Abstract The combination of helium charge transfer dissociation mass spectrometry (He–CTD–MS) with ultrahigh performance liquid chromatography (UHPLC) is presented for the analysis of a complex mixture of acidic and neutral human milk oligosaccharides (HMOs). The research focuses on the identification of the monosaccharide sequence, the branching patterns, the sialylation/fucosylation arrangements, and the differentiation of isomeric oligosaccharides in the mixture. Initial studies first optimized the conditions for the UHPLC separation and the He–CTD–MS conditions. Results demonstrate that He–CTD is compatible with UHPLC timescales and provides unambiguous glycosidic and cross-ring cleavages from both the reducing and the nonreducing ends, which is not typically possible using collision-induced dissociation. He–CTD produces informative fragments, including 0,3An and 0,4An ions, which have been observed with electron transfer dissociation, electron detachment dissociation, and ultraviolet photodissociation (UVPD) and are crucial for differentiating the α-2,3- versus α-2,6-linked sialic acid (Neu5Ac) residues present among sialyllacto-N-tetraose HMOs. In addition to the linkage positions, He–CTD is able to differentiate structural isomers for both sialyllacto-N-tetraoses and lacto-N-fucopentaoses structures by providing unique, unambiguous cross-ring cleavages of types 0,2An, 0,2Xn, and 1,5An while preserving most of the labile Neu5Ac and fucose groups.
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Charge transfer dissociation of a branched glycan with alkali and alkaline earth metal adducts
Alkali and alkaline earth metal adducts of a branched glycan, XXXG, were analyzed with helium charge transfer dissociation (He‐CTD) and low‐energy collision‐induced dissociation (LE‐CID) to investigate if metalation would impact the type of fragments generated and the structural characterization of the analyte. The studied adducts included 1+ and 2+ precursors involving one or more of the cations: H+, Na+, K+, Ca2+, and Mg2+. Regardless of the metal adduct, He‐CTD generated abundant and numerous glycosidic and cross‐ring cleavages that were structurally informative and able to identify the 1,4‐linkage and 1,6‐branching patterns. In contrast, the LE‐CID spectra mainly contained glycosidic cleavages, consecutive fragments, and numerous neutral losses, which complicated spectral interpretation. LE‐CID of [M + K + H]2+and [M + Na]+precursors generated a few cross‐ring cleavages, but they were not sufficient to identify the 1,4‐linkage and 1,6‐branching pattern of the XXXG xyloglucan. He‐CTD predominantly generated 1+ fragments from 1+ precursors and 2+ product ions from 2+ precursors, although both LE‐CID and He‐CTD were able to generate 1+ product ions from 2+ adducts of magnesium and calcium. The singly charged fragments derive from the loss of H+from the metalated product ions and the formation of a protonated complementary product ion; such observations are similar to previous reports for magnesium and calcium salts undergoing electron capture dissociation (ECD) activation. However, during He‐CTD, the [M + Mg]2+precursor generated more singly charged product ions than [M + Ca]2+, either because Mg has a higher second ionization potential than Ca or because of conformational differences and the locations of the charging adducts during fragmentation. He‐CTD of the [M + 2Na]2+and the [M + 2 K]2+precursors generated singly charged product ions from the loss of a sodium ion and potassium ion, respectively. In summary, although the metal ions influence the mass and charge state of the observed product ions, the metal ions had a negligible effect on the types of cross‐ring cleavages observed.
