Glycopeptide identification using liquid-chromatography-compatible hot electron capture dissociation in a radio-frequency-quadrupole ion trap.

We developed a liquid chromatography (LC) compatible electron capture dissociation (ECD) mass spectrometer for glycoproteomics, with which ECD and hot ECD (HECD) experiments can be flexibly switched by quickly changing the electron energy without further tuning of the mass spectrometer. Desialylated glycopeptides were dissociated well in both ECD and HECD experiments. For sialylated glycopeptides, on the other hand, ECD with electron energy higher than 4 eV showed significantly higher sequence coverage than that with an electron energy of 0.2 eV. A nano LC system was coupled to our ECD mass spectrometer to investigate N-linked glycopeptides from lysylendopeptidase (Lys-C) digests of human transferrin. ECD spectra at multiple electron energies of 0.2, 5.0, and 9.0 eV were obtained for each targeting precursor ion in a single LC injection. Glycopeptides with a sialylated bi-, tri-, or tetra-antennary complex N-glycan were identified with high sequence coverage by HECD. Glycopeptides with tri- or tetra-antennary N-glycans have seldom been analyzed by ECD or ETD before this report. We also found that a preferential dissociation of nonreducing termini of glycans in glycopeptides by ECD and HECD.

Elucidating the sequence of intact bioactive peptides by using electron capture dissociation and hot electron capture dissociation in a linear radio-frequency quadrupole ion trap.

RATIONALE: Electron capture dissociation (ECD) is useful tool for sequencing of peptides and proteins with post-translational modifications. To increase the sequence coverage for peptides and proteins, it is important to develop ECD device with high fragmentation efficiency. METHODS: Sequence analysis of intact undigested bioactive peptides (3000-5000 Da) was performed by use of electron capture dissociation (rf-ECD) and collision-induced dissociation (CID) in a linear radio-frequency quadrupole ion trap that was coupled to a time-of-flight mass spectrometer. We applied rf-ECD, hot rf-ECD (rf-ECD with high electron energy), and CID for intact bioactive peptide ions of various charge states and evaluated the sequence coverage of their fragment spectra. RESULTS: Hot rf-ECD produced a higher number of c- and z-type fragment ions of modified peptide ions as electron energy increased in lower charged peptide ions, and sequence coverage greater than 80% was obtained compared with the CID case (40-80%). CONCLUSIONS: The result indicates that intact bioactive modified peptides (Ghrelin, ANP) were correctly identified by use of hot rf-ECD.

Determination of O-glycosylation heterogeneity using a mass-spectrometric method retaining sugar modifications.

A mass-spectrometric method for a de novo determination of O-glycosylation heterogeneity was developed. We used a mild fragmentation technique, electron capture dissociation (ECD), which enables the determination of glycosylation sites as well as peptide sequencing. To demonstrate the correct identification of glycopeptides, we prepared a series of glycopeptides with the same peptide sequence and 6 different glycan modifications. ECD spectra were obtained at various electron energies, and were analyzed with the Mascot database-search engine. The obtained candidate glycopeptides were further validated by confirming the spectral overlap of ECD fragment peaks with the theoretical peaks. The results indicate that all glycopeptides were unambiguously identified, including glycosylation sites by combining ECD results with different electron energies for each glycopeptide.

Probe for label-free quantitative analysis in liquid chromatography/mass spectrometry.

A technique for detecting ion suppression in LC/MS was developed by adding a specific concentration of a probe molecule to an LC mobile phase. The probe is sufficiently acidic and hydrophilic, such that the intensity of the protonated probe, as analyzed in a mass spectrometer, is expected to decrease much more than those of other analytes when ion suppression occurs. Thus, the potential occurrence of ion suppression is detected by monitoring the intensity of the protonated probe. However, the probe has been developed for limited conditions of the LC mobile phase used in proteomics. In this paper, we examine the probe's applicability to the experimental conditions used in pharmacokinetics and drug metabolism. Our results demonstrate that the probe can be used in mobile phases, in which the pH ranges from 1.8 to 6.7 and the organic solvent concentration ranges from 10 to 90%. Furthermore, the detection of ion suppression in the analysis of Omeprazole in human plasma was demonstrated by increasing the amount of the plasma in the sample solution.

Fast multiple electron capture dissociation in a linear radio frequency quadrupole ion trap.

