Comparison of the electron capture dissociation fragmentation behavior of doubly and triply protonated peptides from trypsin, Glu-C, and chymotrypsin digestion

In bottom-up proteomics, proteolytically derived peptides from proteins of interest are analyzed to provide sequence information for protein identification and characterization. Electron capture dissociation (ECD), which provides more random cleavages compared to "slow heating" techniques such as collisional activation, can result in greater sequence coverage for peptides and proteins. Most bottom-up proteomics approaches rely on tryptic doubly protonated peptides for generating sequence information. However, the effectiveness, in terms of peptide sequence coverage, of tryptic doubly protonated peptides in ECD remains to be characterized. Herein, we examine the ECD fragmentation behavior of 64 doubly- and 64 triply protonated peptides (i.e., a total of 128 peptide ions) from trypsin, Glu-C, and chymotrypsin digestion in a Fourier transform ion cyclotron resonance mass spectrometer. Our findings indicate that when triply protonated peptides are fragmented in ECD, independent of which proteolytic enzyme was used for protein digestion, more c- and z-type product ions are observed, and the number of complementary fragment pairs increases dramatically (44%). In addition, triply protonated peptides provide an increase (26%) in peptide sequence coverage. ECD of tryptic peptides, in both charge states, resulted in higher sequence coverage compared to chymotryptic and Glu-C digest peptides. The peptide sequence coverage we obtained in ECD of tryptic doubly protonated peptides (64%) is very similar to that reported for electron transfer dissociation of the same peptide type (63%).     

Label-free mass spectrometry-based relative quantification of proteins separated by one-dimensional gel electrophoresis

Here we present a matrix-assisted laser desorption/ionization tandem time-of-flight (MALDI–TOF/TOF)-based label-free relative protein quantification strategy that involves sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS–PAGE) separation of proteins followed by in-gel trypsin digestion. The main problem encountered in gel-based protein quantification is the difficulty in achieving complete and consistent proteolytic digestion. To solve this problem, we developed a high-pressure-assisted in-gel trypsin digestion method that is based on pressure cycling technology (PCT). The PCT approach performed at least as well as the conventional overnight in-gel trypsin digestion approach in parameters such as number of peaks detected, number of peptides identified, and sequence coverage, and the digestion time was reduced to 45 min. The gel/mass spectrometry (MS)-based label-free protein quantification method presented in this work proved the applicability of the signal response factor concept for relative protein quantification previously demonstrated by other groups using the liquid chromatography (LC)/MS platform. By normalizing the average signal intensities of the three most intense peptides of each protein with the average intensities of spiked synthetic catalase tryptic peptides, which we used as an internal standard, we observed spot-to-spot and lane-to-lane coefficients of variation of less than 10 and 20%, respectively. We also demonstrated that the method can be used for determining the relative quantities of proteins comigrating during electrophoretic separation.     

An in-gel digestion procedure that facilitates the identification of highly hydrophobic proteins by electrospray ionization-mass spectrometry analysis

A procedure is described for in-gel tryptic digestion of proteins that allows the direct analysis of eluted peptides in electrospray ionization (ESI) mass spectrometers without the need of a postdigestion desalting step. It is based on the following principles: (a) a thorough desalting of the protein in-gel before digestion that takes advantage of the excellent properties of acrylamide polymers for size exclusion separations, (b) exploiting the activity of trypsin in water, in the absence of inorganic buffers, and (c) a procedure for peptide extraction using solvents of proven efficacy with highly hydrophobic peptides. Quality of spectra and sequence coverage are equivalent to those obtained after digestion in ammonium bicarbonate for hydrophilic proteins detected with Coomassie blue, mass spectrometry-compatible silver or imidazole-zinc but are significantly superior for highly hydrophobic proteins, such as membrane proteins with several transmembrane domains. ATPase subunit 9 (GRAVY 1.446) is a membrane protein channel, lipid-binding protein for which both the conventional in-gel digestion protocol and in solution digestion failed. It was identified with very high sequence coverage. Sample handling after digestion is notably simplified as peptides are directly loaded into the ESI source without postdigestion processing, increasing the chances for the identification of hydrophobic peptides.     

