Mass spectrometry-based sequencing of protein C-terminal peptide using α-carboxyl group-specific derivatization and COOH capturing

An approach to mass spectrometry (MS)-based sequence analysis of selectively enriched C-terminal peptide from protein is described. This approach employs a combination of the specific derivatization of α-carboxyl group (α-COOH), enzymatic proteolysis using endoproteinase GluC, and enrichment of C-terminal peptide through the use of COOH-capturing material. Highly selective derivatization of α-COOH was achieved by a combination of specific activation of α-COOH through oxazolone chemistry and amidation using 3-aminopropyltris-(2,4,6-trimethoxyphenyl)phosphonium bromide (TMPP-propylamine). This amine component was used to simplify fragmentation in tandem mass spectrometry (MS/MS) measurement, which facilitated manual sequence interpretation. The peptides produced after GluC digestion were then treated with a COOH scavenger to enrich the C-terminal peptide that is only devoid of COOH groups, and the obtained C-terminal peptide was readily sequenced by matrix-assisted laser desorption/ionization (MALDI)-MS/MS due to the TMPP mass tag.     

Multi-residue analysis of eight anticoagulant rodenticides in animal plasma and liver using liquid chromatography combined with heated electrospray ionization tandem mass spectrometry

The determination of C-terminal peptide sequence is critical since the C-terminal peptide contains biologically relevant information and often undergoes post-translational processing. Another important application is in estimating purity of the biopharmaceuticals, especially for determining the presence of ragged processed ends and for N-terminally blocked polypeptides and proteins. In this paper, different isotope coding strategies in combination with reversed phase chromatography (RPC) coupled with electrospray ionization-mass spectrometry (ESI-MS) were evaluated to detect the C-terminal peptide from proteolytic digests. These were (i) O18 (ii) acylation and (iii) esterification based isotope coding strategies. Using reversed phase chromatography, the C-terminal peptide was resolved from other internal peptides. The isotope coding approaches specifically rendered a characteristic MS signature to the C-terminal peptide, thereby facilitating its detection. The unique MS signature, along with accurate mass data for the C-terminal peptide was found to be sufficient for its detection and identification. The advantages and limitations of the three approaches will be discussed.     

p-dimethylaminocinnamaldehyde derivatization for colorimetric detection and HPLC-UV/vis-MS/MS identification of indoles

Cytochrome P450 2A13 (CYP2A13) is a lung specific enzyme known to activate the potent tobacco procarcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) into two carcinogenic metabolites. CYP2A13 has been crystallized and X-ray diffraction experiments illuminated the structure of this enzyme, but with an unknown ligand present in the enzyme active site. This unknown ligand was suspected to be indole but a selective method had to be developed to differentiate among indole and its metabolites in the protein sample. We successfully modified a microbiological colorimetric assay to spectrophotometrically differentiate between indole and a number of possible indole metabolites in nanomolar concentrations by derivatization with p-dimethylaminocinnamaldehyde (DMACA). Further differentiation of indoles was made by mass spectrometry (HPLC-UV/vis-MS/MS) utilizing the chromophore generated in the DMACA conjugation as a UV signature for HPLC detection. The ligand in the crystallized protein was identified as unsubstituted indole, which facilitated refinement of two alternate conformations in the CYP2A13 crystal structure active site.     

C-terminal sequence analysis of peptides using triphenylgermanyl isothiocyanate

The Schlack-Kumpf degradation, also called the isothiocyanate method, is thought to be a promising approach to chemical C-terminal sequencing of peptides and proteins. The derivatizing reagent is most crucial to this method. A new derivatizing reagent, triphenylgermanyl isothiocyanate (TPG-ITC), has been synthesized and applied to C-terminal peptide sequencing. The chemistry involves activation with acetic anhydride, derivatization with TPG-ITC, and cleavage of the derivatized C-terminal amino acid thiohydantoin with sodium hydroxide. A series of reaction conditions, including activation reagent volume, activation time, and derivatization temperature and time, have been investigated using a model peptide covalently attached to 1,4-phenylene diisothiocyanate (DITC)-glass beads. This procedure has been successfully used to sequence eight C-terminal residues of a model peptide at low nanomole levels. TPG-ITC is a white solid with relatively long shelf-life. According to our previous article (B. Mo, J. Li, and S. P. Liang, 1997, Anal. Biochem. 252, 169-176), TPG-ITC is a type II derivatizing reagent. Compared with acetyl isothiocyanate and trimethylsilyl isothiocyanate, TPG-ITC is much more stable and efficient for use in peptide C-terminal sequencing.     

