Spectrophotometric detection of histidine and lysine using combined enzymatic reactions

An amino acid-sensing system with absorption spectrophotometric detection was developed. To ensure specific recognition of each amino acid, aminoacyl-tRNA synthetases were employed and the concentration of NADH produced by way of several enzymatic reactions was measured. Using this detection system, from 1.5 to 55 μM of histidine and from 15 to 95 μM of lysine could be measured selectively in HEPES-KOH buffer (pH 8.0).     

Two-fold efficiency increase by selective excitation of ions for consecutive activation by ion-electron reactions and vibrational excitation in tandem fourier transform ion cyclotron resonance mass spectrometry

A new technique called selective excitation of ions for consecutive activation (SEICA) is proposed for obtaining complementary fragmentation mass spectra from the same precursor ion population. SEICA utilizes precursor ions remaining intact after electron capture dissociation or another ion-electron reaction for efficient MS/MS based on a vibrational excitation (VE) technique, such as infrared multiphoton dissociation. SEICA uses the ability of ion-trapping instruments to detect product ions while retaining inside the trap intact precursor ions, making the latter available for consecutive activation by a VE technique. The possibility of practical implementation of SEICA by software-only modification of a commercial instrument is demonstrated. A 2-fold increase in the efficiency is achieved for both "single-scan" and "multiple-scan" experiments. This improvement can be particularly important for high-sensitivity applications in, for example, proteomics, where limited ECD efficiency poses an obstacle for broad implementation of this technique.     

DSA measurement using heavy ion reactions on the small tandem accelerator

The lifetimes of the 7.12 MeV level in ¹⁶O and the 4.44 MeV level in ¹²C have been measured using the Doppler shift attenuation method at a small accelerator. The reversed nuclear reactions ¹H(¹⁹F, α) ¹⁶O¹ and ¹H(¹¹B, γ) ¹²C¹ were used.     

Novel mass spectrometric method for phosphorylation quantification using cerium oxide nanoparticles and tandem mass tags

The stoichiometry of protein phosphorylation significantly impacts protein function. The development of quantitative techniques in mass spectrometry has generated the ability to systematically monitor the regulation levels of various proteins. This study reports an integrated methodology using cerium oxide nanoparticles and isobaric tandem mass tag (TMT) labeling to assess absolute stoichiometries of protein phosphorylation. This protocol was designed to directly measure the dephosphorylation levels for a known phosphorylation site, therefore allowing for quantification of phosphosites. Both the accuracy and precision of the method were verified using standard peptides and protein tryptic digests. This novel method was then applied to quantify phosphorylations on eukaryotic initiation factor 3H (eIF3H), a protein integral to overall eukaryotic protein translation initiation. To date, this is the first report of assessment of protein phosphorylation quantification on eIF3.     

Analysis of CheA histidine phosphorylation and its influence on protein stability by high-resolution element and electrospray mass spectrometry

A combination of electrospray mass spectrometry (ESI-MS) and element mass spectrometry (ICPMS) with phosphorus detection was used to characterize histidine phosphorylation (His-48) of the chemotaxis protein CheA quantitatively. The phosphorylation at His-48 was found to be responsible for a stabilization of the protein. For this investigation, the acceptor domain and the kinase domain of the bacterial chemotaxis protein CheA were recombinantly expressed as single proteins. Using in vitro kinase assay conditions, the acceptor domain CheA-H was phosphorylated by the kinase domain CheA-C. The degree of histidine phosphorylation was determined by nanoelectrospray mass spectrometry of intact CheA-H, and was found to be limited to a maximum value of approximately 50%. The site specificity of CheA-H phosphorylation was controlled by nanoESI-MS/MS of the [M + 16H](16+) ion of intact (pHis)-CheA-H and allowed localization of the pHis residue to the region between residues 32 and 86, containing candidates His-48 and His-67, for which His-48 phosphorylation has been described. Analysis of the tryptic digest of in vitro histidine-phosphorylated CheA-H by capillary chromatography coupled to ESI-MS and to ICPMS with phosphorus detection revealed a truncated (pHis)-CheA-H protein as the only phosphorus-containing analyte. Since the truncated (pHis)-CheA-H in the digest was found to exhibit a higher degree of phosphorylation than could be generated by in vitro phosphorylation without trypsin treatment, it is concluded that histidine phosphorylation at His-48 strongly interferes with structural properties of the CheA-H domain in particular with respect to proteolytic degradation by trypsin.     

