Isoelectric focusing of histones in extremely alkaline immobilized pH gradients: comparison with capillary electrophoresis

Selection of pH ranges in 2DE

This chapter describes the technical improvements of the two-dimensional electrophoresis pattern resulting of an optimized pH range in the first dimension. Various types of pH gradients are available. Different strategies can be applied in order to select the pH ranges for the exploration of a proteome. The resulting gels are analysed for their background, resolution, sensitivity in relation with the sample complexity. As the complete dynamic range of protein expression cannot be visualized, the high loading capacity of immobilized narrow pH gradients can be used. The limitations and possible enhancements are discussed.

Analysis of histones, histone variants, and their post-translationally modified forms

For many years, histones were considered passive structural components of eukaryotic chromatin. Meanwhile it has been proven that histones also participate in gene regulation and repression via post-translational modification. The multitude of these post-translational modifications and the existence of numerous histone variants require particular separation strategies for their analysis, a prerequisite for studying biological processes. The most widely utilized techniques for the separation of histones, namely PAGE, HPCE, RP-HPLC, and hydrophilic Interaction LC, are reviewed here. Problems inherent to the analysis of histones owing to their unique physical and chemical properties along with advantages and shortcomings of particular methods are discussed.

Unseen proteome: mining below the tip of the iceberg to find low abundance and membrane proteins

Abundant and hydrophilic nonmembrane proteins with isoelectric points below pH 8 are the predominant proteins identified in most proteomics projects. In yeast, however, low-abundance proteins make up 80% of the predicted proteome, approximately 50% have pl's above pH 8 and 30% of the yeast ORFs are predicted to encode membrane proteins with at least 1 trans-membrane span. By applying highly solubilizing reagents and isoelectric fractionation to a membrane fraction of yeast we have a purified and identified 780 protein isoforms, representing 323 gene products, including 28% low abundance proteins and 49% membrane or membrane associated proteins. More importantly, considering the frequency and importance of co- and post-translational modifications, the separation of protein isoforms is essential and two-dimensional electrophoresis remains the only technique which offers sufficient resolution to address this at a proteomic level.

Analysis of histones by on-line capillary zone electrophoresis-electrospray ionisation mass spectrometry

The on-line combination of capillary electrophoresis and electrospray ionisation mass spectrometry was applied for the determination of some basic histones from calf thymus. The separation performance of those basic proteins was significantly improved by coating the capillaries with hydroxypropylmethylcellulose. The coating appeared to mask effectively the underlying silanol groups thus avoiding undesirable adsorption of the histones onto the capillary walls, while it was also shown to be an effective way to avoid contamination of the mass spectrometer. Finally, capillary electrophoresiselectrospray ionisation mass spectrometry with coaxial sheath liquid was successfully applied to the analysis of histones using a simple dialysis step of the sample as sample pretreatment.

Alkaline proteins of Bacillus subtilis: first steps towards a two-dimensional alkaline master gel

The genomic sequence of Bacillus subtilis, which is the best studied Gram-positive bacterium, enabled us to obtain a theoretical two-dimensional (2-D) map, demonstrating that about one-third of this proteome has a theoretical alkaline isoelectric point (pI). This represents an important part of the entire proteome, which is not detectable in conventional 2-D gels (pH range 4-7). Sequence analysis revealed that 91% of the ribosomal proteins and a high amount of theoretical membrane proteins should be localized in the alkaline pH range requiring different protein extraction procedures. In order to find the pH range which gives the best resolution results for the alkaline proteins of B. subtilis, immobilized pH gradients (IPGs) with different pH ranges (pH 6-10, 6-11, 4-12, 9-12, and 3-10) were tested and optimized for IPG 4-12. Here we present a version of a first alkaline master 2-D gel for B. subtilis, which is a further complement of the already existing master gel (pH 4-7) in the Sub2D database. Almost 150 spots could be detected and 41 proteins have already been identified.

The current state of two-dimensional electrophoresis with immobilized pH gradients

The original protocol of two-dimensional electrophoresis with immobilized pH gradient (IPG-Dalt; Gorg et al., Electrophoresis 1988, 9, 531-546) is updated. Merits and limits of different methods for sample solubilization, sample application (by cup-loading or ingel rehydration) with respect to the pH interval used for IPG-isoelectric focusing are critically discussed. Guidelines for running conditions of analytical and micropreparative IPG-Dalt, using wide IPGs up to pH 12 for overview patterns, or narrow IPGs for zoom-in gels for optimum resolution and detection of minor components, are stated. Results with extended separation distances as well as automated procedures are demonstrated, and a comparison between protein detection by silver staining and fluorescent dyes is given. A brief trouble shooting guide is also included.

