Efficient and clean charge derivatization of peptides for analysis by mass spectrometry

Charge derivatization with succinimidyloxycarbonylmethyl tris(2,4,6‐trimethoxyphenyl)phosphonium bromide (TMPP‐Ac‐OSu) has great potential in several aspects of proteomics, such as peptide de novo sequencing, PTM analysis, etc. However, the excess reagent and its side products greatly limited its scope of use. Here, we report an improved method to perform charge derivatization of peptides by TMPP‐Ac‐OSu without interference from the excess reagent and corresponding side products. Briefly, the protein was first separated on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS‐PAGE) or coagulated with the gel. The protein in‐gel was then incubated with a high concentration of reagent, followed by extensive washing. Afterwards, the protein was in‐gel digested with trypsin according to the routine protocol. The mainly resultant peptides were attached with one positive tag on the N‐termini or Lys‐ε‐NH₂. The process has been successfully applied to 2‐DE resolved protein spots. Compared to the native proteins, the derivatized counterparts have higher rates of PMF identification and more straightforward tandem mass spectra. This promising method should pave the way for the practical use of charge derivatization in proteomics. Copyright © 2010 John Wiley & Sons, Ltd.     

Selective detection of thiosulfate-containing peptides using tandem mass spectrometry

Incubation of proteins or peptides containing disulfide bonds (S-S) with sodium sulfite (Na(2)SO(3)) cleaves S-S bonds producing approximately equimolar amounts of free thiols (-SH) and thiosulfates (-S-SO(3)H), a process known as sulfitolysis. Proteins and peptides containing thiosulfates were separated by reverse-phase high-performance liquid chromatography (RP-HPLC) and characterized by mass spectrometry (MS) and peptide mapping. The mass of the thiosulfate-containing peptide formed from oxidized insulin B chain was 3478.02 Da, 80 Da greater than the reduced peptide and corresponding precisely to addition of sulfur trioxide (SO(3)). Disulfide bond cleavage was also observed using RP-HPLC and MS after incubation of the intramolecular homodimer of mouse S100A8 (mass 20614 Da). The mass of HPLC-separated A8-SH was 10308 Da, and 10388 Da for A8-S-SO(3)H. Loss of SO(3) from multiply charged precursor ions was generally observed at elevated declustering potentials in the source region or within q(2) at relatively low collision energies (approximately 20 V). The characteristic loss of SO(3) at low collision energies preceded peptide backbone fragmentations at higher collision energies. Accurate mass measurement and charge-state discrimination, using a hybrid quadrupole time-of-flight mass spectrometer, allowed specific detection of thiosulfate-containing peptides. An information-dependent acquisition method, where the switch criterion was loss of m/z 79.9568, specifically identified 11 thiosulfate-containing peptides using nano-LC/MS from a tryptic digest of bovine serum albumin (BSA).     

Computer-controlled sequencing of peptides by tandem mass spectrometry

A fully automated computer-controlled system was used to generate series of different linked scans at constant B2E and constant neutral loss in the second field-free region. This system has been shown to be suitable for deriving the amino acid sequence of oligopeptides.     

Molecular species analysis of arachidonate containing glycerophosphocholines by tandem mass spectrometry

Carboxylate anions arising from collision-induced dissociation (CID) of the [M - 15]^- ion produced by fast atom bombardment (FAB) of glycerophosphocholine (GPCho) were previously shown to be produced in an abundance ratio of 1:3 for the carboxylic acids esterified at sn - 1 and sn - 2, respectively. This observation has been confirmed in a series of 13 synthetic GPCho molecular species. A good correlation was found between the isomeric purity of GPCho molecular species as determined by negative-ion FAB/CID analysis and the isomeric purity of the sn - 2 fatty acid using a phospholipase A₂ assay. Negative-ion FAB mass spectra of several 1-0-alkyl-2-acyl-GPCho molecular species were found to be similar to those of diacyl GPCho. However, the cm spectra from the major high-mass ions are different from those of the diacyl species in that the [M - 15]^- ion yields only one carboxylate anion and the [M - 86]^- undergoes a neutral loss of the sn - 2 carboxylic acid as a major decomposition product. These results suggest several rules useful for structural characterization of GPCho molecular species by negative-ion tandem mass spectrometry (MS/MS): (1) For diacyl species, the mass of the two carboxyl anions plus the mass of the GPeho backbone (minus a methyl group) must correspond to the mass of the [M - 15] anion; (2) for diacyl species there is a carboxylate anion ratio approximately 1:3 for the substituents at sn - 1 and sn - 2; and (3) for alkylether species, only one fatty acyl group is present, and the difference between the [M - 15] ion and the GPCho backbone (minus methyl) plus the fatty acyl group at sn - 2 corresponds to an alkylether substituent. (4) Assignment of ether-linked molecular species can be made from the [M - 86]^- ion, which has a strong neutral loss of the sn - 2 fatty acid. Analysis of GPCho isolated from human neutrophils by total lipid extraction and normal-phase HPLC was carried out by negative-ion FABand MS/MS. The major arachidonate-eontaining molecular species, which comprise only 5% of total GPCho, were identified by using precursor ion scans for the arachidonate anion, m/ z 303. Decomposition of identified. precursor ions permitted the assignment of those molecular species of GPCho that contain arachidonate at sn - 2 and identification of the substituent at the sn - 1 position. These results were compared to previously identified molecular species from human neutrophils. Several minor arachidonate-containing molecular species were tentatively identified.     

