In-gel isoelectric focusing of peptides as a tool for improved protein identification

In the analysis of proteins in complex samples, pre-fractionation is imperative to obtain the necessary depth in the number of reliable protein identifications by mass spectrometry. Here we explore isoelectric focusing of peptides (peptide IEF) as an effective fractionation step that at the same time provides the added possibility to eliminate spurious peptide identifications by filtering for pI. Peptide IEF in IPG strips is fast and sharply confines peptides to their pI. We have evaluated systematically the contribution of pI filtering and accurate mass measurements on the total number of protein identifications in a complex protein mixture (Drosophila nuclear extract). At the same time, by varying Mascot identification cutoff scores, we have monitored the false positive rate among these identifications by searching reverse protein databases. From mass spectrometric analyses at low mass accuracy using an LTQ ion trap, false positive rates can be minimized by filtering of peptides not focusing at their expected pI. Analyses using an LTQ-FT mass spectrometer delivers low false positive rates by itself due to the high mass accuracy. In a direct comparison of peptide IEF with SDS-PAGE as a pre-fractionation step, IEF delivered 25% and 43% more proteins when identified using FT-MS and LTQ-MS, respectively. Cumulatively, 2190 non redundant proteins were identified in the Drosophila nuclear extract at a false positive rate of 0.5%. Of these, 1751 proteins (80%) were identified after peptide IEF and FT-MS alone. Overall, we show that peptide IEF allows to increase the confidence level of protein identifications, and is more sensitive than SDS-PAGE.     

PICarver: a software tool and strategy for peptides isoelectric focusing

The use of isoelectric focusing as first dimension of separation is a new trend in shotgun proteomics. In all applications using this approach, peptides are separated into equitable fractions, whereas theoretical distribution of peptides according to p I is heterogeneous. We present the development of a new tool and strategy that generates a fractionation scheme resulting in almost even distribution of peptides per fraction, based on theoretical and experimental data. The "pICarver" software tool also increases the throughput of the approach by reducing the number of fractions and merging the peptide-poor regions. A set of isoelectric point fluorescent peptide markers was also developed in combination with the pICarver program to calibrate the pH gradient of commercially available strips. These markers enhanced the precision of pICarver predications. The overall strategy allowed detecting false positive identification and post-translational modifications. The software tool is freely available on www.expasy.org/tools/pICarver.     

Gel based isoelectric focusing of peptides and the utility of isoelectric point in protein identification

Here we present the theoretical and experimental evaluation of peptide isoelectric point as a method to aid in the identification of peptides from complex mixtures. Predicted pI values were found to match closely the experimentally obtained data, resulting in the development of a unique filter that lowers the effective false positive rate for peptide identification. Due to the reduction of the false positive rate, the cross-correlation parameters Xcorr and deltaCn from the SEQUEST program can be lowered resulting in 25% more peptide identifications. This approach was successfully applied to analysis of the soluble fraction of the E. coli proteome, where 417 proteins were identified from 1022 peptides using just 20 microg of material.     

High-molecular-weight carrier ampholytes for isoelectric focusing of peptides

A method is described for the synthesis of high-molecular-weight carrier ampholytes for preparative isoelectric focusing of peptides. A giant polyethylene imine ($\text{M}{}_{\mathrm{<mtext>r</mtext>}}\text{40 000–60 000}$) is mixed with a linear gradient of acrylic acid in a flow-through system and let to react at 80°C for 70 h. Giant carrier ampholytes ($\text{M}{}_{\mathrm{<mtext>r</mtext>}}\text{range}\text{50 000–90 000}$) are thus obtained. These compounds interact very strongly among themselves, probably not by hydrogen bonds or hydrophobic interactions but ionic bonds. In fact, the aggregates are split by high salt (NaCl) or by zwitterionic compounds (Gly, taurine) or at acidic or alkaline pHs. They appear to interact only weakly and reversibly with proteins and no interactions are apparent with model dipeptides (His-Ser, His-Met, His-Phe and His-Lys).     