We developed a fast electron capture dissociation (ECD) device using a linear radio frequency-quadrupole (RFQ) ion trap. The device dissociated peptides and proteins using a focused electron beam with an intensity of 0.5 microA and a diameter of 1 mm. The electron capture rate was 13%/ms for doubly charged peptides, and the total amount of ECD products was identical to the theoretical limit, i.e., 50% of incident precursor ions were observed as maximum ECD products by electron irradiation of 7 ms in a pulse counting detection scheme. Coupling this ECD device to a time-of-flight mass spectrometer, we applied multiple ECD. Protonated ubiquitin precursor ions with a charge state of 10 were repeatedly cleaved by ECD, i.e., charge-reduced species and their highly charged fragments were cleaved again and again, creating lower charged products, leaving only singly to triply charged states among the final products. Meanwhile with the amount of electron irradiated, lower charged products increased. Applying an electron beam for 8 ms, we obtained 96% of the total sequence coverage using a 40 fmol sample except at three proline sites. This fast ECD device should be widely applicable to proteomics including post-translational modification analysis and top-down analysis.

Detection of potential ion suppression for peptide analysis in nanoflow liquid chromatography/mass spectrometry.

A detection technique for ion suppression in liquid chromatography/mass spectrometry (LC/MS) was developed by adding a probe to an LC mobile phase at a certain concentration. The probe is so hydrophilic that it is not adsorbed in a reversed-phase nanoflow LC column, and, furthermore, has an isoelectric point of about 3, which is lower than that for most peptides and is close to the pH of the mobile phase. The intensity of the protonated probe molecule decreases much more than that of other peptides when ion suppression occurs. Thus, the occurrence of the ion suppression is detected by a decrease in the mass chromatogram for the protonated probe molecule, and the decrease ratio is higher than that for other ions.

Structural analysis of O-glycopeptides employing negative- and positive-ion multi-stage mass spectra obtained by collision-induced and electron-capture dissociations in linear ion trap time-of-flight mass spectrometry.

Structural analyses of various glycans attached to proteins and peptides are highly desirable for elucidating their biological roles. An approach based on mass spectrometry (MS) combining both collision-induced dissociation (CID) and electron-capture dissociation (ECD) in the positive- and negative-ion modes has been proposed as a simple and direct method of assigning an O-glycan without releasing it from the peptide and of determining the amino acid sequence of the peptide and glycosylation site. The instrument used is an electrospray ionization (ESI) linear ion trap (LIT) time-of-flight (TOF) mass spectrometer with tandem LITs for CID by He gas and ECD. The proposed approach was tested with two synthetic O-glycopeptides binding a sialyl Lewis x (sLe(x)) oligosaccharide and a 3'-sialyl N-acetyllactosamine (3'-SLN) on a serine (S) residue. In the negative-ion mode, the CID MS(2) spectra of O-glycopeptides showed a relatively abundant glycoside-bond cleavage between the core N-acetylglucosamine (GlcNAc) and serine (S) that yields deprotonated C(3)-type fragment ions of O-glycan and deprotonated Z(0)-type peptide ions. The structure of the sLe(x) (3'-SLN) oligosaccharide was simply assigned by comparing the CID MS(3) spectrum derived from the C(3)-type fragment ion with the CID MS(2) spectra of the sLe(x) and sLe(a) (3'- and 6'-SLN) standards (i.e., negative-ion MS(n) spectral matching). The amino acid sequence of the peptide including the glycosylation site was determined from the ECD MS(2) spectrum in the positive-ion mode.

'Information-Based-Acquisition' (IBA) technique with an ion-trap/time-of-flight mass spectrometer for high-throughput and reliable protein profiling.

Highly complex protein mixtures can be analyzed after proteolysis using liquid chromatography/mass spectrometry (LC/MS). In an LC/MS run, intense peptide ions originating from high-abundance proteins are preferentially analyzed using tandem mass spectrometry (MS(2)), so obtaining the MS(2) spectra of peptide ions from low-abundance proteins is difficult even if such ions are detected. Furthermore, the MS(2) spectra may produce insufficient information to identify the peptides or proteins. To solve these problems, we have developed a real-time optimization technique for MS(2), called the Information-Based-Acquisition (IBA) system. In a preliminary LC/MS run, a few of the most intense ions detected in every MS spectrum are selected as precursors for MS(2) and their masses, charge states and retention times are automatically registered in an internal database. In the next run, a sample similar to that used in the first run is analyzed using database searching. Then, the ions registered in the database are excluded from the precursor ion selection to avoid duplicate MS(2) analyses. Furthermore, real-time de novo sequencing is performed just after obtaining the MS(2) spectrum, and an MS(3) spectrum is obtained for accurate peptide identification when the number of interpreted amino acids in the MS(2) spectrum is less than five. We applied the IBA system to a yeast cell lysate which is a typical crude sample, using a nanoLC/ion-trap time-of flight (IT/TOF) mass spectrometer, repeating the same LC/MS run five times. The obtained MS(2) and MS(3) spectra were analyzed by applying the Mascot (Matrix Science, Boston, MA, USA) search engine to identify proteins from the sequence database. The total number of identified proteins in five LC/MS runs was three times higher than that in the first run and the ion scores for peptide identification also significantly increased, by about 70%, when the MS(3) spectra were used, combined with the MS(2) spectra, before being subjected to Mascot analysis.