Extended Range Proteomic Analysis (ERPA): a new and sensitive LC-MS platform for high sequence coverage of complex proteins with extensive post-translational modifications-comprehensive analysis of beta-casein and epidermal growth factor receptor (EGFR)

We have developed a new and sensitive LC-MS platform, Extended Range Proteomic Analysis (ERPA), which is able to achieve very high sequence coverage and comprehensive characterization of post-translational modifications in complex proteins. This new platform provides advantages of both the top-down and bottom-up proteomic approaches by combining (i) digestion of the protein with an enzyme, such as Lys-C, which cuts less frequently than trypsin, leading to on average a higher molecular weight peptide size, (ii) high-performance LC separation of the resulting fragments, (iii) a new data acquisition strategy using the LTQ-FTMS, a hybrid mass spectrometer that couples a linear ion trap with a Fourier transform ion cyclotron resonance (FTICR) cell, for analysis of peptides in the range of 0.5 to 10 kDa, and (iv) new data analysis methods for assigning large peptide structures and determining the site of attachment of post-translational modifications as well as structural features from the accurate precursor mass together with MS(2) and MS(3) fragmentations. The LC retention of the Lys-C fragments is increased, relative to a tryptic digest, due to the generally greater hydrophobicity of the larger peptides, a result that is particularly important for peptides containing hydrophilic modifications such as glycosylation and phosphorylation. Furthermore, additional positively charged arginine and lysine residues in the Lys-C fragments enhance the sensitivity of the post-translationally modified phospho- and glycopeptides by at least 10-fold relative to tryptic fragments. In typical operation, the FTICR cell provides a survey scan with the high mass resolution (> 100 000) and accurate mass (<2 ppm) to characterize the higher charge-state precursor ions of the larger peptides. In parallel, the linear ion trap provides MS(2) and MS(3) fragmentation spectra, with a scan speed sufficiently fast for on-line LC-MS. Together, these data provide multiple means to determine or enhance the confidence of assignment of large or complicated peptide. Using ERPA, we demonstrate >95% sequence coverage in the analysis of two heavily phosphorylated and glycosylated proteins, beta-casein at the 50 fmole level and the epidermal growth factor receptor (EGFR) at the 1 pmole level. In summary, the combination of digestion strategy, high-performance separation, and the hybrid LTQ-FTMS instrument enables comprehensive characterization of large proteins, including posttranslational modifications.     

Protease inhibitors as possible pitfalls in proteomic analyses of complex biological samples

Sample preparation, especially protein and peptide fractionation prior to identification by mass spectrometry (MS), is typically applied to reduce sample complexity. The second key element in this process is proteolytic digestion, which is performed most often with trypsin. Optimization of this step is an important factor in order to achieve both speed and better performance of proteomic analysis, and tryptic digestion prior to the MS analysis has been a topic of many studies. To date, only a few studies have paid attention to the negative interaction between the proteolytic enzyme and sample components, and sample losses caused by these interactions. In this study, we demonstrated impaired activity after "in solution" tryptic digestion of plasma proteins caused by a potent trypsin inhibitor family, inter-alpha inhibitor proteins. Sample boiling followed by gel electrophoretic separation and "in-gel" digestion drastically improved both the number of identified proteins and the sequence coverage in subsequent LC-ESI-MS/MS. The present investigations show that a thorough validation is necessary when "in solution" digestion followed by LC-MS analysis of complex biological samples is performed. The parallel use of two or more different mass spectrometers can also yield additional information and contribute to further method validation.     