Iodine stain for detection of peptides after isoelectric focusing

Iodine stain is used for the detection of peptides after isoelectric focusing has been developed. Ultrathin gels (240–360 μm) are cast and, after focusing, dried at 110°C on a filter paper sheet. The paper-pasted gel is then exposed to iodine vapors for a few seconds to a few minutes, depending on the peptide load. White peptide zones are visivle on a brown, uniform background. The reaction is fully reversible and can be used also for small-scale preparative purification of peptides. Better than 80% recoveries of peptide from the gel can be obtained by elution in 80% acetic acid.     

Preparative isoelectric focusing and some properties of solubilized adenylate cyclase from rat brain

A new procedure for the purification of rat brain adenylate cyclase (ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.1) is presented. The enzyme solubilized in Lubrol PX was purified either by molecular sieving or by hydrophobic chromatography, followed by a preparative isoelectric focusing step. For this purpose, a new isoelectric focusing technique was developed which allows a good resolution of adenylate cyclase in a short period of time. When resolved by this procedure, the enzyme migrated as a single molecular species with a pI of 6.3. When isoelectric focusing was performed in the presence of EGTA, two distinct peaks of activity could be detected at pI 6.1 and 7.3. This suggests that adenylate cyclase consists of two subunits held together by divalent ions. It is shown that the purified adenylate cyclase has a smaller sedimentation coefficient and is less hydrophobic than the native one. We conclude that the adenylate cyclase containing complex was at least partially disaggregated by this procedure.     

High-sensitivity isoelectric focusing of biotinylated peptides: a new method

A novel technique to selectively analyze prelabeled peptides by isoelectric focusing (IEF) is presented. The conditions are described for biotinylation of peptides, their separation in polyacrylamide gels by IEF, and their fixation to the gel matrix with glutaraldehyde. The gels are developed by a color reaction catalyzed by an avidin-coupled enzyme. The technique is suitable for peptides with at least one free amino group or guanidino group after N-terminal biotinylation. The presence of other peptides or proteins does not interfere with the detection. The sensitivity is below 10 pmol, representing a 1000-fold improvement over existing techniques for analyzing low molecular weight peptides by IEF.     

Isoelectric focusing in layers of granulated gels. II. Preparative isoelectric focusing.

A method for preparative isoelectric focusing of 0.1-10 g amounts of proteins is described. For anticonvective stabilization of the pH gradient, layers of granulated gels (E.G. Sephadex or Bio-Gel) of variable length, width and thickness were used either on glass plates or in troughs. Load capacity, defined as the amount of protein per ml gel suspension, was determined to be 5-10 mg per ml for total protein, irrespective of the pH range of the carrier ampholytes. For single proteins load capacities of 0.25-1 mg per ml were found for pH 3-10 carrier ampholytes, and 2-4 mg per ml for narrow pH range ampholytes. Experiments on a quartz plate followed by densitometric evaluation in situ at 280 nm have demonstrated that it is possible to proceed from analytical thin-layer isoelectric focusing to preparative separations without loss of resolution, just by changing the dimension of the gel layer and increasing the protein load. Improved resolution which facilitates isolation of isoelectrically homegenious components could be achieved on a 40 cm long separation distance. The geometry of a layer is favourable to heat dissipation and this permits the use of high voltage gradients. Recovery of the focused proteins is high an elution simple. The efficiency of the method is illustrated by examples showing separations of single proteins and protein mixtures.     

Polymorphism of the haptoglobin peptides by isoelectric focusing electrophoresis and isoelectric point determinations

Summary In this investigation, the authors developed two new procedures: a micromethod for haptoglobin purification and the isoelectric focusing electrophoresis on slab polyacrylamide gel for peptide subtyping. These technics are adapted to the study of large sample series for population genetic surveys. The improvements obtained enabled us to disclose in an easy and highly reproducible way the Hp and ₂ peptide chains. Electrophoretic separation of the ₂ FS, SS, and FF chains were greatly improved. Their frequencies estimated in a sample already investigated by the conventional PAGE presented higher values than previously described. New Hp and ₂ mutants were also detected. For the first time, isoelectric points of the Hp peptides were determined; the values obtained are discussed with regard to their known amino acid structure.     