Chemical carboxyl-terminal sequence analysis of peptides and proteins using tribenzylsilyl isothiocyanate

A new derivatization reagent, tribenzylsilyl isothiocyanate (TBS-ITC), is applied to C-terminal peptide and protein sequencing. It has been successfully used to sequence six C-terminal residues of house apomyoglobin and a synthetic peptide at low nanomole levels. The chemistry involves activation with acetic anhydride, derivatization with TBS-ITC, and cleavage of derivatized C-terminal amino acid thiohydantoin with sodium hydroxide. The tribenzylsilyl is a bulky, electric donor group and is a good leaving group. It facilitates the nucleophilic attack of the NCS^–1 in the coupling reaction. The efficiency for C-terminal sequencing by TBS-ITC is about the same as that of acetyl isothiocyanate (AITC), which is a derivatizing reagent for C-terminal sequencing developed by our laboratory. TBS-ITC is much more stable than AITC and trimethylsilyl isothiocyanate (TMS-ITC). TBS-ITC is a solid with relatively long shelf life, whereas AITC and TMS-ITC are liquid and not stable at room temperature.     

C-Terminal Protein Characterization by Mass Spectrometry: Isolation of C-Terminal Fragments from Cyanogen Bromide-Cleaved Protein

A sample preparation method for protein C-terminal peptide isolation from cyanogen bromide (CNBr) digests has been developed. In this strategy, the analyte was reduced and carboxyamidomethylated, followed by CNBr cleavage in a one-pot reaction scheme. The digest was then adsorbed on ZipTip_C18 pipette tips for conjugation of the homoserine lactone-terminated peptides with 2,2′-dithiobis (ethylamine) dihydrochloride, followed by reductive release of 2-aminoethanethiol from the derivatives. The thiol-functionalized internal and N-terminal peptides were scavenged on activated thiol sepharose, leaving the C-terminal peptide in the flow-through fraction. The use of reversed-phase supports as a venue for peptide derivatization enabled facile optimization of the individual reaction steps for throughput and completeness of reaction. Reagents were replaced directly on the support, allowing the reactions to proceed at minimal sample loss. By this sequence of solid-phase reactions, the C-terminal peptide could be recognized uniquely in mass spectra of unfractionated digests by its unaltered mass signature. The use of the sample preparation method was demonstrated with low-level amounts of a whole, intact model protein. The C-terminal fragments were retrieved selectively and efficiently from the affinity support. The use of covalent chromatography for C-terminal peptide purification enabled recovery of the depleted material for further chemical and/or enzymatic manipulation. The sample preparation method provides for robustness and simplicity of operation and is anticipated to be expanded to gel-separated proteins and in a scaled-up format to high-throughput protein profiling in complex biological mixtures.     

Comprehensive phosphoprotein analysis of linker histone H1 from Tetrahymena thermophila

Linker histone H1 is highly phosphorylated in normal growing Tetrahymena thermophila but becomes noticeably dephosphorylated in response to certain conditions such as prolonged starvation. Because phosphorylation of H1 has been associated with the regulation of gene expression, DNA repair, and other critical processes, we sought to use mass spectrometry-based approaches to obtain an in depth phosphorylation "signature" for this linker histone. Histone H1 from both growing and starved Tetrahymena was analyzed by nanoflow reversed-phase HPLC MS/MS following enzymatic digestions, propionic anhydride derivatization, and phosphopeptide enrichment via IMAC. We confirmed five phosphorylation sites identified previously and detected two novel sites of phosphorylation and two novel minor sites of acetylation. The sequential order of phosphorylation on H1 was deduced by using mass spectrometry to define the modified sites on phosphorylated H1 isoforms separated by cation-exchange chromatography. Relative levels of site-specific phosphorylation on H1 isolated from growing and starved Tetrahymena were obtained using a combination of stable isotopic labeling, IMAC, and tandem mass spectrometry.     

Labelling saccharides with phenylhydrazine for electrospray and matrix-assisted laser desorption-ionization mass spectrometry

A well-known reaction of carbonyl compounds with phenylhydrazine has been applied to saccharides, providing increased sensitivity for mass spectrometric (MS) and ultraviolet (UV) detection during high-performance liquid chromatographic (HPLC) separations. After a simple derivatization procedure for 1 h at 70 degrees C and purification of the reaction mixture from excess reagent by extraction, the sugar derivatives were characterized by direct injection or on-line HPLC/electrospray ionization (ESI) and by matrix-assisted laser desorption/ionization (MALDI) MS. Because no salts are used or produced upon reaction, this procedure is very simple and suitable for the tagging of saccharides. The reaction allows for on-target derivatization and products are very stable. The derivatization procedure has been applied to commercially-obtained small saccharides and standard N-linked oligosaccharides. Lastly, hen ovalbumin N-glycans were detached enzymatically and characterized by MALDI-MS as their phenylhydrazone derivatives.     