Confetti: A Multiprotease Map of the HeLa Proteome for Comprehensive Proteomics

Bottom-up proteomics largely relies on tryptic peptides for protein identification and quantification. Tryptic digestion often provides limited coverage of protein sequence because of issues such as peptide length, ionization efficiency, and post-translational modification colocalization. Unfortunately, a region of interest in a protein, for example, because of proximity to an active site or the presence of important post-translational modifications, may not be covered by tryptic peptides. Detection limits, quantification accuracy, and isoform differentiation can also be improved with greater sequence coverage. Selected reaction monitoring (SRM) would also greatly benefit from being able to identify additional targetable sequences. In an attempt to improve protein sequence coverage and to target regions of proteins that do not generate useful tryptic peptides, we deployed a multiprotease strategy on the HeLa proteome. First, we used seven commercially available enzymes in single, double, and triple enzyme combinations. A total of 48 digests were performed. 5223 proteins were detected by analyzing the unfractionated cell lysate digest directly; with 42% mean sequence coverage. Additional strong-anion exchange fractionation of the most complementary digests permitted identification of over 3000 more proteins, with improved mean sequence coverage. We then constructed a web application (https://proteomics.swmed.edu/confetti) that allows the community to examine a target protein or protein isoform in order to discover the enzyme or combination of enzymes that would yield peptides spanning a certain region of interest in the sequence. Finally, we examined the use of nontryptic digests for SRM. From our strong-anion exchange fractionation data, we were able to identify three or more proteotypic SRM candidates within a single digest for 6056 genes. Surprisingly, in 25% of these cases the digest producing the most observable proteotypic peptides was neither trypsin nor Lys-C. SRM analysis of Asp-N versus tryptic peptides for eight proteins determined that Asp-N yielded higher signal in five of eight cases.Mass-spectrometry based proteomics provides various tools to detect and quantify changes in protein expression or post-translational modifications (PTMs).¹ In bottom-up proteomics, these analyses typically involve using peptides derived from the tryptic digestion of proteins. Although trypsin is a robust enzyme and provides peptides suitable for mass spectrometry, not all sequences are detectable by this approach (1). Sequences may be missed because of the limited number and uneven distribution of lysine and arginine residues throughout a protein sequence. Tryptic coverage of interesting regions of sequence, such as trans-membrane domains that may contain notable PTMs, is often incomplete (2). Sequence coverage greater than that offered by trypsin is a requirement for many studies (3).Missing sequence coverage can also adversely affect analysis by selected reaction monitoring (SRM). Although SRM has emerged in recent years as a highly sensitive and accurate method for protein detection and quantification (4), it is sometimes hampered by the limited number of targetable peptides (primarily tryptic peptides) available in public databases. Improving amino acid sequence coverage would provide more targets for SRM assay development, facilitating protein quantification and the ability to target specific isoforms or sequence regions of interest.Fractionation is commonly employed to increase protein identifications and improve sequence coverage, but introduces a number of complexities. Separation of proteins or peptides significantly increases the number of samples to analyze and the amount of data to process. Species may be present in multiple fractions or in different fractions in different runs, which makes quantitative analysis with techniques like SRM difficult. However, SRM has sufficient sensitivity that peptides identified in fractionated discovery experiments are often targetable in whole lysate (5).One approach to increase sequence coverage without fractionation or purification is to use proteases other than trypsin for digestion (6, 7). In recent years, there has been a surge in the use of alternative proteases to improve sequence coverage. Biringer et al. demonstrated in 2006 that combining the MS data from tryptic and Glu-C digestions of human cerebrospinal fluid (CSF) resulted in increased protein identifications. Sequence coverage also improved versus individual enzyme digests, though this was shown only for the 38 most confidently identified proteins (8). In 2010, Swaney et al. expanded the multi-enzyme approach to five specific proteases (trypsin, Lys-C, Arg-C, Asp-N, and Glu-C) and showed that although this method only modestly increases the number of protein IDs, it significantly increases the average sequence coverage (from 24.5% to 43.4%) (9). The most comprehensive coverage of a human cell line to date was reported by Nagaraj et al., in which in-depth proteomics with two levels of prefractionation and analysis using trypsin, Lys-C, and Glu-C was carried out for the HeLa cell line. A total of 10,255 proteins and 166,420 peptides were identified (10). However, none of these studies investigated the use of consecutive enzymatic digestion on a sample.The Mann laboratory recently introduced a strategy, using consecutive digestion in conjunction with filter-aided sample preparation (FASP), for two-step and three-step digestions with various combinations of trypsin, Lys-C, Glu-C, Arg-C, and Asp-N (11). The consecutive use of Lys-C and trypsin enabled the identification of up to 40% more proteins and phosphorylation sites in comparison to trypsin alone. However, a systematic study of all common commercially available proteases for comprehensive mapping of the human proteome has not yet been performed.These prior studies have clearly shown the ability of tandem and parallel protease digestion to improve protein ID and sequence coverage. However, their focus has been either to improve the number of protein identifications or to improve the sequence coverage of few targets. In an effort to provide a resource for targeting as much of the amino acid sequence in a human cell line as possible, we conducted a comprehensive study in which seven commercially available enzymes were used individually and in combination. First, we digested HeLa lysate with a total of 48 single, double, and triple enzyme combinations. Across these combinations we detected 5223 proteins with an average of 42% sequence coverage by analyzing the total cell lysate digest without fractionation. We then selected the best five complementary digests for each of Orbitrap elite collision induced dissociation (CID) and Q exactive higher-energy CID (HCD) analyses. A strong-anion exchange fractionation strategy was applied to these best digests, from which we were able to identify 8470 proteins with 40.3% mean sequence coverage. Combining all digests, both unfractionated and SAX, gave 8539 proteins with 44.7% mean coverage. These data are now publically available (https://proteomics.swmed.edu/confetti) and can be queried using a simple web interface to discover the enzyme or combination of enzymes required to yield a peptide spanning a certain region of interest on a protein.Finally, we performed a proof-of-concept experiment to demonstrate that SRM assays using nontryptic peptides are viable, and in some cases more sensitive than tryptic assays. Though tryptic peptides are generally sufficient for protein quantification by SRM we believe there will be increased use of nontryptic SRM as coverage of specific regions of sequence becomes more important. For example, bio-marker studies considering the presence of specific PTMs rather than general protein abundance are increasingly common. Truly comprehensive PTM studies require access to the nontryptic proteome.     

