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.
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.
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.
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.
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.
- NSF-PAR ID:
- 10498807
- Publisher / Repository:
- Wiley Blackwell (John Wiley & Sons)
- Date Published:
- Journal Name:
- Rapid Communications in Mass Spectrometry
- Volume:
- 38
- Issue:
- 11
- ISSN:
- 0951-4198
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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Rationale Coordinatively driven self‐assembly of transition metal ions and bidentate ligands gives rise to organometallic complexes that usually contain superimposed isobars, isomers, and conformers. In this study, the double dispersion ability of ion mobility mass spectrometry (IM‐MS) was used to provide a comprehensive structural characterization of the self‐assembled supramolecular complexes by their mass and charge, revealed by the MS event, and their shape and collision cross‐section (Ω), revealed by the IM event.
Methods Self‐assembled complexes were synthesized by reacting a bis(terpyridine) ligand exhibiting a 60odihedral angle between the two ligating terpyridine sites (
T ) with divalent Zn, Ni, Cd, or Fe. The products were isolated as (Metal2+[T ])n (PF6)2n salts and analyzed using IM‐MS after electrospray ionization (ESI) which produced several charge states from eachn ‐mer, depending on the number of PF6ˉ anions lost upon ESI. Experimental Ω data, derived using IM‐MS, and computational Ω predictions were used to elucidate the size and architecture of the complexes.Results Only macrocyclic dimers, trimers, and tetramers were observed with Cd2+, whereas Zn2+formed the same plus hexameric complexes. These two metals led to the simplest product distributions and no linear isomers. In sharp contrast, Ni2+and Fe2+formed all possible ring sizes from dimer to hexamer as well as various linear isomers. The experimental and theoretical Ω data indicated rather planar macrocyclic geometries for the dimers and trimers, twisted 3D architectures for the larger rings, and substantially larger sizes with spiral conformation for the linear congeners. Adding PF6ˉ to the same complex was found to mainly cause size contraction due to new stabilizing anion–cation interactions.
Conclusions Complete structural identification could be accomplished using ESI‐IM‐MS. Our results affirm that self‐assembly with Cd2+and Zn2+proceeds through reversible equilibria that generate the thermodynamically most stable structures, encompassing exclusively macrocyclic architectures that readily accommodate the 60oligand used. In contrast, complexation with Ni2+and Fe2+, which form stronger coordinative bonds, proceeds through kinetic control, leading to more complex mixtures and kinetically trapped less stable architectures, such as macrocyclic pentamers and linear isomers.
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Methods Cationic uranyl‐propiolate precursor ions were generated by electrospray ionization, and multiple‐stage CID in a linear trap instrument was used to prepare [O=U≡CH]+. Neutral CS2was admitted into the trap through a modified He inlet and precision leak valves.
Results The [O=U≡CH]+ion reacts with CS2to generate [OUS]+. CID of [OUS]+causes elimination of the axial sulfide ligand to generate [OU]+. Using isotopically labeled reagent, we found that [OUS]+reacts with O2to create [UO2]+.
Conclusions [O=U≡CH]+proves to be a useful reagent ion for synthesis of [OUS]+, a species that to date has only been created by gas‐phase reactions of U+and U2+. Dissociation of [OUS]+to create [OU]+, but not [US]+, and the efficient conversion of the species into [UO2]+, is consistent with the relative differences in U–O and U–S bond energies.
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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 (
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Methods Four model peptides and two wild‐type peptide sequences containing either Leu or Ile residues were subjected to charge transfer dissociation (CTD) mass spectrometry on a modified three‐dimensional ion trap. The peptides were analyzed in both the 1+ and 2+ charge states, and the results were compared to conventional collision‐induced dissociation spectra of the same peptides obtained using the same instrument.
Results CTD resulted in 100% sequence coverage for each of the studied peptides and provided a variety of side‐chain cleavages, including
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