In‐gel equilibration for improved protein retention in 2DE‐based proteomic workflows

The 2DE is a powerful proteomic technique, with excellent protein separation capabilities where intact proteins are spatially separated by pI and molecular weight. 2DE is commonly used in conjunction with MS to identify proteins of interest. Current 2DE workflow requires several manual processing steps that can lead to experimental variability and sample loss. One such step is the transition between first dimension IEF and second‐dimension SDS‐PAGE, which requires exchanging denaturants and the reduction and alkylation of proteins. This in‐solution‐based equilibration step has been shown to be rather inefficient, losing up to 30% of the original starting material through diffusion effects. We have developed a refinement of this equilibration step using agarose stacking gels poured on top of the second‐dimension SDS‐PAGE gel, referred to as in‐gel equilibration. We show that in‐gel equilibration is effective at reduction and alkylation in SDS‐PAGE gels. Quantification of whole‐cell extracts separated on 2DE gels shows that in‐gel equilibration increases protein retention, decreased intergel variability, and simplifies 2DE workflow.     

Property and Application of BACy‐Based Functional Hydrogels

Conventional polyacrylamide hydrogels prepared from the free radical polymerization between acrylamide and N,N′‐methylenebisacrylamide (NMBA) have been frequently used in the biochemical technique like the sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS‐PAGE) to resolve protein mixtures. In this study, we have prepared an alternative polyacrylamide hydrogel from the cross‐linking of acrylamide and N,N′‐bisacrylylcystamine (BACy). In addition, we have compared the BACy‐based hydrogel with the NMBA‐based polyacrylamide hydrogel for their physical properties such as swelling ratio, shear modulus, crosslink density and morphology. Moreover, we further determined whether BACy‐based polyacrylamide hydrogel could be applied to SDS‐PAGE and proteomics research. The results showed that this type of hydrogel is capable of separating proteins and facilitates further in‐gel protein digestion and the following protein identifications by mass spectrometry. In summary, our study provides a basis for the putative application of BACy‐based hydrogels.     

Cover Picture: Electrophoresis 3'2010

Issue no. 3 is a regular issue with Emphasis on “Proteins and Proteomics”. The first part has 8 articles on proteins and proteomics covering various topics, e.g. preparative divergent flow IEF, multichannel gel electrophoresis, capillary gel electrophoresis, nanoparticle‐based CE of proteins, 2‐DE in a radial gel format, depletion of high abundance proteins, and proteomic investigation of fetal brain and lentil seed. The remaining 10 articles are concerned with nucleic acids, gene expression, methodologies and application. Featured articles include: Preparative divergent flow IEF without carrier ampholytes for separation of complex biological samples (( 10.1002/elps.200900484 )) SDS‐PAGE and two‐dimensional maps in a radial gel format (( 10.1002/elps.200900526 )) Analysis of Effect of Electrolyte Types on Electrokinetic Energy Conversion in Nanoscale Capillaries (( 10.1002/elps.200900409 )) A simple method to determine the surface charge in microfluidic channels (( 10.1002/elps.200900603 ))     

Proteomics of cypress pollen allergens using double and triple one-dimensional electrophoresis

Italian cypress (Cupressus sempervirens, Cups) pollen causes allergic diseases in inhabitants of many of the cities surrounding the Mediterranean basin. However, allergens of Cups pollen are still poorly known. We introduce here a novel proteomic approach based on double one‐dimensional gel electrophoresis (D1‐DE) as an alternative to the 2‐DE immunoblot, for the specific IgE screening of allergenic proteins from pollen extracts. The sequential one‐dimensional combination of IEF and SDS‐PAGE associated with IgE immunoblotting allows a versatile multiplexed immunochemical analysis of selected groups of allergens by converting a single protein spot into an extended protein band. Moreover, the method appears to be valuable for MS/MS identification, without protein purification, of a new Cups pollen allergen at 43 kDa. D1‐DE immunoblotting revealed that the prevalence of IgE sensitization to this allergen belonging to the polygalacturonase (PG) family was 70% in tested French allergic patients. In subsequent triple one‐dimensional gel electrophoresis, the Cups pollen PG was shown to promote lectin‐based protein‐protein interactions. Therefore, D1‐DE could be used in routine work as a convenient alternative to 2‐DE immunoblotting for the simultaneous screening of allergenic components under identical experimental conditions, thereby saving considerable amounts of sera and allergen extracts.     