Biomedical applications of two-dimensional electrophoresis using immobilized pH gradients: current status

There is currently much interest, as we enter the postgenome era, in studying gene expression at the protein level. Two-dimensional electrophoresis (2-DE) using immobilized pH gradients (IPG), coupled with mass spectrometry (MS), is currently the most widely utilized approach for the analysis of whole tissue proteins. The methodology for IPG-based 2-DE, since the introduction of the technique in the 1980s, is reviewed. In its present form the IPG methodology is mostly useful as a research tool. In general, high reproducibility and high resolution have been achieved. However, the lack of substantial automation and the limited sensitivity of the current overall methodology continue to represent drawbacks for biomedical applications. Further developments to increase throughput and to reduce sample requirement would substantially benefit the application of IPG-based 2-DE to biomedicine and would enhance the prospects for introducing the methodology into the clinical laboratory.

The current state of two-dimensional electrophoresis with immobilized pH gradients

The original protocol of two-dimensional electrophoresis with immobilized pH gradient (IPG-Dalt; Gorg et al., Electrophoresis 1988, 9, 531-546) is updated. Merits and limits of different methods for sample solubilization, sample application (by cup-loading or ingel rehydration) with respect to the pH interval used for IPG-isoelectric focusing are critically discussed. Guidelines for running conditions of analytical and micropreparative IPG-Dalt, using wide IPGs up to pH 12 for overview patterns, or narrow IPGs for zoom-in gels for optimum resolution and detection of minor components, are stated. Results with extended separation distances as well as automated procedures are demonstrated, and a comparison between protein detection by silver staining and fluorescent dyes is given. A brief trouble shooting guide is also included.

Isoelectric focusing in immobilized pH gradients: an update

The latest trends on isoelectric focusing (IEF) in immobilized pH gradients (IPG) are here reviewed. The major advances on IPG technologies have been made when interfacing this technique with sodium dodecyl sulfate-polyacrylamide gel electrophoresis to produce two-dimensional (2-D) maps. Previous 2-D maps were routinely performed using conventional IEF as a first dimension, which typically resulted in poor reproducibility of spot position. With IPGs, correlation between experimental and calculated protein pI values is as good as +0.01 to 0.02 pH units. A new software has also been released, permitting easy calculation and optimization of linear, concave and convex exponential gradients, even in very complex recipes utilizing all ten Immobiline chemicals. It has also been proven that IPGs can be interfaced with mass spectrometry, thus obtaining a novel 2-D map with the best of pI measurements in the first dimension coupled with the best of mass determination in the second dimension. Recently, it has been shown that IPGs can be exploited to charter forbidden grounds, with the creation of non-linear pH gradients covering the extreme alkaline pH 10-12 gradient. In such basic regions, excellent steady-state patterns of histones and subtilisin mutants have been reported. Different families of histones could be mapped not only in this pH 10-12 interval, but also in 2-D maps exploiting this very alkaline gradient in the first dimension. Although the IPG technique is now a trouble-free, user-friendly technique, some annoying artefacts, producing severe protein smears and precipitation, were very recently reported, but found to be linked to some commercial Immobiline preparations containing up to 5% oligomers. Better quality control on the part of the company producing such chemicals should eliminate even this last source of troubles.

Very alkaline immobilized pH gradients for two-dimensional electrophoresis of ribosomal and nuclear proteins

Basic proteins normally lost by the cathodic drift of carrier ampholyte focusing, or separated by NEPHGE with limited reproducibility, could be well separated by two-dimensional (2-D) electrophoresis under equilibrium conditions using immobilized pH gradients (IPGs) 4-10 and 6-10 using a previously published protocol (Görg et al., Electrophoresis 1988, 9, 531-546). In the present study we have extended the pH gradient to pH 12 with IPGs 8-12, 9-12 and 10-12 for the analysis of very basic proteins. Different optimization steps with respect to pH engineering, gel composition and running conditions, such as substitution of acrylamide by dimethylacrylamide and addition of isopropanol with and without methylcellulose to the IPG rehydration solution (in order to suppress the reverse electroosmotic flow) were necessary to obtain highly reproducible 2-D patterns of ribosomal proteins from HeLa cells and mouse liver. Histones from chicken erythrocyte nuclei as well as total cell extracts of erythrocytes were also successfully separated under steady-state conditions. Due to the selectivity of isoelectric focusing in IPG 9-12, where the more acidic proteins abandon the gel, the tedious procedure of nuclei preparation prior to histone extraction can be omitted.