Analysis of protein phosphorylation by a combination of elastase digestion and neutral loss tandem mass spectrometry

Loss of phosphoric acid is the most effective fragmentation reaction of pSer- and pThr-containing phosphopeptides of small size (up to 10-15 residues) in low-energy collision-induced dissociation. Therefore, tandem mass spectrometry with neutral loss scanning was evaluated for its utility to analyze protein phosphorylation using protein kinase A (PKA) catalytic subunit, which is phosphorylated at Thr197 and Ser338, as an example. Analysis of tryptic digests of phosphoproteins by tandem mass spectrometry with scanning for neutral loss of phosphoric acid resulted in spectra with poor signal-to-noise ratio, mainly because of the large size of the phosphopeptides formed (>2 kDa). This unfavorable size was caused by the distribution of tryptic cleavage sites in PKA and by interference of phosphorylation with tryptic cleavage. To generate a set of smaller peptide fragments, digestion was performed using the low-specificity protease elastase. Analysis of the total elastase digest with neutral loss scanning resulted in observation of a set of partially overlapping phosphopeptides with high abundance, providing a complete coverage of PKA phosphorylation sites. The peptide size generated by elastase (0.5-1.5 kDa) is ideally suited for this scan mode, which was found to provide the highest specificity for detection of singly charged phosphopeptides (neutral loss of 98). Identification of the PKA phosphorylation sites was performed by mass spectrometric sequencing of the elastase-derived phosphopeptides, which provided highly informative product ion spectra.     

Analysis of amino acid isotopomers using FT-ICR MS

Fluxes through known metabolic pathways and the presence of novel metabolic reactions are often determined by feeding isotopically labeled substrate to an organism and then determining the isotopomer distribution in amino acids in proteins. However, commonly used techniques to measure the isotopomer distributions require derivatization prior to analysis (gas chromatography/mass spectrometry (GC/MS)) or large sample sizes (nuclear magnetic resonance (NMR) spectroscopy). Here, we demonstrate the use of Fourier transform-ion cyclotron resonance mass spectrometry with direct infusion via electrospray ionization to rapidly measure the amino acid isotopomer distribution in a biomass hydrolysate of the soil bacterium Desulfovibrio vulgaris Hildenborough. By applying high front-end resolution for the precursor ion selection followed by sustained off-resonance irradiation collision-induced dissociation, it was possible to determine exactly and unambiguously the specific locations of the labeled atoms in the amino acids, which usually requires a combination of 2-D 13C NMR spectroscopy and GC/MS. This method should be generally applicable to all biomass samples and will allow more accurate determination of metabolic fluxes with less work and less sample.     

Analysis of epipolythiodioxopiperazines in fungus Chaetomium cochliodes using HPLC-ESI-MS/MS/MS

A series of epipolythiodioxopiperazines in the fungus Chaetomium cochliodes was investigated using reversed-phase liquid chromatography with diode array detection and electrospray quadrupole time-of-flight-type tandem mass spectrometry in the positive ion mode. The fragmentation of protonated molecular ions including low-abundance parent ions, [M+H]+ for five known epipolythiodioxopiperazines, dethiotetra(methylthio)chetomin, chaetocochins A-C, and chetomin, was carried out using low-energy collision-induced electrospray ionization tandem spectrometry. It was found that McLafferty rearrangements occurred in the CID processes and produced a complementary pair of characteristic fragment ions containing piperazine rings (fused and unfused), especially to determine the number of S atoms on each ring. The fragmentation differential between [M+H]+ and [M+Na]+ was uncovered. Complementary fragmentation information obtained from [M+H]+ and [M+Na]+ precursor ions is especially valuable for rapid identification of epipolythiodioxopiperazines. A likely known compound, possibly related to chetoseminudin A, and three new species of epipolythiodioxopiperazines from the fungus C. cochliodes were identified or tentatively characterized based on tandem mass spectra of known ones.     

Probing ligand binding to duplex DNA using KMnO4 reactions and electrospray ionization tandem mass spectrometry