LC-MS/MS quantitation of plasma progesterone in cattle

Quantitation of progesterone (P₄) in biological fluids is often performed by radioimmunoassay (RIA), whereas liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS) has been used much less often. Due to its autoconfirmatory nature, LC-MS/MS greatly minimizes false positives and interference. Herein we report and compare with RIA an optimized LC-MS/MS method for rapid, efficient, and cost-effective quantitation of P₄ in plasma of cattle with no sample derivatization. The quantitation of plasma P₄ released from three nonbiodegradable, commercial, intravaginal P₄-releasing devices (IPRD) over 192 h in six ovariectomized cows was compared in a pairwise study as a test case. Both techniques showed similar P₄ kinetics (P > 0.05) whereas results of P₄ quantitation by RIA were consistently higher compared with LC-MS/MS (P < 0.05) due to interference and matrix effects. The LC-MS/MS method was validated according to the recommended analytical standards and displayed P₄ limits of detection (LOD) and quantitation (LOQ) of 0.08 and a 0.25 ng/mL, respectively. The high selective LC-MS/MS method proposed herein for P₄ quantitation eliminates the risks associated with radioactive handling; it also requires no sample derivatization, which is a common requirement for LC-MS/MS quantitation of steroid hormones. Its application to multisteroid assays is also viable, and it is envisaged that it may provide a gold standard technique for hormone quantitation in animal reproductive science studies.     

Drawbacks in the use of unconventional hydrophobic anhydrides for histone derivatization in bottom‐up proteomics PTM analysis

MS‐based proteomics has become the most utilized tool to characterize histone PTMs. Since histones are highly enriched in lysine and arginine residues, lysine derivatization has been developed to prevent the generation of short peptides (<6 residues) during trypsin digestion. One of the most adopted protocols applies propionic anhydride for derivatization. However, the propionyl group is not sufficiently hydrophobic to fully retain the shortest histone peptides in RP LC, and such procedure also hampers the discovery of natural propionylation events. In this work we tested 12 commercially available anhydrides, selected based on their safety and hydrophobicity. Performance was evaluated in terms of yield of the reaction, MS/MS fragmentation efficiency, and drift in retention time using the following samples: (i) a synthetic unmodified histone H3 tail, (ii) synthetic modified histone peptides, and (iii) a histone extract from cell lysate. Results highlighted that seven of the selected anhydrides increased peptide retention time as compared to propionic, and several anhydrides such as benzoic and valeric led to high MS/MS spectra quality. However, propionic anhydride derivatization still resulted, in our opinion, as the best protocol to achieve high MS sensitivity and even ionization efficiency among the analyzed peptides.     

Isolation and characterization of the insecticidal,two-domain toxin LaIT3 from the Liocheles australasiae scorpion venom

ABSTRACT

A novel insecticidal peptide (LaIT3) was isolated from the Liocheles australasiae venom. The primary structure of LaIT3 was determined by a combination of Edman degradation and MS/MS de novo sequencing analysis. Discrimination between Leu and Ile in MS/MS analysis was achieved based on the difference in side chain fragmentation assisted by chemical derivatization. LaIT3 was determined to be an 84-residue peptide with three intrachain disulfide bonds. The sequence similarity search revealed that LaIT3 belongs to the scorpine-like peptides consisting of two structural domains: an N-terminal α-helical domain and a C-terminal cystine-stabilized domain. As observed for most of the scorpine-like peptides, LaIT3 showed significant antibacterial activity against Escherichia coli, which is likely to be caused by its membrane-disrupting property.     

Improved collision-induced dissociation analysis of peptides by matrix-assisted laser desorption/ionization tandem time-of-flight mass spectrometry through 3-sulfobenzoic acid succinimidyl ester labeling

The sulfonation reagent, a succinimidyl ester of 3-sulfobenzoic acid, has been synthesized for effective peptide sequencing. It is capable of incorporating an additional mobile proton into the peptide backbone, thus, facilitating efficient collision-induced dissociation. This reagent is easily and inexpensively prepared in short time. Tandem mass spectra of the guanidinated and reagent-sulfonated peptides consist mainly of the y-ion series with higher intensities than those observed for solely guanidinated peptides. These enhanced tandem MS attributes significantly improved MASCOT total-ion scores, thus, allowing more confident peptide sequencing. This derivatization was also very effective for the analysis of tryptic digest of human blood serum proteins separated by two-dimensional gel electrophoresis. When used in LC-MALDI/MS/MS format, this type of derivatization does not adversely affect chromatographic efficiencies.     