Development of a high-performance capillary isoelectric focusing technique with application to studies of microheterogeneity in chicken conalbumin

A robust, simple, reproducible isoelectric focusing method using capillary electrophoresis that exhibits high stability, migration time reproducibility and pH linearity over a wide pH gradient was developed. Consecutive runs (over 113 runs) of several proteins and one peptide with isoelectric points (p/s) ranging from 9.45 to 2.75 yielded excellent migration time reproducibility (< 2% R.S.D.). Experimental parameters including buffer aging and capillary-to-capillary variation were thoroughly examined and optimized to improve the migration time reproducibility. The capillary isoelectric focusing (CIEF) method was applied to the analysis of chicken conalbumin (ovotransferrin), an iron-binding protein in egg white. Conalbumin (low iron content) separated into three major components with p/s of 7.2, 6.6 and 6.2. When the protein was saturated with iron (2 Fe/mol), a shift to lower p/s was detected. Chicken serum transferrin subjected to CIEF gave a pattern similar to conalbumin with three p/s of 7.1, 6.6 and 6.1, indicating that it was not fully saturated with iron. Thus, CIEF can be used as a potential analytical method to provide information about the metal-binding properties of specific metalloproteins.

Preparative electrofocusing for industrial applications

This paper presents a case study of using a multicompartment isoelectric focusing apparatus to determine the isoelectric points and focus preparative quantities of brain derived neurotrophic factor (BDNF) and neurotrophic factor 3 (NT3). A separation of PEGylated from unPEGylated forms of granulocyte colony stimulating factor (G-CSF) is described as well. Both BDNF and NT3 have substantially higher pI values in this system than is predicted from sequenced based modeling. Although PEGylated forms of G-CSF can be separated from the unPEGylated forms, separation of protein with differing degrees of PEGylation was not achieved. The paper additionally demonstrates that this technique can be used simultaneously as an analytical and preparative tool, eliminating the need for analytical IEF gels.

'Tunable' positive and negative surface charges on a capillary wall: exploiting the Immobiline chemistry

The Immobiline (weak acrylamido acids and bases) chemistry has been applied to the covalent attachment of a positively (or, if needed, negatively) charged layer onto the inner surface of the silica wall. In particular, the following basic Immobilines have been used: pK 6.2, pK 7.0, pK 8.5 and pK 9.3. In order to avoid pK changes, the charged Immobilines are mixed with neutral acrylamido derivatives (in particular the highly resistant and hydrophilic N-acryloyl aminoethoxyethanol) so as to form a co-polymer having a 1:5 molar ratio (charged to neutral). The mu(eo) vs. pH curves have a slope opposite to that of a naked capillary and fan out on the pH scale following the titration curves of the different weak bases. Such chemistry allows the covalent attachment of charged species having known pK values and offering controlled charged densities on the wall. However, with the atomic force microscope, it is found that such soft coatings (whether charged or neutral) do not seem to provide complete coverage of the surface: naked patches of fused silica are found interdispersed among the polymer-coated ones. A good solution is a hybrid bonded and dynamic coating, obtained by adding short chain linear polyacrylamides to the background electrolyte. Good separations of polycations [poly(L-histidine)] and of histones are reported up to pH 5.7.

Steady-state two-dimensional maps of very alkaline proteins in an immobilized pH 10-12 gradient, as exemplified by histone types

Two-dimensional steady-state patterns of histones are here reported for the first time. The first dimension run consists in nonlinear immobilized pH gradients, spanning the pH 10-12 range. The second dimension run is a standard SDS-PAGE in a constant concentration (15% T) gel slab, in presence of a 6% T stacking gel. All the histone fractions analysed (II-AS, VI-S, VII-S and VIII-S) exhibit pI values between pH 11 and 12. The M(r) values range from 13 to 32 kDa, with the heaviest distribution around 18 kDa. When running all different histone fractions in a single mixture, and analysing the 2-D gel by computerized image data acquisition, a total of 35 individual spots is detected.