more » « less- Award ID(s):
- 1710376
- NSF-PAR ID:
- 10451093
- Publisher / Repository:
- Wiley Blackwell (John Wiley & Sons)
- Date Published:
- Journal Name:
- Journal of Mass Spectrometry
- Volume:
- 56
- Issue:
- 7
- ISSN:
- 1076-5174
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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Abstract We recently reported a detailed investigation of the collision‐induced dissociation (CID) of [UO2(NO3)3]−and [UO2(NO3)2(O2)]−in a linear ion trap mass spectrometer (
J. Mass Spectrom . DOI:10.1002/jms.4705). Here, we describe the CID of [UO2(NO3)(O2)]−which is created directly by ESI, or indirectly by simple elimination of O2from [UO2(NO3)(O2)2]−. CID of [UO2(NO3)(O2)]−creates product ions as atm/z 332 andm/z 318. The former may be formed directly by elimination of O2, while the latter required decomposition of a nitrate ligand and elimination of NO2. DFT calculations identify a pathway by which both product ions can be generated, which involves initial isomerization of [UO2(NO3)(O2)]−to create [UO2(O)(NO2)(O2)]−, from which elimination of NO2or O2will leave [UO2(O)(O2)]−or [UO2(O)(NO2)]−, respectively. For the latter product ion, the composition assignment of [UO2(O)(NO2)]−rather than [UO2(NO3)]−is supported by ion‐molecule reaction behavior, and in particular, the fact that spontaneous addition of O2, which is predicted to be the dominant reaction pathway for [UO2(NO3)]−is not observed. Instead, the species reacts with H2O, which is predicted to be the favored pathway for [UO2(O)(NO2)]−. This result in particular demonstrates the utility of ion‐molecule reactions to assist the determination of ion composition. As in our earlier study, we find that ions such as [UO2(O)(NO2)]−and [UO2(O)(O2)]−form H2O adducts, and calculations suggest these species spontaneously rearrange to create dihydroxides. -
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Rationale Free fatty acids and lipid classes containing fatty acid esters are major components of lipidome. In the absence of a chemical derivatization step, FA anions do not yield all of the structural information that may be of interest under commonly used collision‐induced dissociation (CID) conditions. A line of work that avoids condensed‐phase derivatization takes advantage of gas‐phase ion/ion chemistry to charge invert FA anions to an ion type that provides the structural information of interest using conventional CID. This work was motivated by the potential for significant improvement in overall efficiency for obtaining FA chain structural information.
Methods A hybrid triple quadrupole/linear ion‐trap tandem mass spectrometer that has been modified to enable the execution of ion/ion reaction experiments was used to evaluate the use of 4,4′,4″‐tri‐tert‐butyl‐2,2′:6′,2″‐terpyridine (ttb‐Terpy) as the ligand in divalent magnesium complexes for charge inversion of FA anions.
Results Mg(ttb‐Terpy)22+complexes provide significantly improved efficiency in producing structurally informative products from FA ions relative to Mg(Terpy)22+complexes, as demonstrated for straight‐chain FAs, branched‐chain FAs, unsaturated FAs, and cyclopropane‐containing FAs. It was discovered that most of the structurally informative fragmentation from [FA‐H + Mg(ttb‐Terpy)]+results from the loss of a methyl radical from the ligand followed by radical‐directed dissociation (RDD), which stands in contrast to the charge‐remote fragmentation (CRF) believed to be operative with the [FA‐H + Mg(Terpy)]+ions.
Conclusions This work demonstrates that a large fraction of product ions from the CID of ions of the form [FA‐H + Mg(ttb‐Terpy)]+are derived from RDD of the FA backbone, with a very minor fraction arising from structurally uninformative dissociation channels. This ligand provides an alternative to previously used ligands for the structural characterization of FAs via CRF.
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Non-covalent complexes of the short amyloid peptide motif Gly-Asn-Asn-Gln-Gln-Asn-Tyr (GNNQQNY) with peptide counterparts that were tagged with a diazirine ring at the N-termini (*GNNQQNY) were generated as singly charged ions in the gas phase. Specific laser photodissociation (UVPD) of the diazirine tag in the gas-phase complexes at 355 nm generated transient carbene intermediates that underwent covalent cross-linking with the target GNNQQNY peptide. The crosslinking yields ranged between 0.8 and 4.5%, depending on the combinations of peptide C-terminal amides and carboxylates. The covalent complexes were analyzed by collision-induced dissociation tandem mass spectrometry (CID-MS 3 ), providing distributions of cross-links at the target peptide amino acid residues. A general preference for cross-linking at the target peptide Gln-4-Gln-5-Asn-6-Tyr-7 segment was observed. Born–Oppenheimer molecular dynamics calculations were used to obtain 100 ps trajectories for nine lowest free-energy conformers identified by ωB97X-D/6-31+G(d,p) gradient geometry optimizations. The trajectories were analyzed for close contacts between the incipient carbene atom and the X–H bonds in the target peptide. The close-contact analysis pointed to the Gln-5 and Tyr-7 residues as the most likely sites of cross-linking, consistent with the experimental CID-MS 3 results. Non-covalent binding in the amide complexes was evaluated by DFT calculations of structures and energies. Although antiparallel arrangements of the GNNQQNY and *GNNQQNY peptides were favored in low-energy gas-phase and solvated complexes, the conformations and peptide–peptide interface surfaces were found to differ from the secondary structure of the dry interface in GNNQQNY motifs of amyloid aggregates.more » « less
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