Identification of proteins from two-dimensional polyacrylamide gels using a novel acid-labile surfactant

Protein identification by peptide mass mapping usually involves digestion of gel-separated proteins with trypsin, followed by mass measurement of the resulting peptides by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS). Positive identification requires measurement of enough peptide masses to obtain a definitive match with sequence information recorded in protein or DNA sequence databases. However, competitive binding and ionization of residual surfactant introduced during polyacrylamide gel electrophoresis (PAGE) can inhibit solid-phase extraction and MS analysis of tryptic peptides. We have evaluated a novel, acid-labile surfactant (ALS) as an alternative to sodium dodecylsulfate (SDS) for two-dimensional (2-D) PAGE separation and MALDI-MS mapping of proteins. ALS was substituted for SDS at the same concentration in buffers and gels used for 2-D PAGE. Manual and automated procedures for spot cutting and in-gel digestion were used to process Coomassie stained proteins for MS analysis. Results indicate that substituting ALS for SDS during PAGE can significantly increase the number of peptides detected by MALDI-MS, especially for proteins of relatively low abundance. This effect is attributed to decomposition of ALS under acidic conditions during gel staining, destaining, peptide extraction and MS sample preparation. Automated excision and digestion procedures reduce contamination by keratin and other impurities, further enhancing MS identification of gel separated proteins.     