Analysis of E. coli soluble proteins by non‐denaturing micro 2‐DE/3‐DE and MALDI‐MS‐PMF

Escherichia coli (strain K‐12)‐soluble proteins were analyzed by nondenaturing micro 2‐DE and MALDI‐MS‐PMF. The reported conditions of nondenaturing IEF in agarose column gels [Jin, Y., Manabe, T., Electrophoresis 2009, 30, 939–948] were modified to optimize the resolution of cellular soluble proteins. About 300 CBB‐stained spots, the apparent molecular masses of which ranged from ca. 6000 to 10 kDa, were detected. All the spots on two reference 2‐DE gels (one for wide mass range and one for low‐molecular‐mass range) were numbered and subjected to MALDI‐MS‐PMF for the assignment of constituting polypeptides. Most of the spots (310 spots out of 329) provided significant match (p<0.05) with polypeptides in Swiss‐Prot database and totally 228 polypeptide species were assigned. Activity staining of enzymes such as alkaline phosphatase and catalases was performed on the 2‐DE gels and the locations of the activity spots matched well with those of the MS‐assigned polypeptides of the enzymes. Most of the polypeptides with subunit information in Swiss‐Prot (119 polypeptides as homo‐multimers and 25 as hetero‐multimers out of the 228), such as pyruvate dehydrogenase complex which is composed of three enzymatic components, were detected at the apparent mass positions of their polymers, suggesting that the proteins were separated retaining their subunit structures. When a nondenaturing 2‐DE gel was vertically cut into 2 mm strips and one of the strips was subjected to a third‐dimension micro SDS‐PAGE (micro 3‐DE), about 190 CBB‐stained spots were detected. The assignment of the polypeptides separated on the 3‐DE gel would further provide information on protein/polypeptide interactions.     

Performance of nondenaturing micro 2-DE followed by third-dimension SDS-PAGE in the analysis of Escherichia coli soluble proteins

In a previous paper, we reported on the analysis of Escherichia coli (strain K‐12) soluble proteins by nondenaturing micro 2‐DE/3‐DE and MALDI‐MS‐PMF [Manabe, T., Jin, Y., Electrophoresis 2010, 31, 2740–2748]. To evaluate the performance of the 2‐DE/3‐DE technique, a nondenaturing 2‐DE gel just after the second‐dimension run was cut into 12 vertical strips, each 2 mm‐wide strip was set on a micro slab gel, and third‐dimension SDS‐PAGE was run in parallel. Each of the twelve 3‐DE gels showed about 150–200 CBB‐stained spots. Two of the 3‐DE gels were selected for the assignment of polypeptides using MALDI‐MS‐PMF and totally 161 polypeptides were assigned on the two 3‐DE gels, in which 81 have been assigned on the nondenaturing micro 2‐DE gel and 80 were newly assigned. Most of the newly assigned polypeptides resided in faintly stained spots on the 3‐DE gels, which indicates that the polypeptides were purified in the process of the third‐dimension separation. The comparisons of the apparent mass values estimated from the second‐dimension (nondenaturing pore‐gradient PAGE) mobility with those estimated from the third‐dimension (SDS‐PAGE) mobility suggested the oligomer structures of the assigned polypeptides and they matched well with those described in a database (UniProtKnowledgebase). The technique of nondenaturing micro 2‐DE/3‐DE, combined with MALDI‐MS‐PMF, could become an efficient method to obtain information on the quaternary structures of hundreds of cellular soluble proteins simultaneously because of its high efficiency in protein/polypeptide separation and assignment.     

