic acids and bacterial lipopolysaccharides. We highlight the common aspects in the detection of the three types of biomolecules, and their applications to structural and biological analyses. Emphasis is given on the mechanism underlying imidazole-zinc staining, as it contributes to a deeper understanding of a general detection mechanism with metal salts. Finally, we discuss the latest applications of the techniques in proteomics and their possible impact on the characterization of gel-separated single components from complex lipopolysaccharides.

Rescue of very virulent and mosaic infectious bursal disease virus from cloned cDNA: VP2 is not the sole determinant of the very virulent phenotype

Many recent outbreaks of infectious bursal disease in commercial chicken flocks worldwide are due to the spread of very virulent strains of infectious bursal disease virus (vvIBDV). The molecular determinants for the enhanced virulence of vvIBDV compared to classical IBDV are unknown. The lack of a reverse genetics system to rescue vvIBDV from its cloned cDNA hampers the identification and study of these determinants. In this report we describe, for the first time, the rescue of vvIBDV from its cloned cDNA. Two plasmids containing a T7 promoter and either the full-length A- or B-segment cDNA of vvIBDV (D6948) were cotransfected into QM5 cells expressing T7 polymerase. The presence of vvIBDV could be detected after passage of the transfection supernatant in either primary bursa cells (in vitro) or embryonated eggs (in vivo), but not QM5 cells. Rescued vvIBDV (rD6948) appeared to have the same virulence as the parental isolate, D6948. Segment-reassorted IBDV, in which one of the two genomic segments originated from cDNA of classical attenuated IBDV CEF94 and the other from D6948, could also be rescued by using this system. Segment-reassorted virus containing the A segment of the classical attenuated isolate (CEF94) and the B segment of the very virulent isolate (D6948) is not released until 15 h after an in vitro infection. This indicates a slightly retarded replication, as the first release of CEF94 is already found at 10 h after infection. Next to segment reassortants, we generated and analyzed mosaic IBDVs (mIBDVs). In these mIBDVs we replaced the region of CEF94 encoding one of the viral proteins (pVP2, VP3, or VP4) by the corresponding region of D6948. Analysis of these mIBDV isolates showed that tropism for non-B-lymphoid cells was exclusively determined by the viral capsid protein VP2. However, the very virulent phenotype was not solely determined by this protein, since mosaic virus containing VP2 of vvIBDV induced neither morbidity nor mortality in young chickens.

Understanding the mechanism of the zinc-ion stains of biomacromolecules in electrophoresis gels: generalization of the reverse-staining technique

We have recently shown that a few nanograms of protein separated by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels can be detected by reverse-staining, exploiting the precipitation reaction between zinc(II) and imidazole. Modifications of this method have also been generated to detect gel-isolated nucleic acids and bacterial glycolipids. Because there is no recourse to chemical modifiers, the reverse-staining technique has been valuable when micropreparing these biomacromolecules for later use or characterization. The mechanism underlying the reverse-staining effect, however, remains incompletely understood and this has prevented a further generalization of the technique. Here, we have conducted physicochemical experiments and identified zinc imidazolate (ZnIm2) as the main component of the precipitate that forms along the surface of zinc-imidazole reverse-stained gels. Many staining effects observed when gels containing electrophoretically separated biopolymers are subjected to zinc-imidazole stains have been rationalized. The reverse-staining method has been vastly generalized, now allowing the detection of proteins and glycolipids as well as complexes of these macromolecules in native gels. We demonstrate the application of the reverse-staining technique in situations where Coomassie blue or silver staining was inappropriate or failed to produce detection of the species of interest. The present generalization of the reverse-staining method facilitated the characterization of biomacromolecular interaction partners in mixtures of bacterial glycolipids and human tears.

Partial purification and characterization of a Ca(2+)-dependent proteinase from Arabidopsis roots

Ca2+, an important intracellular messenger in plants, is implicated in controlling diverse cellular functions by regulating the activity of several enzymes. Here we report the presence of a Ca(2+)-dependent proteinase (CDP) activity in roots of Arabidopsis using in-gel assays (zymograms). The CDP activity showed absolute Ca2+ requirement for its activation; other divalent ions such as Mg2+, Sr2+, and Zn2+ did not substitute for Ca2+ in stimulating protease activity. The CDP activity was inhibited by the proteinase inhibitors leupeptin, E-64, and N-ethylmaleimide, whereas pepstatin A and phenylmethylsulfonyl fluoride were without effect. These data indicate that the enzyme is likely to be a cysteine proteinase. The CDP activity was partially purified from root cultures using ammonium sulfate precipitation, DE-52, Mono-Q, and Superdex 200 column chromatography. This purification scheme resulted in about 40-fold purification of the CDP activity. Based on the elution of Arabidopsis CDP (ACDP) activity on gel filtration column the molecular mass of CDP was estimated to be about 75 kDa. Isoelectric focusing showed that the enzyme had a pI between 5.2 and 5.4. SDS-polyacrylamide gel analysis showed that activity was associated with a 45-kDa polypeptide, suggesting that the native ACDP is a homodimer. Five different antibodies raised to animal CDPs did not cross-react with the partially purified protein. These data suggest that the plant CDP differs from the known CDPs characterized from animals and is likely to be a new CDP that is unique to plants.

