Long-lived electron capture dissociation product ions experience radical migration via hydrogen abstraction

Electron detachment dissociation (EDD) has recently been shown by Amster and coworkers to constitute a valuable analytical approach for structural characterization of glycosaminoglycans. Here, we extend the application of EDD to neutral and sialylated oligosaccharides. Both branched and linear structures are examined, to determine whether branching has an effect on EDD fragmentation behavior. EDD spectra are compared to collisional activated dissociation (CAD) and infrared multiphoton dissociation (IRMPD) spectra of the doubly and singly deprotonated species. Our results demonstrate that EDD of both neutral and sialylated oligosaccharides provides structural information that is complementary to that obtained from both CAD and IRMPD. In all cases, EDD resulted in additional cross-ring cleavages. In most cases, cross-ring fragmentation obtained by EDD is more extensive than that obtained from IRMPD or CAD. Our results also indicate that branching does not affect EDD fragmentation, contrary to what has been observed for electron capture dissociation (ECD). . Unlike most biomolecules, oligosaccharides often exist as several isomeric forms with diverse linkages, and may form linear or branched structures. Complete structural characterization of oligosaccharides requires the determination of constituent monosaccharides, their linkage, sequence, and branching patterns. Given their diversity and structural complexity, structural elucidation of oligosaccharides often relies upon a wide range of analytical methodologies, of which nuclear magnetic resonance spectroscopy and mass spectrometry are two vital techniques. Tandem mass spectrometry (MS/MS) is widely used for glycan structural characterization [5][6][7], due to the advent of instruments that provide high-quality spectra from even low-abundance molecular species.Tandem mass spectra of oligosaccharides consist mainly of glycosidic and cross-ring product ions. Glycosidic cleavage occurs between monosaccharide units and provides information regarding saccharide sequence and branching. Cross-ring cleavages can provide valuable information regarding saccharide linkage, particularly when occurring at branching residues. Several factors are known to affect oligosaccharide fragmentation and the degree of cross-ring fragmentation, such as the ionizing cation, the lifetime of the ion before detection, and the energy deposited into the ion.Typically, neutral oligosaccharides are analyzed in positive-ion mode, by their protonated forms or through metal ion adduction. In addition, chemical derivatization such as permethylation is widely used to increase sensitivity, reduce molecular ion lability, and produce structurally diagnostic product ions [8 -10]. Low-energy activation methods, such as collisional activated dissociation (CAD) and infrared multiphoton dissociation (IRMPD), applied to protonated oligosaccharides results in predominantly glycosidic cleavages. However, oligosaccharides ionized with alkali, alkaline earth, and transition metals often fragment to yield more cro...

Section: Ms/ms Of Neutral Oligosaccharidesmentioning

confidence: 79%

Electron detachment dissociation of neutral and sialylated oligosaccharides

Adamson

Håkansson

2007

“…This picture is consistent with what is known about radical migration during ECD. In that case, the unpaired electron in an ␣-radical transfers stepwise to various other ␣-carbons, inducing a "radical cascade" of backbone fragmentations [33,36]. However, one cannot rule out the possibility that there is a similar distance dependence to the rate that radical ions fold.…”

Section: Kinetic Competition Between Radical Transfer and Charge-drivmentioning

confidence: 99%

“…Although O'Connor and coworkers have demonstrated that backbone ␣-hydrogens can be easily abstracted [36], it is still unclear whether backbone amidehydrogens are involved in the radical migration process. To address this issue, amide-hydrogens were replaced with deuterium by H/D exchange.…”

Section: Are Backbone Amide Hydrogens Transferable?mentioning

confidence: 99%

“…This differs from collisional dissociation of even-electron peptide ions, which favors the formation of b-and y-type ions. The unusual fragmentation of chargereduced radical ions has been attributed to radical-driven chemistry that can be described by a mobile hydrogen radical [35] or free radical reaction cascade [33,36]. Theoretical studies have also shown that a radical is responsible for these unusual fragmentation processes [9].…”

mentioning

confidence: 99%

See 1 more Smart Citation

Radical-driven dissociation of odd-electron peptide radical ions produced in 157 nm photodissociation