Isolation of specific antigens from Angiostrongylus cantonensis. 1. Preparative flatbed isoelectric focusing

Electrophoresis on SDS gel and analytical isoelectric focusing showed that a crude extract of Angiostrongylus cantonensis consisted of at least 40 protein components with molecular weights ranging from 13 000-70 000 and isoelectric points of pI values ranging from 3.7-10.0. Crossed-immunoelectrophoresis with a hyperimmune antiserum to A. cantonensis showed at least 40 different antigenic components in the crude worm extract which were cross-reactive with those of Ascaris suum, Metastrongylus apri and Toxocara canis. Using preparative isoelectric focusing, the somatic worm preparation was divided into 13 equal fractions, of which 3, 4 and 5, with pI values of 3.7, 4.0 and 4.45 respectively, were later shown by immunoelectrophoretic techniques and enzyme-linked immunosorbent assay to contain antigens specific to A. cantonensis.     

Preparative isoelectric focusing of human serum very low-density and low-density lipoproteins.

Ten percent glycerol prevented the usual precipitation of human serum very low-density lipoproteins (VLDL) and low-density lipoproteins (LDL) at their isoelectric points during their preparative isoelectric focusing (IEF), IEF separated VLDL and LDL into two major fractions. The observed optical density peaks are not artifacts caused by binding of Ampholines to VLDL or LDL since no radioactivity accumulated in the fractions containing VLDL or LDL during IEF in the presence of [¹⁴C]Ampholine, and gel filtration completely separated the lipoproteins from [¹⁴C]Ampholine. These results suggest that IEF may separate subspecies of VLDL and LDL under suitable experimental conditions.     

Preparative purification of recombinant thrombolytic protein from complex biological mixtures

The purification of recombinant thrombolytic protein from a crude fermentation broth mixture was examined in antibody exchange (ABx) chromatographic system. ABx system was shown to exhibit unique selectivity for the recombinant protein broth mixture and higher total binding capacity for the recombinant protein than cation-exchange system. The research with the ABx system indicated that these mixed mode interaction systems could be successfully employed in the displacement mode using DEAE-dextran as the displacer.     

Modeling the isoelectric focusing of peptides in an OFFGEL multicompartment cell

In proteomic analysis of complex samples at the peptide level (termed shotgun proteomics), an effective prefractionation is crucial to decrease the complexity of the peptide mixture for further analysis. In this perspective, the high-resolving power of the IEF fractionation step is a determining parameter, in order to obtain well-defined fractions and correct information on peptide isoelectric points, to provide an additional filter for protein identification. Here, we explore the resolving power of OFFGEL IEF as a prefractionation tool to separate peptides. By modeling the peak width evolution versus the peptide charge gradient at pI, we demonstrate that for the three proteomes considered in silico (Deinococcus radiodurans, Saccharomyces cerevisiae, and Homo sapiens), 90% of the peptides should be correctly focused and recovered in two wells at most. This result strongly suggests OFFGEL to be used as a powerful fractionation tool in shotgun proteomics. The influence of the height and shape of the compartments is also investigated, to give the optimal cell dimensions for an enhanced peptide recovery and fast focusing time.     

iTRAQ compatibility of peptide immobilized pH gradient isoelectric focusing

Immobilized pH gradient isoelectric focusing (IPG-IEF) has emerged as a highly promising alternative to strong-cation exchange fractionation as the first dimension in shot-gun proteomics. Herein is shown the compatibility of this method with iTRAQ isotope labeling for relative quantitation and validation of sequence matches from database searching.     

Rapid and effective focusing in a carrier ampholyte solution isoelectric focusing system: a proteome prefractionation tool

Preparative (solution) isoelectric focusing (sIEF) is a proven technique for proteome prefractionation, but carries limitations which include the risk of protein loss from isoelectric precipitation, poor focusing, and excessively long separation times. This report describes a simple yet effective method to achieve rapid focusing (as fast as 1 h) and maximize protein recovery using a carrier ampholyte sIEF system. Cathodic drift was not present over the time course of the experiment using our eight-chamber device, and we demonstrate the effectiveness of this device for focusing proteome mixtures. We also discuss an MS-compatible acidic wash protocol, which is shown to enhance the recovery of proteins following sIEF, thus, improving detection by LC-MS/MS. These approaches overcome significant shortcomings of the technique, enabling effective prefractionation prior to MS analysis.     