An electrospray ionization tandem mass spectrometry (ESI-MS/MS) strategy employing the thymine-selective KMnO4 oxidation reaction to detect conformational changes and ligand binding sites in noncovalent DNA/drug complexes is reported. ESI-MS/MS is used to detect specific mass shifts of the DNA ions that are associated with the oxidation of thymines. This KMnO4 oxidation/ESI-MS/MS approach is an alternative to conventional gel-based oxidation methods and affords excellent sensitivity while eliminating the reliance on radiolabeled DNA. Comparison of single-strand versus duplex DNA indicates that the duplexes exhibit a significant resistance to the reaction, thus confirming that the oxidation process is favored for unwound or single-strand regions of DNA. DNA complexes containing different drugs including echinomycin, actinomycin-D, ethidium bromide, Hoechst 33342, and cis-C1 were subjected to the oxidation reaction. Echinomycin, a ligand with a bisintercalative binding mode, was found to induce the greatest KMnO4 reactivity, while Hoechst 33342, a minor groove binder, caused no increase in the oxidation of DNA. The oxidation of echinomycin/DNA complexes containing duplexes with different sequences and lengths was also assessed. Duplexes with thymines closer to the terminal ends of the duplex demonstrated a greater increase in the degree of oxidation than those with thymines in the middle of the sequence. Collisional activated dissociation (CAD) and infrared multiphoton dissociation (IRMPD) experiments were used to determine the site of oxidation based on oligonucleotide fragmentation patterns.     

Analysis of protein tyrosine phosphorylation by nanoelectrospray ionization high-resolution tandem mass spectrometry and tyrosine-targeted product ion scanning

A novel highly sensitive strategy is introduced for analysis of tyrosine phosphorylation in previously identified proteins channelling for this aim all analytical and sequence information available. Nanoelectrospray high-resolution MS/MS analysis is targeted to precalculated m/z values corresponding to phosphotyrosine-containing tryptic peptides. Identification of these peptides is supported by the occurrence of the phosphotyrosine immonium ion at m/z 216, neutral loss of 79.97/z (= loss of HPO3), and similarity of the fragmentation patterns of phosphotyrosine-containing peptides with their nonphosphorylated analogues. This tyrosine-targeted tandem mass spectrometry strategy is demonstrated for epidermal growth factor receptor showing that phosphotyrosine-containing tryptic peptides invisible in the survey spectrum can be safely identified.     

Ultrasensitive proteomics using high-efficiency on-line micro-SPE-nanoLC-nanoESI MS and MS/MS

Ultrasensitive nanoscale proteomics approaches for characterizing proteins from complex proteomic samples of <50 ng of total mass are described. Protein identifications from 0.5 pg of whole proteome extracts were enabled by ultrahigh sensitivity (<75 zmol for individual proteins) achieved using high-efficiency (peak capacities of approximately 10(3)) 15-microm-i.d. capillary liquid chromatography separations (i.e., using nanoLC, approximately 20 nL/min mobile-phase flow rate at the optimal linear velocity of approximately 0.2 cm/s) coupled on-line with a micro-solid-phase sample extraction and a nanoscale electrospray ionization interface to a 11.4-T Fourier transform ion cyclotron resonance (FTICR) mass spectrometer (MS). Proteome measurement coverage improved as sample size was increased from as little as 0.5 pg of sample. It was found that a 2.5-ng sample provided 14% coverage of all annotated open reading frames for the microorganism Deinococcus radiodurans, consistent with previous results for a specific culture condition. The estimated detection dynamic range for detected proteins was 10(5)-10(6). An improved accurate mass and LC elution time two-dimensional data analysis methodology, used to both speed and increase the confidence of peptide/protein identifications, enabled identification of 872 proteins/run from a single 3-h nanoLC/FTICR MS analysis. The low-zeptomole-level sensitivity provides a basis for extending proteomics studies to smaller cell populations and potentially to a single mammalian cell. Application with ion trap MS/MS instrumentation allowed protein identification from 50 pg (total mass) of proteomic samples (i.e., approximately 100 times larger than FTICR MS), corresponding to a sensitivity of approximately 7 amol for individual proteins. Compared with single-stage FTICR measurements, ion trap MS/MS provided a much lower proteome measurement coverage and dynamic range for a given analysis time and sample quantity.     

Analysis of peptide MS/MS spectra from large-scale proteomics experiments using spectrum libraries

A widespread proteomics procedure for characterizing a complex mixture of proteins combines tandem mass spectrometry and database search software to yield mass spectra with identified peptide sequences. The same peptides are often detected in multiple experiments, and once they have been identified, the respective spectra can be used for future identifications. We present a method for collecting previously identified tandem mass spectra into a reference library that is used to identify new spectra. Query spectra are compared to references in the library to find the ones that are most similar. A dot product metric is used to measure the degree of similarity. With our largest library, the search of a query set finds 91% of the spectrum identifications and 93.7% of the protein identifications that could be made with a SEQUEST database search. A second experiment demonstrates that queries acquired on an LCQ ion trap mass spectrometer can be identified with a library of references acquired on an LTQ ion trap mass spectrometer. The dot product similarity score provides good separation of correct and incorrect identifications.     