Combination of SDS‐PAGE and intact mass analysis for rapid determination of heterogeneities in monoclonal antibody therapeutics

mAbs are currently mainstream in biopharmaceuticals, and their market has been growing due to their high target specificity. Characterization of heterogeneities in mAbs is performed to secure their quality and safety by physicochemical analyses. However, they require time‐consuming task, which often strain the resources of drug development in pharmaceuticals. Rapid and direct method to determine the heterogeneities should be a powerful tool for pharmaceutical analysis. Considering the advantages of electrophoresis and MS, this study addresses the combination of SDS‐PAGE and intact mass analysis, which provides direct, rapid, and orthogonal determination of heterogeneities in mAb therapeutics. mAb therapeutics that migrated in SDS‐PAGE were recovered from gel by treatment with SDC‐containing buffer. Usage of SDC‐containing buffer as extraction solvent and ethanol‐based staining solution enhanced the recovery of intact IgG from SDS‐PAGE gels. Recovery of mAbs reached more than 86% with 0.2% SD. The heterogeneities, especially N ‐glycan variants in the recovered mAb therapeutics, were clearly determined by intact mass analysis. We believe that the study is important in pharmaceuticals‧ perspective since orthogonal combination of gel electrophoresis and intact mass analysis should be pivotal role for rapid and precise characterization of mAbs.     

Mass spectrometric characterization of the zein protein composition in maize flour extracts upon protein separation by SDS‐PAGE and 2D gel electrophoresis

Highly homogenous α zein protein was isolated from maize kernels in an environment‐friendly process using 95% ethanol as solvent. Due to the polyploidy and genetic polymorphism of the plant source, the application of high resolution separation methods in conjunction with precise analytical methods, such as MALDI‐TOF‐MS, is required to accurately estimate homogeneity of products that contain natural zein protein. The α zein protein product revealed two main bands in SDS‐PAGE analysis, one at 25 kDa and other at 20 kDa apparent molecular mass. Yet, high resolution 2DE revealed approximately five protein spot groups in each row, the first at ca. 25 kDa and the second at ca. 20 kDa. Peptide mass fingerprinting data of the proteins in the two dominant SDS‐PAGE bands matched to 30 amino acid sequence entries out of 102 non‐redundant data base entries. MALDI‐TOF‐MS peptide mapping of the proteins from all spots indicated the presence of only α zein proteins. The most prominent ion signals in the MALDI mass spectra of the protein mixture of the 25 kDa SDS gel band after in‐gel digestion were found at m/z 1272.6 and m/z 2009.1, and the most prominent ion signals of the protein mixture of the 20 kDa band after in‐gel digestion were recorded at m/z 1083.5 and m/z 1691.8. These ion signals have been found typical for α zein proteins and may serve as marker ion signals which upon chymotryptic digestion reliably indicate the presence of α zein protein in two hybrid corn products.     

Rapid superparamagnetic‐beads‐based automated immunoseparation of Zn‐proteins from Staphylococcus aureus with nanogram yield

Pathogenic bacteria have become a serious socio‐economic concern. Immunomagnetic separation‐based methods create new possibilities for rapidly recognizing many of these pathogens. The aim of this study was to use superparamagnetic particles‐based fully automated instrumentation to isolate pathogen Staphylococcus aureus and its Zn(II) containing proteins (Zn‐proteins). The isolated bacteria were immediately purified and disintegrated prior to immunoextraction of Zn‐proteins by superparamagnetic beads modified with chicken anti‐Zn(II) antibody. S. aureus culture was treated with ZnCl₂. Optimal pathogen isolation and subsequent disintegration assay steps were carried out with minimal handling. (i) Optimization of bacteria capturing: Superparamagnetic microparticles composed of human IgG were used as the binding surface for acquiring live S. aureus. The effect of antibodies concentration, ionic strength, and incubation time was concurrently investigated. (ii) Optimization of zinc proteins isolation: pure and intact bacteria isolated by the optimized method were sonicated. The extracts obtained were subsequently analyzed using superparamagnetic particles modified with chicken antibody against zinc(II) ions. (iii) Moreover, various types of bacterial zinc(II) proteins precipitations from particle–surface interactions were tested and associated protein profiles were identified using SDS‐PAGE. Use of a robotic pipetting system sped up sample preparation to less than 4 h. Cell lysis and Zn‐protein extractions were obtained from a minimum of 100 cells with sufficient yield for SDS‐PAGE (tens ng of proteins). Zn(II) content and cell count in the extracts increased exponentially. Furthermore, Zn(II) and proteins balances were determined in cell lysate, extract, and retentate.     