Study of peptides containing modified lysine residues by tandem mass spectrometry: precursor ion scanning of hexanal-modified peptides

Upon hexanal-modification in the presence of NaCNBH(3), the oxidized B chain of insulin becomes mono- and further dialkylated on both the N-terminal and Lys(29) residues. A pseudo-MS(3) study was performed with a triple-quadrupole mass spectrometer on the different modified lysine-containing species to gain further insights into the characteristic fragmentation pattern. These fragmentations, in good agreement with true MS(3) measurements obtained using an ion trap mass spectrometer, highlighted characteristic monoalkylated lysine (immonium-NH(3)) and protonated modified caprolactam ions at m/z 168 and 213, respectively. In contrast, no fragment ion derived from a modified lysine residue (immonium or caprolactam) was observed when dialkylation occurs on Lys(29). However, a fragment ion corresponding to a protonated dihexylamine was observed at m/z 186. This loss, characteristic of dialkylated lysine fragmentation, was also observed upon dialkylation of N(alpha)-acetyllysine with either hexanal or pentanal. On the other hand, acetylation and malondialdehyde-modification of the N(alpha)-acetyllysine side chain led mainly to the corresponding modified (immonium-NH(3)) fragment ions at m/z 126 and 138, respectively. Finally, it was demonstrated that precursor ion scanning for both m/z 168 and 213 ions led to specific and sensitive identification of peptides containing hexanal-modified lysine residues within an unfractionated tryptic digest of hexanal-modified apomyoglobin. Thus, Lys(42), Lys(45), Lys(62), Lys(63), Lys(77), Lys(87), Lys(96), Lys(98), Lys(145) and Lys(147) were found to be modified upon reaction with hexanal.     

Amino acid identification and sequence analysis of peptides by reaction mass spectrometry

Fast atom bombardment mass spectrometry (FAB-MS) is applied to distinguish N-terminal series ions from C-terminal series ions of a peptide by on-probe acetylation, it providesvaluable information about the sequence of an unknown peptide. The FAB mass spectra containa number of characteristic ions at low-mass region in addition to the sequence ions at high-massregion. It was found that the ions below m/z 200 are characteristic of the amino acid composition ofthe peptide, from which the amino acid composition of the peptide could be estimated. Additionally,mixture analysis is also discussed.     

Simultaneous quantitative analysis of isobars by tandem mass spectrometry from unresolved chromatographic peaks

A method was developed for the simultaneous quantitation of isobars from unresolved chromatographic peaks. The method is based on differences in branching ratios of ion abundances in their tandem mass spectra and an assumption that the product ion mass spectra of a mixture can be considered as a linear combination of the spectra of individual constituents. We present analytical equations and a matrix-based approach for deconvoluting the concentration of individual components from the total peak intensity for two and three isobars and also a matrix-based generalization to any number of compounds. The feasibility of the simultaneous analysis of mixtures containing two compounds was assessed. The approach was evaluated for the analysis of structural isomers of methylmalonic and succinic acids in human plasma and urine samples for a group of 270 samples. The linear regression equation, standard error and correlation coefficient for the agreement with a traditional method utilizing chromatographic separation of the isomers were y = 0.999x - 0.005, 0.024 micro mol l(-1), and 0.985, respectively. The utility of a spectral contrast angle as a predictor of analysis feasibility was evaluated.     