Zhang

Reilly

2009

Odd-electron a ϩ 1 radical ions generated in the 157 nm photodissociation of peptide ions were investigated in an ion trap mass spectrometer. To localize the radical, peptide backbone amide hydrogens were replaced with deuterium. When the resulting radical ions underwent hydrogen elimination, no H/D scrambling was obvious, suggesting that without collisional activation, the radical resides on the terminal ␣-carbon. Upon collisional excitation, oddelectron radical ions dissociate through two favored pathways: the production of a-type ions at aromatic amino acids via homolytic cleavage of backbone C ␣ -C(O) bonds and side-chain losses at nonaromatic amino acids. When aromatic residues are not present, nonaromatic residues can also lead to a-type ions. In addition to a-type ions, serine and threonine yield c n-1 and a n-1 ϩ 1 ions where n denotes the position of the serine or threonine. All of these fragments appear to be directed by the radical and they strongly depend on the amino acid side-chain structure. In addition, thermal fragments are also occasionally observed following cleavage of labile Xxx-Pro bonds and their formation appears to be kinetically competitive with radical migration. (J Am Soc Mass

“…Particular advances have been achieved as a result of Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS)-based electron capture dissociation (ECD) [4] complementarity to slow heating fragmentation methods [5], such as collision-induced dissociation (CID) [6] and infrared multiphoton dissociation (IRMPD) [7]. In addition to mainly product ion mass-based MS/ MS, product ion abundance (PIA) in ECD is increasingly considered as a new source of information to improve peptide and protein sequencing [8,9], quantitative modification analysis [10,11], higher-order structure characterization [8,[12][13][14][15], providing new insights into ECD mechanism [16,17], suggesting charge location in peptides and proteins [18,19], and indicating routes toward developing a quantitative model of ECD/ETD [15]. Double-resonance (DR) ECD, with and without ion preactivation, is used to estimate the radical intermediate lifetimes and differentiate between short-lived and long-lived intermediates by monitoring PIA variation attributed to radical intermediates ejection from the ICR trap immediately upon formation [20,21].…”

mentioning

confidence: 99%

Electron capture and transfer dissociation: Peptide structure analysis at different ion internal energy levels

Hamidane

Chiappe

Hartmer

et al. 2008

We decoupled electron-transfer dissociation (ETD) and collision-induced dissociation of charge-reduced species (CRCID) events to probe the lifetimes of intermediate radical species in ETD-based ion trap tandem mass spectrometry of peptides. Short-lived intermediates formed upon electron transfer require less energy for product ion formation and appear in regular ETD mass spectra, whereas long-lived intermediates require additional vibrational energy and yield product ions as a function of CRCID amplitude. The observed dependencies complement the results obtained by double-resonance electron-capture dissociation (ECD) Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS) and ECD in a cryogenic ICR trap. Compared with ECD FT-ICR MS, ion trap MS offers lower precursor ion internal energy conditions, leading to more abundant charge-reduced radical intermediates and larger variation of product ion abundance as a function of vibrational post-activation amplitude. In many cases decoupled CRCID after ETD exhibits abundant radical c-type and even-electron z-type ions, in striking contrast to predominantly even-electron c-type and [7]. In addition to mainly product ion mass-based MS/ MS, product ion abundance (PIA) in ECD is increasingly considered as a new source of information to improve peptide and protein sequencing [8,9], quantitative modification analysis [10, 11], higher-order structure characterization [8,[12][13][14][15], providing new insights into ECD mechanism [16,17], suggesting charge location in peptides and proteins [18,19], and indicating routes toward developing a quantitative model of ECD/ETD [15]. Double-resonance (DR) ECD, with and without ion preactivation, is used to estimate the radical intermediate lifetimes and differentiate between short-lived and long-lived intermediates by monitoring PIA variation attributed to radical intermediates ejection from the ICR trap immediately upon formation [20,21]. An alternative approach to DR-ECD is to compare ECD fragmentation patterns obtained at room-temperature (300 K) and cold (86 K) ICR ion trap conditions [22]. In cold ICR trap long-lived radical intermediates remain inside of the trap but do not have sufficient internal energy to initiate product ion separation and thus do not contribute to the product ion mass spectrum [9,22]. In general, long-lived radical intermediates exhibit a higher yield of radical N-terminal product ions, c· ions, and even-electron or prime C-terminal product ions, z= ions than that of short-lived intermediates, presumably as the result of increased probability of hydrogen atom transfer between ECD products [9,23]. Ion internal energy variation in activated ion (AI)-ECD [24] was shown to influence hydrogen atom rearrangement between ECD products and determine the ratio of radical to prime product ions [9,21]. Consideration of hydrogen atom loss/gain is important for correct product ion assignment and error-free peptide sequencing in proteomics [23,25].Implementation of electron-transfer dissociation (ETD) in io...