Simultaneous electrophoretic analysis of proteins of very high and low molecular mass using Tris‐acetate polyacrylamide gels

To separate and analyze giant and small proteins in the same electrophoresis gel, we have used a 3–15% polyacrylamide gradient gel containing 2.6% of the crosslinker bisacrylamide and 0.2 M of Tris‐acetate buffer (pH 7.0). Samples were prepared in a sample buffer containing lithium dodecyl sulphate and were run in the gel described above using Tris‐Tricine‐SDS‐sodium bisulfite buffer, pH 8.2, as electrophoresis buffer. Here, we show that this system can be successfully used for general applications of SDS‐PAGE such as CBB staining and immunoblot. Thus, by using Tris‐acetate 3–15% polyacrylamide gels, it is possible to simultaneously analyze proteins, in the mass range of 10–500 kDa, such as HERC1 (532 kDa), HERC2 (528 kDa), mTOR (289 kDa), Clathrin heavy chain (192 kDa), RSK (90 kDa), S6K (70 kDa), β‐actin (42 kDa), Ran (24 kDa) and LC3 (18 kDa). This system is highly sensitive since it allows detection from as low as 10 μg of total protein per lane. Moreover, it has a good resolution, low cost, high reproducibility and allows for analysis of proteins in a wide range of weights within a short period of time. All these features together with the use of a standard electrophoresis apparatus make the Tris‐acetate‐PAGE system a very helpful tool for protein analysis.     

Combination of FASP and fully automated 2D‐LC‐MS/MS allows in‐depth proteomic characterization of mouse zymogen granules

Zymogen granule (ZG) constituents play important roles in pancreatic injury and disease. In previous studies, proteomic analyses with rat zymogen granules were separated by two‐dimensional gel electrophoresis or one‐dimensional SDS–PAGE, followed by in‐gel tryptic digestion. In order to overcome the disadvantage of in‐gel digestion and to carry out further in‐depth proteomic analysis of the zymogen granules, in this study, by combining a filter‐aided sample preparation method and fully automated 2D‐LC‐MS/MS technique, 800 ZG proteins were identified with at least two unique peptides for each protein, 75% of which have not been previously reported. The identified proteins revealed broad diversity in protein identity and function. This is the largest dataset of ZG proteome, and also the first dataset of the mouse ZG proteome, which may help elucidate on the molecular architecture of ZGs and their functions. Copyright © 2012 John Wiley & Sons, Ltd.     

Size‐matched alkyne‐conjugated cyanine fluorophores to identify differences in protein glycosylation

Currently, there are few methods to detect differences in posttranslational modifications (PTMs) in a specific manner from complex mixtures. Thus, we developed an approach that combines the sensitivity and specificity of click chemistry with the resolution capabilities of 2D‐DIGE. In “Click‐DIGE”, posttranslationally modified proteins are metabolically labeled with azido‐substrate analogs, then size‐ and charge‐matched alkyne‐Cy3 or alkyne‐Cy5 dyes are covalently attached to the azide of the PTM by click chemistry. The fluorescently‐tagged protein samples are then multiplexed for 2DE analysis. Whereas standard DIGE labels all proteins, Click‐DIGE focuses the analysis of protein differences to a targeted subset of posttranslationally modified proteins within a complex sample (i.e. specific labeling and analysis of azido glycoproteins within a cell lysate). Our data indicate that (i) Click‐DIGE specifically labels azido proteins, (ii) the resulting Cy‐protein conjugates are spectrally distinct, and (iii) the conjugates are size‐ and charge‐matched at the level of 2DE. We demonstrate the utility of this approach by detecting multiple differentially expressed glycoproteins between a mutant cell line defective in UDP‐galactose transport and the parental cell line. We anticipate that the diversity of azido substrates already available will enable Click‐DIGE to be compatible with analysis of a wide range of PTMs.     