Combined in-gel tryptic digestion and CNBr cleavage for the generation of peptide maps of an integral membrane protein with MALDI-TOF mass spectrometry

A limitation of the in-gel approaches for the generation of peptides of membrane proteins is the size and hydrophobicity of the fragments generated. For membrane proteins like the lactose transporter (LacS) of Streptococcus thermophilus, tryptic digestion or CNBr cleavage yields several hydrophobic fragments larger than 3.5 kDa. As a result, the sequence coverage of the membrane domain is low when the in-gel tryptic-digested or CNBr-cleaved fragments are analyzed by matrix-assisted laser desorption/ionization-time-of-flight (MALDI-TOF) mass spectrometry (MS). The combination of tryptic digestion and subsequent CNBr cleavage on the same gel pieces containing LacS approximately doubled the coverage of the hydrophobic membrane domain compared to the individual cleavage methods, while the coverage of the soluble domain remained complete. The fragments formed are predominantly below m/z 2500, which allows accurate mass measurement.     

Comparative study of workflows optimized for in-gel, in-solution, and on-filter proteolysis in the analysis of plasma membrane proteins

Proteomic studies of plasma membrane proteins are challenged by the limited solubility of these proteins and the limited activity of proteolytic enzymes in solubilizing agents such as SDS. In this work, we have evaluated three bottom-up workflows to obtain tryptic peptides from plasma membrane proteins solubilized with 2% SDS. The workflows are in-gel digestion, in-solution digestion, and on-filter digestion. The efficiencies of these strategies, optimized to employ different matrices for trypsin cleavage, were compared using a plasma membrane sample enriched from multiple myeloma cells using a nanoparticle pellicle. On the basis of the number of proteins identified, number of transmembrane proteins identified, hydrophobicity, and spectral count per protein, the workflow that uses in-gel digestion is the most advantageous approach for analysis of plasma membrane proteins.     

Analysis of the adenovirus type 5 proteome by liquid chromatography and tandem mass spectrometry methods

We compared detection sensitivity and protein sequence coverage of the adenovirus type 5 proteome achievable by liquid chromatography and tandem mass spectroscopy (LC/MS/MS) using three sample preparation and clean up methods. Tryptic digestion was performed on either purified viral proteins or whole virus, and followed by shotgun sequencing using tandem mass spectrometry for peptide identification. We used a recombinant adenovirus type 5 as a test system. The methods included separation of adenoviral proteins by reversed-phase high-performance liquid chromatography followed by tryptic digestion and analysis by LC/MS/MS. Alternatively, the purified whole virus was digested with trypsin and the peptides separated either by one-dimensional (reversed-phase) or by two-dimensional (cation exchange and reversed-phase) chromatography and analyzed by tandem mass spectrometry. A total of 11 protein species were identified from 154 peptides. All of the major viral proteins were found. In addition, two minor proteins, the 23 kDa viral protease and the late L1 protein, were identified for the first time by chromatography based assays. The 23 kDa viral protease, present at only 10 copies per virus, and representing 0.2% of the protein content of the virus, was detected by the 2D LC/MS/MS analysis of the whole virus digest from a sample containing only 70 fmols of the protein. This demonstrates the high sensitivity and selectivity of the method. The 2D LC/MS/MS analysis of the whole virus digest was also able to detect all viral proteins with copy numbers at or above 10/virus particle, with broad coverage of the amino acid sequences. Coverage ranged from 2 to 54%, a majority between 20 and 35%, suggesting the possibility of using this analysis to assess the purity of the virus preparations. This broad coverage may also provide a useful approach to identify posttranslational modifications on the structural proteins of the adenovirus.     

Identification of a novel phosphorylation site in human androgen receptor by mass spectrometry

An N-terminal hexahistidine-tagged full-length human androgen receptor protein (His(6)-hAR) was overexpressed and purified to apparent homogeneity in the presence of dihydrotestosterone (DHT) in our previous studies. In-gel trypsin digestion of the purified DHT-bound His(6)-hAR, and tryptic peptide mapping using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI/TOF-MS), detected a total of 17 peptides (21% coverage of hAR) with 9 peptides originating from the ligand-binding domain (LBD, 31% coverage of LBD). Amino acid sequencing analysis of the tryptic peptides from a separate in-gel digestion of the His(6)-hAR, using HPLC-coupled electrospray ionization ion trap mass spectrometry (LC/ESI-ITMS and MS/MS), unambiguously confirmed 21 peptides with 19% coverage of the hAR, of which 11 peptides originated from the LBD (35% coverage of LBD). These 21 peptides included 11 out of the 17 peptides detected by MALDI/TOF-MS. In addition, a novel serine phosphorylation site (Ser(308)) within the N-terminal transactivation domain of hAR was identified.     