Electrospray mass and tandem mass spectrometry identification of ozone oxidation products of amino acids and small peptides

Aqueous ozonation of the 22 most common amino acids and some small peptides were studied by electrospray mass (ESI-MS) and tandem mass spectrometry. After 5 min of ozonation only His, Met, Trp, and Tyr form oxidation products clearly detectable by ESI-MS. For His, the main oxidation product is formed by the addition of three oxygen atoms, His + 30; for Met and Tyr by the addition of one oxygen atom, Met + O and Tyr + O, and for Trp by the addition of two oxygen atoms, Trp + 20. Ozone oxidation occurs rapidly, products are already detected after 30 s of ozonation, and the reactivity order is Met > Trp > Tyr > His. The structures of the oxygen addition products were investigated by electrospray product ion mass spectra, and by comparing these spectra to those of protonated intact amino acids, and when available, to those of model compounds. His + 30 was assigned as 2-amino-4-oxo-4-(3-formylureido)butanoic acid (1) formed by oxidation of the His imidazole ring, Met + O as methionine sulfoxide (2), Trp + 20 as N-formylkynurenine (4), and Tyr + O as a mixture of dihydroxyphenylalanines (7 and 8). Ozonation of peptides show that the same number of oxygen atoms are added as expected from the ozonation of the free amino acids. The product ion mass spectra of both the protonated intact peptides, MH+, and the main ozonation products (M + nO)H+ (n = 1-3) revealed b and y type ions as the main fragments, which allow one to assign the type and location of modified amino acid in the model peptides.     

Solid-phase derivatization of tryptic peptides for rapid protein identification by matrix-assisted laser desorption/ionization mass spectrometry

Solid-phase sulfonation of tryptic peptides adsorbed to C18 muZipTips has been carried out to facilitate de novo sequencing with mass spectrometry. Peptides are reacted with the sulfonation reagent while they are still adsorbed to the solid phase. Excess reagent passes through the ZipTip to waste. Washing the products before subsequent elution from the mini-column also affords sample cleanup prior to analysis. Near quantitative N-terminal sulfonation can be achieved reliably at room temperature in only a few seconds. The method has been applied successfully to model peptides and to solution or in-gel digests of proteins. Current sequencing limits are about 100 fmol of protein. Multiplexed sample sulfonation reactions have been carried out with a manual 8-position micropipettor or using centrifugal force to reliably pass reagents and wash solutions over sample-loaded ZipTips. With multiplexing, overall preparation times have been reduced to about 1 min per sample. The solid-phase format facilitates efficient use of precious digest samples by enabling them to be recovered from the matrix-assisted laser desorption/ionization (MALDI) sample stage after mass fingerprinting, derivatized and re-analyzed by MALDI postsource decay mass spectrometry.     

Differentiation of estriol glucuronide isomers by chemical derivatization and electrospray tandem mass spectrometry

This paper describes a way of differentiating between the three isomers of estriol glucuronide by the use of chemical derivatization and liquid chromatography/electrospray tandem mass spectrometry (MS/MS). In their native form, these isomers gave rise to almost identical product ion spectra, involving the neutral loss of 176 Da (i.e. monodehydrated glucuronic acid), which made it impossible to determine the position of conjugation by MS/MS alone. In order to change the fragmentation pathways, positive charges were introduced into the analytes by chemical derivatization. The following reagents were tested: 2-chloro-1-methylpyridinium iodide, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide and 2-picolylamine. Interestingly, derivatization using a combination of all three reagents gave a selective fragmentation pattern that could differentiate between the isomers estriol-16-glucuronide and estriol-17-glucuronide. Estriol-3-glucuronide, which lacks a free phenolic group, could be differentiated through a different type of reaction product when exposed to 2-chloro-1-methylpyridinium iodide. Furthermore, in order to assist structural assignment of the fragments, their accurate masses were determined using a hybrid quadrupole time-of-flight mass spectrometer and fragmentation pathways were elucidated by the use of MS3 on an ion trap mass spectrometer.     