Loss of PEG chain in routine SDS‐PAGE analysis of PEG‐maleimide modified protein

SDS‐PAGE represents a quick and simple method for qualitative and quantitative analysis of protein and protein‐containing conjugates, mostly pegylated proteins. PEG‐maleimide (MAL) is frequently used to site‐specifically pegylate therapeutic proteins via free cysteine residue by forming a thiosuccinimide structure for pursuing homogeneous products. The C–S linkage between protein and PEG‐MAL is generally thought to be relatively stable. However, loss of intact PEG chain in routine SDS‐PAGE analysis of PEG‐maleimide modified protein was observed. It is a thiol‐independent thioether cleavage and the shedding of PEG chain exclusively happens to PEG‐MAL modified conjugates although PEG‐vinylsulfone conjugates to thiol‐containing proteins also through a C–S linkage. Cleavage kinetics of PEG40k‐MAL modified ciliary neurotrophic factor showed this kind of degradation could immediately happen even in 1 min incubation at high temperature and could be detected at physiological temperature and pH, although the rate was relatively slow. This may provide another degradation route for maleimide‐thiol conjugate irrespective of reactive thiol, although the specific mechanism is still not very clear for us. It would also offer a basis for accurate characterization of PEG‐MAL modified protein/peptide by SDS‐PAGE analysis.     

Design and synthesis of a novel fluorescent protein probe for easy and rapid electrophoretic gel staining by using a commonly available UV‐based fluorescent imaging system

A new fluorescent molecular probe, methyl 3‐(3,5‐bis((bis(pyridin‐2‐ylmethyl)amino)‐methyl)‐4‐hydroxyphenyl)‐2‐(5‐(dimethylamino)naphthalene‐1‐sulfonamido) propanoate, dizinc(II) chloride salt (Dansyl‐ 1 ‐Zn(II)), which possesses Zn(II) complexes and a dansyl group, was designed and synthesized to enable the detection of proteins in solution and in high‐throughput electrophoresis by using a UV‐based detection system. Dansyl‐ 1 ‐Zn(II) exhibited weak fluorescence in the absence of proteins and strong green fluorescence at approximately 510 nm in the presence of BSA upon irradiation with light at a wavelength of 345 nm. Compared with conventional protocols for in‐gel SDS‐PAGE protein staining (e.g. silver staining, SYPRO Ruby, and Oriole), the operating times of which range from 90 min to overnight, Dansyl‐ 1 ‐Zn(II) allowed 1‐step protein staining (SDS‐PAGE →Staining →Detection) and shortened the operating time (35 min) with high sensitivity (LOD: 1 ng or less) under 312‐nm or 365‐nm light excitation with orange or red emission filters, respectively. Moreover, Dansyl‐ 1 ‐Zn(II) was successfully applied to protein identification by MS via in‐gel tryptic digestion, Western blotting, and Native‐PAGE. Accordingly, Dansyl‐ 1 ‐Zn(II) may facilitate highly sensitive and high‐throughput protein detection, and it may be widely applicable as a convenient tool in various scientific and medical fields.     

CE detection of N‐(3‐dimethylaminopropyl)‐N‐carbodiimide/N‐hydroxysuccinimide‐coupled proteins after homo‐ and hetero‐crosslinking reactions

Protein–protein conjugates formed by carbodiimide crosslinking reactions have been analyzed for the first time using CE. Lysozyme and BSA were chosen as model proteins to study the efficacy of N‐(3‐dimethylaminopropyl)‐N‐ethylcarbodiimide and N‐hydroxysuccinimide as crosslinkers. Detection of the molecular mass increase was checked by SDS‐PAGE. Commercially available, PVA‐coated capillaries showed appropriate selection, while phospho‐deactivated and dynamic PVA‐coated capillaries did not give suitable resolution. CE was found to be an efficient tool to characterize homo‐ (lysozyme–lysozyme) and hetero‐ (lysozyme–BSA) protein coupling by suitable variations of electrophoretic mobilities.     