Analytical and preparative isoelectric focusing of peptides in immobilized pH gradients

A new method for peptide analysis and purification is described, based on isoelectric focusing in immobilized pH gradients. On the analytical scale, the peptide zones can now be revealed by an stain for primary and secondary amino group (e.g. ninydrin, fluorescamine, dansyl chloride) since the buffering species, unlike conventional carrier ampholytes, contain only carboxyl and tertiary amino groups. For preparative purposes, conditions have been described to remove most contaminants (e.g. unreacted monomers, non-cross-linked, short polyacrylamide chains) from the gel matrix before the electrophoretic run. However, ca. 2% of the gel dry mass is still present as extractable material. The focused peptides can be recovered in higly yields (ca. 90%) with a fairly high degree of purity (75%), the contaminants being mostly components eluted from the polyacrylamide gel.     

Preparative isoelectric focusing in ampholine electrofocusing columns versus immobiline polyacrylamide gel for the purification of biologically active leukoregulin

Preparative vertical and rotating horizontal (Rotofor) ampholine column and immobiline flat bed polyacrylamide gel isoelectric focusing were evaluated for the isolation of the biologically active acidic form of leukoregulin, a 50,000-Da glycoprotein lymphokine with tumor growth inhibitory activity. Leukoregulin secreted by normal human lymphocytes was concentrated by 10,000 nominal molecular weight size exclusion ultrafiltration and by DEAE anion exchange chromatography using step elution with 0.02 M Tris-HCl: 0.1 M NaCl, pH 7.4. Preparative isoelectric focusing was carried out in a 110-ml vertical column containing 1% ampholines in a pH 4-6 gradient at 15 W constant power for 16-18 h, in a Rotofor 55-ml horizontal column containing 2% ampholines in a pH 4-6 gradient at 12 W constant power for 4-6 h, or in an immobiline pH 4.5-6.5 gradient within a 5% polyacrylamide 120 X 110 X 5-mm flat bed gel at 3 W constant power for 16-18 h. Recovery of biologically active leukoregulin from the vertical and horizontal ampholine columns was similar. The pH 4.9-5.2 fractions from the Rotofor ampholine column contained 4-7% and the fractions from the immobiline gel contained 4% of the leukoregulin activity applied to the electrofocusing column or gel, respectively. Analytical immobiline isoelectric focusing of the leukoregulin in the pH 4.9-5.2 fractions from the Rotofor column demonstrated that a single silver staining band with a pI of 5.1 can be obtained by this rapid method of preparative isoelectric focusing.     

Capillary isoelectric focusing with laser-induced fluorescence whole column imaging detection as a tool to monitor reactions of proteins

Capillary isoelectric focusing (CIEF) with laser-induced fluorescence (LIF) whole column imaging detection (WCID) has the characteristics of high resolution, high speed and high sensitivity for separation of amphoteric biomolecules. These features enable a CIEF-LIF-WCID system to monitor the dynamic process of a protein reaction. The reaction can be a physical change or a chemical reaction, provided that the kinetics of the reaction is slower than the focusing speed or that the intermediates involved have long enough life-span compared to the analysis time. The processes of denaturation (a physical reaction), reduction and carbamylation (both chemical reactions) were dynamically monitored. The CIEF profiles at successive reaction times clearly displayed the formation of different products at different stages. At incomplete denaturation, intermediates with higher apparent pI values relative to the products at complete denaturation were detected. Carbamylation products of a protein were detected when the protein reacted with a urea solution that had prepared three months earlier, exhibiting gradually decreased pI values. Mechanisms involved in these reactions were rationalized. A combined mechanism of denaturation and reduction was suggested to explain the denaturing process under high concentrations of urea. Potential applications and critical factors to manipulate these reactions were also discussed.