Open tubular immobilized metal ion affinity chromatography combined with MALDI MS and MS/MS for identification of protein phosphorylation sites

Protein phosphorylation is one of the most important known posttranslational modifications. Tandem mass spectrometry has become an important tool for mapping out the phosphorylation sites. However, when a peptide generated from the enzymatic or chemical digestion of a phosphoprotein is highly phosphorylated or contains many potential phosphorylation residues, phosphorylation site assignment becomes difficult. Separation and enrichment of phosphopeptides from a digest mixture is desirable and often a critical step for MS/MS-based site determination. In this work, we present a novel open tubular immobilized metal ion affinity chromatography (OT-IMAC) method, which is found to be more effective and reproducible for phosphopeptide enrichment, compared to a commonly used commercial product, Ziptip from Millipore. A strategy based on a combination of OT-IMAC, sequential dual-enzyme digestion, and matrix-assisted laser desorption/ionization (MALDI) quadrupole time-of-flight tandem mass spectrometry for phosphoprotein characterization is presented. It is shown that MALDI MS/MS with collision-induced dissociation can be very effective in generating fragment ion spectra containing rich structural information, which enables the identification of phosphorylation sites even from highly phosphorylated peptides. The applicability of this method for real world applications is demonstrated in the characterization and identification of phosphorylation sites of a Na(+)/H(+) exchanger fusion protein, His182, which was phosphorylated in vitro using the kinase Erk2.     

Robust phosphoproteomic profiling of tyrosine phosphorylation sites from human T cells using immobilized metal affinity chromatography and tandem mass spectrometry

Protein tyrosine phosphorylation cascades are difficult to analyze and are critical for cell signaling in higher eukaryotes. Methodology for profiling tyrosine phosphorylation, considered herein as the assignment of multiple protein tyrosine phosphorylation sites in single analyses, was reported recently (Salomon, A. R.; Ficarro, S. B.; Brill, L. M.; Brinker, A.; Phung, Q. T.; Ericson, C.; Sauer, K.; Brock, A.; Horn, D. M.; Schultz, P. G.; Peters, E. C. Proc. Natl. Acad. Sci. U.S.A. 2003, 100, 443-448). The technology platform included the use of immunoprecipitation, immobilized metal affinity chromatography (IMAC), liquid chromatography, and tandem mass spectrometry. In the present report, we show that when using complex mixtures of peptides from human cells, methylation improved the selectivity of IMAC for phosphopeptides and eliminated the acidic bias that occurred with unmethylated peptides. The IMAC procedure was significantly improved by desalting methylated peptides, followed by gradient elution of the peptides to a larger IMAC column. These improvements resulted in assignment of approximately 3-fold more tyrosine phosphorylation sites, from human cell lysates, than the previous methodology. Nearly 70 tyrosine-phosphorylated peptides from proteins in human T cells were assigned in single analyses. These proteins had unknown functions or were associated with a plethora of fundamental cellular processes. This robust technology platform should be broadly applicable to profiling the dynamics of tyrosine phosphorylation.     

Comprehensive phosphorylation site analysis of individual phosphoproteins applying scoring schemes for MS/MS data

We have developed novel scoring schemes for the identification of (phospho)peptides (PeptideScore) and for pinpointing phosphorylation sites (PhosphoSiteScore) using MS/MS data. These scoring schemes have been developed for the in-depth analysis of individual phosphoproteins, not for large-scale phosphoproteomic-type data. The scoring schemes are implemented into the new software tool Phosm, which provides a concise and comprehensive presentation of the results. For development and evaluation of these schemes, we have analyzed approximately 500 phosphopeptide MS/MS spectra, most of them nontryptic peptides. The novel scoring schemes turned out to be very powerful, even with CID MS/MS spectra of very low quality. Many phosphopeptides and phosphorylation sites that remained unassigned in our LC-MS/MS data sets with Mascot could be identified with Phosm. Especially the number of identified multiply phosphorylated peptides could be significantly increased. The applied scoring parameters are described, and the scoring for several selected examples of phosphopeptides is discussed in detail. Furthermore, a new and simple nomenclature for all types of phosphorylated fragment ions is introduced in this publication.     