Using chemical derivatization and mass spectrometric analysis to characterize the post-translationally modified Staphylococcus aureus surface protein G

The Staphylococcus aureus surface protein G (SasG) is an important mediator of biofilm formation in virulent S. aureus strains. A detailed analysis of its primary sequence has not been reported to date. SasG is highly abundant in the cell wall of the vancomycin-intermediate S. aureus strain HIP5827, and was purified and subjected to sequence analysis by MS. Data from MALDI-TOF and LC-MS/MS experiments confirmed the predicted N-terminal signal peptide cleavage site at residue A₅₁ and the C-terminal cell wall anchor site at residue T₁₀₈₆. The protein was also derivatized with N-succinimidyloxycarbonyl-methyl-tris(2,4,6-trimethoxyphenyl) phosphonium bromide (TMPP-Ac-OSu) to assess the presence of additional N-terminal sites of mature SasG. TMPP-derivatized SasG peptides featured m/z peaks with a 572 Da mass increase over the equivalent underivatized peptides. Multiple N-terminal peptides, all of which were observed in the 150 amino acid segment following the signal peptide cleavage at the residue A₅₁, were characterized from MS and MS/MS data, suggesting a series of successive N-terminal truncations of SasG. A strategy combining TMPP derivatization, multiple enzyme digestions to generate overlapping peptides and detailed MS analysis will be useful to determine and understand functional implications of PTMs in bacterial cell wall-anchored proteins, which are frequently involved in the modulation of virulence-associated bacterial surface properties.     

The Essential Role of Mass Spectrometry in Characterizing Protein Structure: Mapping Posttranslational Modifications

Over the last few years we have developed mass spectrometry-based approaches for selective identification of a variety of posttranslational modifications, and for sequencing the modified peptides. These methods do not involve radiolabeling or derivatization. Instead, modification-specific fragment ions are produced by collision-induced dissociation (CID) during analysis of peptides by ESMS. The formation and detection of these marker ions on-the-fly during the LC-ESMS analysis of a protein digest is a powerful technique for identifying posttranslationally modified peptides. Using the marker ion strategy in an orthogonal fashion, a precursor ion scan can detect peptides which give rise to a diagnostic fragment ion, even in an unfractionated protein digest. Once the modified peptide has been located, the appropriate precursor ion can be sequenced by tandem MS. The utility and interplay of this approach to mapping PTM is illustrated with examples that involve protein glycosylation and phosphorylation.     

An improved chemical approach toward the C-terminal sequence analysis of proteins containing all natural amino acids.

An improved chemical method, capable of derivatizing all natural amino acids to their corresponding thiohydantoins, is described. This involves activation by acetyl chloride in TFA followed by derivatization with ammonium thiocyanate. Possible interference of reactive side chains was investigated by reacting N-acetylamino acids as well as several peptides with propionyl chloride instead of acetyl chloride. The products were characterized by PDMS mass spectrometry and 1H-NMR. This chemical method allows, for the first time, complete derivatization of N-acetylproline to proline thiohydantoin. Applying this chemistry to peptides with a C-terminal proline, the yields for formation of proline thiohydantoin were found to be up to 60%, depending on the peptide sequence. The previous inability to derivatize C-terminal proline to thiohydantoin was thought to stem from the fact that proline cannot form the oxazolonium ion required for efficient reaction with the thiocyanate ion. However, we have found mass spectrometric evidence for the existence of a proline oxazolonium ion, under basic as well as under acidic conditions. This improvement in derivatization of C-terminal amino acids including proline is a major step forward in the development of a general chemical C-terminal sequencing method that permits the C-terminal sequence analysis of proteins of any amino acid composition.     

Sequencing of peptides and proteins from the carboxy terminus.

A new chemical method for carboxy-terminal (C-terminal) protein sequencing has been developed. This approach has been successfully used to sequence 5 residues of standard proteins and 5 to 10 residues of synthetic peptides at low nanomole levels. The sequencing procedure consists of converting the C-terminal amino acid into a thiohydantoin (TH) derivative, followed by transformation of the TH into a good leaving group by alkylation. Next, the alkylated TH is cleaved mildly and efficiently with (N = C V S)- anion, which simultaneously forms a TH on the newly truncated protein or peptide. Thus, after the initial TH derivatization, there is no return to a free carboxyl group at the C-terminus. An additional benefit of this method is that the alkylating moiety can be chosen with a variety of properties allowing for variation in the detection method. This chemistry has been adapted to automated protein sequencers with a cycle time of about 1 h.     