Characterization of metal-labelled peptides by matrix-assisted laser desorption/ionization mass spectrometry and tandem mass spectrometry

Metal labelling of peptides and proteins using high-affinity metal-chelating compounds has found widespread applications in the medical and bioanalytical fields. In the present study we investigated the analysis of peptides derivatized either with cysteine- or amino group-directed metal-bound DOTA (1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid) chelators in matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS). The metal complexes of DOTA were shown to be stable under MALDI-MS conditions. The introduction of the metal label led in a number of cases to significantly increased signal-to-noise (S/N) values and thus improved sensitivity of the labelled peptides compared to their unlabelled counterparts, especially for multiply labelled peptides. The presence of the labels did alter the tandem mass spectrometric (MS/MS) behaviour, namely the formation of sequence specific a-, b- and y-ion series, in dependence of the position of the label within the peptide sequence. For cysteine-derivatized peptides several label-specific reporter ions and characteristic immonium ions could be identified. Amino-directed labelling led only to the formation of characteristic immonium ions in ε-amino groups of lysine, whereas N-terminal labelling in some cases led to the formation of a(1)- and b(1)-ions. The results clearly show that MALDI-MS is suitable for the analysis of metal-labelled peptides, which was also confirmed in liquid chromatography (LC)/MALDI-based identification of proteins in a model protein mixture labelled with Cys-reactive DOTA. Here, in comparison to a run with alkylated cysteines, more than 50% more cysteine-containing peptides were identified.     

Precolumn derivatization of cysteine residues for quantitative analysis of five major cytochrome P450 isoenzymes by liquid chromatography/tandem mass spectrometry

The development of a novel method for absolute quantification of the five most clinically relevant CYP450 isoenzymes is described based on chemical derivatization of cysteine residues. The sulfhydryl-reactive reagents, 2-bromo-4'-chloroacetophenone (p-CPB) and 2-bromo-4'-bromoacetophenone (p-BPB), are proposed for use in quantitative proteomics. After reducing and denaturing, the P450s are derivatized with p-CPB for sulfhydryl alkylation then subjected to trypsin digestion. The resulting p-CPB-attached peptides are enriched using a phenyl resin solid-phase cartridge, then separated on a Zorbax 300SB reversed-phase column, and detected under positive electrospray ionization in the multiple reaction monitoring mode. Quantification is achieved using p-BPB-modified peptides as internal standards. Validation results demonstrated that this method showed good linearity between the concentration range of 10 fmol/microg to 5 pmol/microg for the six selected peptides in a complex matrix (rat liver microsomal protein). Intra-day and inter-day precision, expressed by relative standard deviation, were all less than 18%. Assay accuracy was within +/- 20% in terms of relative error. The quantitative derivatization approach proved to be reproducible, cost-effective and readily suitable for high-throughput assays. The reliability of this method for quantification of intact P450s was demonstrated through comparing with the well-applied isotope-coded affinity tag (ICAT) method.     

Selective enrichment and identification of azide-tagged cross-linked peptides using chemical ligation and mass spectrometry

Protein-protein interaction is one of the key regulatory mechanisms for controlling protein function in various cellular processes. Chemical cross-linking coupled with mass spectrometry has proven to be a powerful method not only for mapping protein-protein interactions of all natures, including weak and transient ones, but also for determining their interaction interfaces. One critical challenge remaining in this approach is how to effectively isolate and identify cross-linked products from a complex peptide mixture. In this work, we have developed a novel strategy using conjugation chemistry for selective enrichment of cross-linked products. An azide-tagged cross-linker along with two biotinylated conjugation reagents were designed and synthesized. Cross-linking of model peptides and cytochrome c as well as enrichment of the resulting cross-linked peptides has been assessed. Selective conjugation of azide-tagged cross-linked peptides has been demonstrated using two strategies: copper catalyzed cycloaddition and Staudinger ligation. While both methods are effective, Staudinger ligation is better suited for enriching the cross-linked peptides since there are fewer issues with sample handling. LC MSⁿ analysis coupled with database searching using the Protein Prospector software package allowed identification of 58 cytochrome c cross-linked peptides after enrichment and affinity purification. The new enrichment strategy developed in this work provides useful tools for facilitating identification of cross-linked peptides in a peptide mixture by MS, thus presenting a step forward in future studies of protein-protein interactions of protein complexes by cross-linking and mass spectrometry.     