A multichannel gel electrophoresis and continuous fraction collection apparatus for high‐throughput protein separation and characterization

To facilitate a direct interface between protein separation by PAGE and protein identification by mass spectrometry, we developed a multichannel system that continuously collects fractions as protein bands migrate off the bottom of gel electrophoresis columns. The device was constructed using several short linear gel columns, each of a different percent acrylamide, to achieve a separation power similar to that of a long gradient gel. A “Counter Free‐Flow” elution technique then allows continuous and simultaneous fraction collection from multiple channels at low cost. We demonstrate that rapid, high‐resolution separation of a complex protein mixture can be achieved on this system using SDS‐PAGE. In a 2.5 h electrophoresis run, for example, each sample was separated and eluted into 48–96 fractions over a mass range of ～10–150 kDa; sample recovery rates were 50% or higher; each channel was loaded with up to 0.3 mg of protein in 0.4 mL; and a purified band was eluted in two to three fractions (200 μL/fraction). Similar results were obtained when running native gel electrophoresis, but protein aggregation limited the loading capacity to about 50 μg per channel and reduced resolution.     

Preventing the mixed detergent micelle effect in two‐dimensional electrophoresis on Tris‐Tricine gels

Application of Tris‐N‐[Tris(hydroxymethyl)methyl]glycine gels for 2DE is hampered by formation of mixed CHAPS–SDS micelles resulting in typical swirling pattern in the low mass range, which makes reliable quantitative and qualitative gel evaluation impossible. Modification of 2DE strip equilibration procedure prevented the direct interaction between both detergents during equilibration process, thus substantially improving gel separation.     

Improved disc SDS‐PAGE for extraction of low molecular weight proteins from serum

The low molecular weight proteins can provide a lot of valuable information of biomarkers. To study these proteins, the high abundance and high molecular weight proteins must be removed prior to analysis. In this work, a simple and inexpensive disc SDS‐PAGE to extract low molecular weight proteins from human serum and cutoff proteins larger than 30 kDa was developed. Some experimental conditions were examined. The experimental results obtained by plate SDS‐PAGE and MALDI‐TOF MS showed that the molecular weight of extracted proteins was about in the range from 0.3 to 28 kDa. Some experiments, including precipitation of proteins in organic solvents, SPE and cytochrome C test, were carried out and the experimental results demonstrated successful recovery of proteins/peptides with molecular weight from several hundreds of dalton to about 30 kDa. The experimental results obtained by plate SDS‐PAGE indicated the repeatability was satisfactory.     

BOP: A basic phenylalanine‐rich oligo‐peptide located on the surface of glycolate oxidase influences its pI values

Glycolate oxidase (GO) consists of identical subunits and therefore should show one definite pI value, but the isolated GO exhibited a range of pIs. This study investigated the underlying cause of this phenomenon. GO was purified and showed a molecular weight of 40 kDa by SDS‐PAGE. Elution behavior on DEAE‐cellulose chromatography and cellulose acetate membrane electrophoresis indicated that the purified GO was highly basic (pI>10.0). Repeated IEF and cIEF analysis showed that the pI of the purified GO was in the range of 10.0–3.25, either in a smear form or as distinct bands. 2‐DE analysis showed that the 40 kDa subunit of GO displayed variable pIs from 9.6 to 3.65. It was likely that the purified GO was actually a complex consisted of GO and an unknown protein. CE‐SDS, SDS‐cellulose acetate membrane electrophoresis and amino acid compositions indicated that the unknown protein was a highly basic polymer (BP) consisting of basic and phenylalanine‐rich oligo‐peptide (BOP). Many BOPs are located on the surface of the acidic GO via ionic and hydrophobic interactions and formed GO‐BOP complex (GC), resulting in a highly basic GC although GO itself was acidic. This hypothesis was further supported by the facts that anti‐GC serum failed to recognize GO, and GC showed a peak at 257 nm although GO has few phenylalanine residues. Irregular and incomplete disassociation between GO and BOP was observed in IEF and cIEF, resulting in various intermediates with different ratios of GO/BOP, which could be the reason for the range of pIs observed for GO.