A multifunctional bioconjugate module for versatile photoaffinity labeling and click chemistry of RNA

A multifunctional reagent based on a coumarin scaffold was developed for derivatization of naive RNA. The alkylating agent N3BC [7-azido-4-(bromomethyl)coumarin], obtained by Pechmann condensation, is selective for uridine. N3BC and its RNA conjugates are pre-fluorophores which permits controlled modular and stepwise RNA derivatization. The success of RNA alkylation by N3BC can be monitored by photolysis of the azido moiety, which generates a coumarin fluorophore that can be excited with UV light of 320?nm. The azidocoumarin-modified RNA can be flexibly employed in structure-function studies. Versatile applications include direct use in photo-crosslinking studies to cognate proteins, as demonstrated with tRNA and RNA fragments from the MS2 phage and the HIV genome. Alternatively, the azide function can be used for further derivatization by click-chemistry. This allows e.g. the introduction of an additional fluorophore for excitation with visible light.     

Cartilage degradation by hyaluronate lyase and chondroitin ABC lyase: a MALDI-TOF mass spectrometric study

Matrix-assisted laser desorption ionization and time-of-flight mass spectrometry (MALDI-TOF MS) has been used to investigate degradation products of two selected polysaccharides of cartilage (chondroitin sulfate and hyaluronic acid). Testicular hyaluronate lyase and chondroitin ABC lyase were used for enzymic digestion of both polysaccharides as well as of cartilage specimens. Polysaccharide solutions and cartilage supernatants were assayed by positive and negative MALDI-TOF MS. Especially chondroitin ABC lyase produced high amounts of digestion products (unsaturated di- and tetrasaccharides) from polysaccharides as well as from cartilage, clearly monitored by MALDI-TOF MS. It is concluded that MALDI-TOF MS provides a precise and fast tool for the determination of oligosaccharides since no previous derivatization is required.     

A method for simple identification of signature peptides derived from polyUb-K48 and K63 by MALDI-TOF MS and chemically assisted MS/MS fragmentation

Summary. A simple method is described to identify signature peptides derived from polyubiquitin (polyUb) chains. The method is based on MALDI-TOF MS/MS analysis after chemically assisted fragmentation, and works on peptides isolated from polyacrylamide gels. PolyUb chains branched at K48 and K63 were chosen as models for Ub-protein conjugates. They were resolved by SDS-PAGE, and their tryptic peptides (in-gel-trypsinolysis) derivatized with 3-sulfopropinic acid NHSester to obtain chemically assisted fragmentation during the MS/MS analysis. PolyUb-K63 produced a single peptide identified as ⁵⁵TLSDYNIQK⁶³ (GG)ESTLHLVLR⁷². PolyUb-K48 produced two branched signature peptides identified as ⁴³LIFAGK⁴⁸(GG)QLEDGR⁵⁴ and ⁴³LIFAGK⁴⁸(LRGG)QLEDGR⁵⁴. The recovery of signature peptide with LRGG as branched chain underscores the need to take limited proteolysis into account in the search for detection of ubiquitinated peptides in proteomics studies. In conclusion, a simple method has been described allowing the identification of signature peptides, which are diagnostic markers of the majority of polyUb-conjugated proteins. In principle, the method should be applicable also for other more rare signature peptides.     

Microwave-assisted derivatization of 2,5-hexanedione in urine: evaluation using GC-MS and GC-ECD

2,5-Hexanedione, the main metabolite of n-hexane, can be responsible for axonal degeneration symptoms via formation of pyrrol-adducts with several amino acids. In order to make it amenable to gas chromatographic analysis, a protocol including microwave assisted derivatization is presented and compared to state-of-the-art technique of urine analysis. The applied methodology includes derivatization with O-(2,3,4,5,6-pentafluorobenzyl) hydroxylamine, extraction of the oximes and final analysis using either GC-MS or GC-muECD. Furthermore, the mass spectra of derivatized 2,5-hexanedione and 5-hydroxy-2-hexanone as well as preliminary excretion kinetics are provided. Orthogonal regression methodology demonstrated superior sensitivity for the microwave heating. Limits of detection were calculated to be approximately 20 ng mL(-1) with both MS and electron capture detection, the decompositon of excess derivatizing agent using sulfuric acid, following the reaction is beneficial. A matrix effect caused by urine was not observed, a calibration in aqueous matrix ensures accurate results therefore. Microwave heating yields excellent results regarding recovery, sensitivity and the time needed for sample preparation, furthermore, it is demonstrated that both mass selective as well as electron capture detection are of comparable suitability for this task.