Effect of cleavage enzyme, search algorithm and decoy database on mass spectrometric identification of wheat gluten proteins

While tandem mass spectrometry (MS/MS) is routinely used to identify proteins from complex mixtures, certain types of proteins present unique challenges for MS/MS analyses. The major wheat gluten proteins, gliadins and glutenins, are particularly difficult to distinguish by MS/MS. Each of these groups contains many individual proteins with similar sequences that include repetitive motifs rich in proline and glutamine. These proteins have few cleavable tryptic sites, often resulting in only one or two tryptic peptides that may not provide sufficient information for identification. Additionally, there are less than 14,000 complete protein sequences from wheat in the current NCBInr release. In this paper, MS/MS methods were optimized for the identification of the wheat gluten proteins. Chymotrypsin and thermolysin as well as trypsin were used to digest the proteins and the collision energy was adjusted to improve fragmentation of chymotryptic and thermolytic peptides. Specialized databases were constructed that included protein sequences derived from contigs from several assemblies of wheat expressed sequence tags (ESTs), including contigs assembled from ESTs of the cultivar under study. Two different search algorithms were used to interrogate the database and the results were analyzed and displayed using a commercially available software package (Scaffold). We examined the effect of protein database content and size on the false discovery rate. We found that as database size increased above 30,000 sequences there was a decrease in the number of proteins identified. Also, the type of decoy database influenced the number of proteins identified. Using three enzymes, two search algorithms and a specialized database allowed us to greatly increase the number of detected peptides and distinguish proteins within each gluten protein group.     

A systematical analysis of tryptic peptide identification with reverse phase liquid chromatography and electrospray ion trap mass spectrometry

In this study we systematically analyzed the elution condition of tryptic peptides and the characteristics of identified peptides in reverse phase liquid chromatography and electrospray tandem mass spectrometry (RPLC-MS/MS) analysis. Following protein digestion with trypsin, the peptide mixture was analyzed by on-line RPLC-MS/MS. Bovine serum albumin (BSA) was used to optimize acetonitrile (ACN) elution gradient for tryptic peptides, and Cytochrome C was used to retest the gradient and the sensitivity of LC-MS/MS. The characteristics of identified peptides were also analyzed. In our experiments, the suitable ACN gradient is 5% to 30% for tryptic peptide elution and the sensitivity of LC-MS/MS is 50 fmol.Analysis of the tryptic peptides demonstrated that longer (more than 10 amino acids) and multi-charge state ( 2, 3) peptides are likely to be identified, and the hydropathicity of the peptides might not be related to whether it is more likely to be identified or not. The number of identified peptides for a protein might be used to estimate its loading amount under the same sample background. Moreover, in this study the identified peptides present three types of redundancy, namely identification, charge, and sequence redundancy, which may repress low abundance protein identification.     

Improvement of an in-gel tryptic digestion method for matrix-assisted laser desorption/ionization-time of flight mass spectrometry peptide mapping by use of volatile solubilizing agents

The combination of matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS), in-gel enzymatic digestion of proteins separated by two-dimensional gel electrophoresis and searches of molecular weight in peptide-mass databases is a powerful and well established method for protein identification in proteomics analysis. For successful protein identification by MALDI-TOF mass spectrometry of peptide mixtures, critical parameters include highly specific enzymatic cleavage, high mass accuracy and sufficient numbers and sequence coverage of the peptides which can be analyzed. For in-gel digestion with trypsin, the method employed should be compatible both with enzymatic cleavage and subsequent MALDI-TOF MS analysis. We report here an improved method for preparation of peptides for MALDI-TOF MS mass fingerprinting by using volatile solubilizing agents during the in-gel digestion procedure. Our study clearly demonstrates that modification of the in-gel digestion protocols by addition of dimethyl formamide (DMF) or a mixture of DMF/N,N-dimethyl acetamide at various concentrations can significantly increase the recovery of peptides. These higher yields of peptides resulted in more effective protein identification.     