High yield elution of proteins from sodium dodecyl sulfate-polyacrylamide gels at the low-picomole level. Application to N-terminal sequencing of a scarce protein and to in-solution biological activity analysis of on-gel renatured proteins

A simple, reliable procedure for practically quantitative (90-98%) and fast (< 30 min) elution of proteins from SDS-PA gels is described with reproducible recoveries in the range from 100 to 1 pmol per band, which does not require the inclusion of detergents in the elution buffer. It consists in the combination of (1) highly sensitive on-gel protein detection (50 mol per band) with imidazole-SDS-zinc (reverse staining), (2) crushing of the protein band to produce 32-micron gel particles, and (3) vortexing of the slurry in a solution of a zinc-complexing agent, e.g. glycine 0.5 M or EDTA 100 mM (100 microliters for a 100-pmol BSA band), at room temperature. Eluted proteins can be directly analyzed by RP-HPLC, quantitatively loaded onto a PVDF membrane, or, provided that they are previously renatured on-gel, analyzed by biological activity tests. The application of the procedure to in-solution enrichment of scarce proteins for N-terminal analysis is shown.

Complete removal and exchange of sodium dodecyl sulfate bound to soluble and membrane proteins and restoration of their activities, using ceramic hydroxyapatite chromatography

Up to now, removal of sodium dodecyl sulfate (SDS) from proteins in terms of restoration of their activity was an unsolved problem. A general procedure using ceramic hydroxyapatite (HAP) chromatography was developed for the complete removal of SDS bound to soluble or membrane proteins. This procedure involves (i) the binding of the SDS-protein complexes onto the ceramic hydroxyapatite column, (ii) extensive washing of bound proteins with phosphate buffer containing a mild detergent to exchange SDS, (iii) elution of the retained protein by increasing the phosphate concentration. Using this approach, complete exchange of [35S]SDS into a nonionic detergent such as dodecyl maltoside was achieved with a 90-100% protein recovery. The efficiency of protein-bound SDS removal is very likely due to the combined effect of phosphate ions and the hydrophobic tail of nonionic detergent: acting together, they are able to displace SDS molecules from their protein-binding sites. The advantages of this HAP-mediated SDS removal method include high efficiency, rapidity, simplicity and general applicability to a wide variety of detergents and soluble or membrane proteins. Of utmost importance, SDS-treated P-glycoprotein, glutamate dehydrogenase, and lysozyme fully recovered their enzymatic activities after HAP chromatography, including lysozyme electroeluted from SDS-polyacrylamide gel electrophoresis. This demonstrates that reactivation of SDS-treated protein can be achieved, provided that SDS is completely removed under mild conditions.

A procedure for protein elution from reverse-stained polyarcylamide gels applicable at the low picomole level: An alternative route to the preparation of low abundance proteins for microanalysis

We developed a technique that allows rapid protein elution from polyacrylamide gel bands at room temperature into a detergent-free buffer (elution time 2 x 10 min, total working time about 30 min) with high yields (90-98%) even at a low picomole level (1 picomole per band). Its efficacy relies on the combination of protein detection by reverse staining with the enhancement of protein diffusion after gel crushing. Detection is accomplished by gel incubation in an imidazole solution, followed by incubation in a zinc salt solution to develop a negative stain pattern. Proteins are eluted by zinc complexation in Laemmli electrophoresis buffer (Tris + glycine), from which sodium dodecyl sulfate is omitted to allow direct subsequent microanalysis, e.g. high performance liquid chromatography (HPLC) and automatic sequencing. A variety of proteins were eluted efficiently (with no apparent restriction due to their intrinsic properties) as quantified with radioiodinated total E. coli proteins. Yields were independent of acrylamide concentration, protein molecular mass (from 10 to 100 kDa) and the amount (from 1 to 100 picomole) of protein in the band. This protocol was derived from a quantitative evaluation of the effect of protein staining and of sample reduction prior to electrophoresis on elution yields. For N-terminal sequencing, the protein eluate was automatically loaded on a polyvinylidene difluoride (PVDF) membrane with conventional HPLC equipment; both loading and membrane clean-up were monitored at 206 nm. By simultaneously processing several analytical bands, the procedure allowed trace enrichment of a natural scarce protein that was N-terminal sequenced.