Analysis of perchlorate in human urine using ion chromatography and electrospray tandem mass spectrometry

Because of health concerns surrounding widespread exposure to perchlorate, we developed a sensitive and selective method for quantifying perchlorate in human urine using ion chromatography coupled with electrospray ionization tandem mass spectrometry. Perchlorate was quantified using a stable isotope-labeled internal standard ((18)O(4)-perchlorate) with excellent assay precision (coefficient of variation <5% for repetitively analyzed quality control material). Analytical accuracy was established by blind analysis of certified proficiency testing materials prepared in synthetic urine matrix; calculated amounts deviated minimally from true amounts, with percent differences ranging from 2% to 5%. Selective chromatography and tandem mass spectrometry reduced the need for sample cleanup, resulting in a rugged and rapid method capable of routinely analyzing 75 samples/day. The lowest reportable level (0.025 ng/mL) was sufficiently sensitive to detect perchlorate in all human urine samples evaluated to date, with a linear response range from 0.025 to 100 ng/mL. This selective, sensitive, and rapid method will help elucidate any potential associations between human exposure to low levels of perchlorate and adverse health effects.     

Discovering known and unanticipated protein modifications using MS/MS database searching

We present an MS/MS database search algorithm with the following novel features: (1) a novel protein database structure containing extensive preindexing and (2) zone modification searching, which enables the rapid discovery of protein modifications of known (i.e., user-specified) and unanticipated delta masses. All of these features are implemented in Interrogator, the search engine that runs behind the Pro ID, Pro ICAT, and Pro QUANT software products. Speed benchmarks demonstrate that our modification-tolerant database search algorithm is 100-fold faster than traditional database search algorithms when used for comprehensive searches for a broad variety of modification species. The ability to rapidly search for a large variety of known as well as unanticipated modifications allows a significantly greater percentage of MS/MS scans to be identified. We demonstrate this with an example in which, out of a total of 473 identified MS/MS scans, 315 of these scans correspond to unmodified peptides, while 158 scans correspond to a wide variety of modified peptides. In addition, we provide specific examples where the ability to search for unanticipated modifications allows the scientist to discover: unexpected modifications that have biological significance; amino acid mutations; salt-adducted peptides in a sample that has nominally been desalted; peptides arising from nontryptic cleavage in a sample that has nominally been digested using trypsin; other unintended consequences of sample handling procedures.     

On-line nano-HPLC/ESI QTOF MS and tandem MS for separation, detection, and structural elucidation of human erythrocytes neutral glycosphingolipid mixture

A superior approach involving nano-high-performance liquid chromatography (nano-HPLC) in on-line conjunction to electrospray ionization quadrupole time-of-flight mass spectrometry (ESI QTOF MS) and tandem MS for screening and structural characterization of complex mixtures of neutral glycosphingolipids (GSLs) is here described. Neutral GSLs purified from human erythrocytes were efficiently separated according to the differences in carbohydrate chain length by an optimized nano-HPLC protocol and flow-through detected by ESI QTOF MS at the low femtomole level. Additionally, GSL species were accurately distinguished from the accompanying lipids in the mixture, thus permitting the determination of detailed structural characteristics by data-dependent analysis for identification of GSL constitution within single experiments. An alternative nano-HPLC/ESI QTOF MS approach was designed for dissection of unsaturation/saturation degree of the ceramide moieties defining the hydrophobic portion of GSLs and subsequent localization by nano-HPLC/ESI QTOF MS/MS of the -CH=CH- within the ceramide regions. The method is fast, highly sensitive, and high-throughput amenable and is highlighted as a new and valuable analytical dimension in glycolipidomics.     

Peptide sequence motif analysis of tandem MS data with the SALSA algorithm.

We have developed a pattern recognition algorithm called SALSA (scoring algorithm for spectral analysis) for the detection of specific features in tandem MS (MS-MS) spectra. Application of the SALSA algorithm to the detection of peptide MS-MS ion series enables identification of MS-MS spectra displaying characteristics of specific peptide sequences. SALSA analysis scores MS-MS spectra based on correspondence between theoretical ion series for peptide sequence motifs and actual MS-MS product ion series, regardless of their absolute positions on the m/z axis. Analyses of tryptic digests of bovine serum albumin (BSA) by LC-MS-MS followed by SALSA analysis detected MS-MS spectra for both unmodified and multiple modified forms of several BSA tryptic peptides. SALSA analysis of MS-MS data from mixtures of BSA and human serum albumin (HSA) tryptic digests indicated that ion series searches with BSA peptide sequence motifs identified MS-MS spectra for both BSA and closely related HSA peptides. Optimal discrimination between MS-MS spectra of variant peptide forms is achieved when the SALSA search criteria are optimized to the target peptide. Application of SALSA to LC-MS-MS proteome analysis will facilitate the characterization of modified and sequence variant proteins.