Evaluation of the application of sodium deoxycholate to proteomic analysis of rat hippocampal plasma membrane

Detergents have been widely used for the solubilization of membrane proteins and the improvement of their digestion. In this paper, we have evaluated the application of sodium deoxycholate (SDC) to the solubilization and digestion of rat hippocampal plasma membrane (PM) proteins. For in-solution digestion, rat hippocampal PM fraction from sucrose-density gradient centrifugation was solubilized by boiling in 1.0% SDC, and directly digested without dilution. During the in-gel digestion of the hippocampal PM proteins separated by SDS-PAGE, 0.1% SDC was added. Before analysis of peptide mixture by liquid chromatography and electrospray mass spectrometry, SDC in the tryptic digests was removed by centrifugation following acidification. Use of 1.0% SDC in solubilization and in-solution digestion of rat PM proteins had led to 77 PM or membrane-associated proteins identified, a more than 2-fold increase over that by use of SDS. The addition of 0.1% SDC to the in-gel digestion of SDS-PAGE-resolved membrane proteins remarkably enhanced the coverage of tryptic peptides and the number of hydrophobic membrane proteins identified. Being a cheaper and more tractable acid-insoluble detergent, SDC could be used at higher concentration in the solubilization and tryptic digestion of proteins including PM proteins with the purpose of enhancing the protein solubility and at the same time making no interference with trypsin activity and subsequent analyses.     

The proteomic analysis improved by cleavage kinetics‐based fractionation of tryptic peptides

Selective enrichment of specific peptides is an effective way to identify low abundance proteins. Fractionation of peptides prior to mass spectrometry is another widely used approach to reduce sample complexity in order to improve proteome coverage.In this study, we designed a multi‐stage digestion strategy to generate peptides with different trypsin cleavage kinetics. It was found that each of the collected peptide fractions yielded many new protein identifications compared to the control group due to the reduced complexity. The overlapping peptides identified between adjacent fractions were very low, indicating that each fraction had different sets of peptides. The multi‐stage digestion strategy separates tryptic peptides with different cleavage kinetics while RPLC separates peptides with different hydrophobicity. These two separation strategies were highly orthogonal, and showed an effective multidimensional separation to improve proteome coverage.     

Sulfo‐NHS‐SS‐biotin derivatization: A versatile tool for MALDI mass analysis of PTMs in lysine‐rich proteins

The discovery of PTMs in proteins by MS requires nearly complete sequence coverage of the detected proteolytic peptides. Unfortunately, mass spectrometric analysis of the desired sequence fragments is often impeded due to low ionization efficiency and/or signal suppression in complex samples. When several lysine residues are in close proximity tryptic peptides may be too short for mass analysis. Moreover, modified peptides often appear in low stoichiometry and need to be enriched before analysis. We present here how the use of sulfo‐NHS‐SS‐biotin derivatization of lysine side chain can help to detect PTMs in lysine‐rich proteins. This label leads to a mass shift which can be adjusted by reduction of the SS bridge and alkylation with different reagents. Low intensity peptides can be enriched by use of streptavidin beads. Using this method, the functionally relevant protein kinase A phosphorylation site in 5‐lipoxygenase was detected for the first time by MS. Additionally, methylation and acetylation could be unambiguously determined in histones.     