Analysis of organotin compounds by grignard derivatization and gas chromatography-ion trap tandem mass spectrometry

The determination of organotin compounds in water using gas chromatography-tandem mass spectrometry (GC-MS-MS) is described. Several organotin derivatives were synthesized by the reaction of organotin chlorides with Grignard reagents such as methyl-, propyl- and pentylmagnesium halides. After the optimization of the GC-MS-MS conditions, several derivatizations with the Grignard reagents were compared by evaluating the molar responses and volatilities of the derivatives and derivatization yields. As a result, the derivatizing reagent of choice is pentylmagnesium bromide. Calibration curves for the mono-, di- and tributyltins and mono-, di- and triphenyltins with pentylmagnesium bromide were linear in the range of 0.5-100 pg of Sn. The instrumental detection limits of six organotins ranged from 0.20 to 0.35 pg of Sn. The recovery tests from water samples (500 ml) were performed by using sodium diethyldithiocarbamate (DDTC) as a complexing reagent. Except for monophenyltin, the absolute recoveries of organotins from pure water at 200 ng of Sn/l were satisfactory. The recoveries calibrated by surrogate compounds (perdeuterated organotin chlorides) ranged from 71 to 109%. The method detection limits ranged from 0.26 to 0.84 pg of Sn (500-ml sample). This method was applied to the recovery of organotins from river water and seawater. The calibrated recoveries were between 90 and 122%.     

Linkage position and residue identification of disaccharides by tandem mass spectrometry and linear discriminant analysis

The discrimination of isomeric disaccharides with different linkage types and different monosaccharide residues--glucose (Glc), galactose (Gal), and mannose (Man) at the non-reducing end--was investigated with tandem mass spectrometry (MS/MS) and linear discriminant analysis (LDA). Conventional matrix-assisted laser desorption/ionization (MALDI)-MS has strong interference peaks from matrix ions in the low mass region (<500 Da). This greatly limits the application of MALDI-MS for the analysis of small molecules such as saccharides. We solved this problem by using LDI with acidic fullerene matrix, which gives a very clean background in the low-mass region. Disaccharides with different linkage types give different tandem mass spectral profiles from various cross-ring fragmentation pathways. Disaccharides with the same linkage type but with three different kinds of monosaccharide residues bear the same fragmentation profiles. However, the relative ratios of the fragment ion intensities were found to be distinctly different among the three disaccharide isomers. By employing statistical tools such as LDA to classify the tandem mass spectra, disaccharide isomers with either different linkages or different monosaccharide residues were successfully classified.     

Rapid screening and identification of cytochalasins by electrospray tandem mass spectrometry

The cytochalasin class of fungal metabolites was analyzed by electrospray ionization tandem mass spectrometry (ESI-MS/MS) with the aim of developing a methodology for their rapid identification in microbial extracts. ESI-MS analyses of reference cytochalasins were performed and several product ions were produced in MS/MS experiments on parent ions that are structurally characteristic. A precursor ion search was performed to detect cytochalasins in an ethyl acetate extract of fungal strain RK97-F21. Three cytochalasins were detected and one of the components was identified as epoxycytochalasin H by comparing the tandem mass spectra of the product ions with those of reference compounds. This finding was further validated by LC/MS and LC/MS/MS experiments.     

Detection and identification of carcinogen-peptide adducts by nanoelectrospray tandem mass spectrometry

Nanoelectrospray (nanoES) tandem mass spectrometry was used to examine covalently modified peptides in crude enzymatic digests of human serum albumin (HSA) that had been exposed to either benzo[a]pyrene diol epoxide (B[a]PDE, 1), chrysene diol epoxide (CDE, 2), 5-methylchrysene diol epoxide (5MeCDE, 3), or benzo[g]chrysene diol epoxide (B[g]CDE, 4). The low flow rates of nanoES (～20 nL/min) allowed several MS/MS experiments to be optimized and performed on a single sample with very little sample consumption (～30 min analysis time/µL sample). Initially, nanoES was compared with conventional LC/MS/MS analysis of carcinogen-peptide adducts. For example, nanoES analysis of an unseparated digest of B[a]PDE-treated serum albumin revealed the same peptides (RRHPY and RRHPY-FYAPE) that were previously shown, by LC/MS/MS, to be adducted with B[a]PDE. In addition, nanoES could detect unstable peptide adducts that might not otherwise have been directly observable. Finally, nanoES was shown to be an effective way to screen mixtures of modified and unmodified peptides for which no chromatographic information is available.