Characteristic pH and electrolyte concentration dependences of 2-aminopyridine-derivatized oligosaccharides (N-glycans) in sonic-spray ionization mass spectrometry.

The intensities of ion signals from neutral oligosaccharides (N-glycans) derivatized with 2-aminopyridine (PA) were analyzed by ion trap mass spectrometry with a sonic-spray ionization (SSI) source, in both positive- and negative-ion modes, while varying the pH and concentration of ammonium acetate buffer solution. Two characteristic results are reported and discussed. The first characteristic is the pH dependence of the ion intensities; on increasing the solution pH from 4.3 to 8.6, positive ion intensities increase and negative ion intensities decrease. The second characteristic concerns the dependence of ion intensities on electrolyte concentration; on increasing the electrolyte concentration, the SSI efficiency for the PA N-glycans first increases and then decreases. Assuming that the SSI mechanism essentially conforms to the statistical charging model and the charge residue model, a new model that focuses a great deal of attention on the counter (electrolyte) ion distribution surrounding the solvated analyte (PA N-glycan) is proposed, in particular to rationalize the characteristic pH dependence.

Electron capture dissociation in a radio frequency ion trap.

We report on the first evidence of electron capture dissociation (ECD) in a radio frequency (rf) ion trap. Peptide ions, [substance P]2+, trapped in a two-dimensional, linear rf ion trap were cleaved by electrons injected along the central axis of the trap. Along the axis, the rf field component was zero and a magnetic field of 50 mT was applied. This electron injection scheme keeps the energy of the electrons below 1 eV, preventing them from heating by the rf field. The present ECD efficiency is approximately 4% by irradiation of electron current of 0.2 microA for 80 ms. ECD in rf traps may open high-throughput and low-cost ECD applications to obtain molecular structure information complementary to collision-induced dissociation.

A novel nanoflow interface for atmospheric pressure ionization mass spectrometry.

A novel spray-ionization technique for nanoflow liquid chromatography/mass spectrometry (nLC/MS) has been developed by modifying the sonic spray ionization (SSI) technique. A solution from a tapered fused-silica capillary is sprayed by a gas flow coaxial to the capillary, and ions produced are analyzed with an ion-trap mass spectrometer. The ion intensity is shown to have a steep threshold at a low gas velocity and to be much less dependent on the gas velocity than that of conventional SSI, in which the ion intensity is strongly dependent on the gas velocity and reaches its maximum at sonic velocity. Thus, we conclude that the concentration of charge in the solution at the tapered capillary tip with an inner diameter of 15 microm is almost at saturation so that charged droplets are produced from the solution by electrical force, rather than by sheer stress due to the gas flow. The ions are readily produced from these charged droplets. Preliminary results are compared with results obtained with a miniaturized electrospray unit.

Multi-charged oligonucleotide ion formation in sonic spray ionization.

An oligonucleotide tends to release hydrogen atoms from a phosphoric acid group and to form negative ions that can be detected by mass spectrometry. Usually, with a solution-spray based ionization technique, the negative ions are present in different charge states. Ion formation for the nucleotide is quite complicated and is easily influenced by matrix and other constituents in a sample solution, as well as by the operating parameters for a mass spectrometer. In this work, we studied oligonucleotide ion formation by using an ion trap mass spectrometer combined with a sonic spray ionization (SSI) source. An oligonucleotide with 20 bases was measured. Effects from contaminants and parameters affecting the ion production, such as a high voltage applied to the ionization source and sample solution-flow rate, were investigated. Our results showed that an ion with about one charge for every three bases was most abundant. However, the signal intensity and the mass spectrum pattern were sensitive to the matrix and operating parameters. One of the reasons for such sensitivity is that there are various ion states for an oligonucleotide. Any change in the matrix or an operating parameter may shift the balances between the ion states. Adding Tris, or (hydroxymethyl)aminomethane, enhanced the signal intensity of the oligonucleotide and promoted formation of the oligonucleotide ion with higher charges, while adding acetic acid favored the ions with lower charges, compared with that obtained in the medium without adding Tris and acetic acid. The effects on charged droplets and chemical enhancement were investigated. The mechanism for oligonucleotide ion formation is discussed.