Identification and quantification of DNA repair proteins by liquid chromatography/isotope-dilution tandem mass spectrometry using their fully 15N-labeled analogues as internal standards

Oxidatively induced DNA damage is implicated in disease, unless it is repaired by DNA repair. Defects in DNA repair capacity may be a risk factor for various disease processes. Thus, DNA repair proteins may be used as early detection and therapeutic biomarkers in cancer and other diseases. For this purpose, the measurement of the expression level of these proteins in vivo will be necessary. We applied liquid chromatography/isotope-dilution tandem mass spectrometry (LC-MS/MS) for the identification and quantification of DNA repair proteins human 8-hydroxyguanine-DNA glycosylase (hOGG1) and Escherichia coli formamidopyrimidine DNA glycosylase (Fpg), which are involved in base-excision repair of oxidatively induced DNA damage. We overproduced and purified (15)N-labeled analogues of these proteins to be used as suitable internal standards to ensure the accuracy of quantification. Unlabeled and (15)N-labeled proteins were digested with trypsin and analyzed by LC-MS/MS. Numerous tryptic peptides of both proteins were identified on the basis of their full-scan mass spectra. These peptides matched the theoretical peptide fragments expected from trypsin digestion and provided statistically significant protein scores that would unequivocally identify these proteins. We also recorded the product ion spectra of the tryptic peptides and defined the characteristic product ions. Mixtures of the analyte proteins and their (15)N-labeled analogues were analyzed by selected-reaction monitoring on the basis of product ions. The results obtained suggest that the methodology developed would be highly suitable for the positive identification and accurate quantification of DNA repair proteins in vivo as potential biomarkers for cancer and other diseases.     

Improve the coverage for the analysis of phosphoproteome of HeLa cells by a tandem digestion approach

Complete coverage of all phosphorylation sites in a proteome is the ultimate goal for large-scale phosphoproteome analysis. However, only making use of one protease trypsin for protein digestion cannot cover all phosphorylation sites, because not all tryptic phosphopeptides are detectable in MS. To further increase the phosphoproteomics coverage of HeLa cells, we proposed a tandem digestion approach by using two different proteases. By combining the data set of the first Glu-C digestion and the second trypsin digestion, the tandem digestion approach resulted in the identification of 8062 unique phosphopeptides and 8507 phosphorylation sites in HeLa cells. The conventional trypsin digestion approach resulted in the identification of 3891 unique phosphopeptides and 4647 phosphorylation sites. It was found that the phosphorylation sites identified from the above two approaches were highly complementary. By combining above two data sets, in total we identified 10899 unique phosphopeptides and 11262 phosphorylation sites, corresponding to 3437 unique phosphoproteins with FDR < 1% at peptide level. We also compared the kinase motifs extracted from trypsin, Glu-C, or a second trypsin digestion data sets. It was observed that basophilic motifs were more frequently found in the trypsin and the second trypsin digestion data sets, and the acidic motifs were more frequently found in the Glu-C digestion data set. These results demonstrated that our tandem digestion approach is a good complement to the conventional trypsin digestion approach for improving the phosphoproteomics analysis coverage of HeLa cells.     

Sodium-deoxycholate-assisted tryptic digestion and identification of proteolytically resistant proteins

Identification of proteolytically resistant proteins with compact molecular structure and/or poor water solubility is a challenge in current proteomic study. In this study, sodium deoxycholate (SDC)-assisted tryptic digestion and identification of proteolytically resistant myoglobin and integral membrane proteins were systematically investigated. When the effect of SDC up to 10% on trypsin activity was investigated, little decrease in the trypsin activity was observed in 1% SDC solution, 2-5% SDC decreased the enzyme activity only by about 13.6%, and even in the presence of 10% SDC trypsin still retained 77.4% of its activity. Matrix-assisted laser desorption ionization time of flight mass spectrometry analysis showed that SDC could be removed from sample solution with acid treatment followed by centrifugation, and the remaining SDC, if any, had little effect on mass spectrometry analysis with regard to the number and signal/noise ratio of ions in the mass spectra. Compared with urea and methanol, two other commonly used additives in addition to SDS in proteomic analysis, SDC improved more efficiently the denaturation, solubilization, and tryptic digestion of proteins, particularly proteolytically resistant myoglobin and integral membrane proteins, thereby enhancing the efficiency of their identification with regard to the number of identified proteins and unique peptides and the sequence coverage of matched proteins.