A Negative Ion Mass Spectrometry Approach to Identify Cross-Linked Peptides Utilizing Characteristic Disulfide Fragmentations

Calabrese, Antonio N.; Good, Nikki J.; Wang, Tianfang; He, Jingjia; Bowie, John H.; Pukala, Tara L.

doi:10.1007/s13361-012-0407-x

Cited by 15 publications

(24 citation statements)

References 49 publications

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“…In addition, the resulting protein/peptide thiols often need to be protected due to the possibility of being reoxidized prior to MS analysis. Besides chemical reduction, other novel approaches include the cleavage of disulfide bonds via laser-based ionization [4–7], ultraviolet photodissociation [8–10], negative ion dissociation [11–14], electron-capture dissociation (ECD)[15], electron-transfer dissociation (ETD)[16–20], plasma-induced oxidation [21], or using new ion chemistry [22–28]. An alternative way for reducing disulfide bonds without involving chemical reductants is electrolytic reduction [29,30].…”

Section: Introductionmentioning

confidence: 99%

Integration of online digestion and electrolytic reduction with mass spectrometry for rapid disulfide-containing protein structural analysis

Zheng

Zhang

Chen

2013

International Journal of Mass Spectrometry

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Bottom-up structural analysis of disulfide-bond containing proteins usually involves time-consuming offline enzymatic digestion, chemical reduction and thiol protection prior to mass spectrometric detection, which takes many hours. This paper presents an expedited bottom-up approach, employing desorption electrospray ionization-mass spectrometry (DESI-MS) coupled with online pepsin digestion and online electrochemical reduction of disulfide bonds. Peptides are generated in high digestion yield as its precursor protein in acidic aqueous solution flows through a pepsin column, which can undergo direct electrolysis. The electrolytic behaviors of peptides, as online monitored by DESI-MS, suggest the presence or absence of disulfide bonds in the peptides, and also provide information to relate disulfide bond-containing peptide precursors to their corresponding reduced products. Furthermore, selective electrolysis simply using different reduction potentials can be adopted to generate either partially or fully reduced peptides to assist disulfide bond mapping. In addition, it turns out that DESI is suitable for ionizing peptides in water without organic solvent additives (organic solvent additives would not be compatible with the use of pepsin column). The feasibility of this method was demonstrated using insulin, a protein carrying three pairs of disulfide-bonds as an example, in which all disulfide bond linkages and most of the protein sequence were successfully determined. Strikingly, this method shortens the sample digestion, reduction and MS detection from hours to less than 7 min, which could be of high value in high-throughput proteomics research.

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Section: Introductionmentioning

confidence: 99%

Integration of online digestion and electrolytic reduction with mass spectrometry for rapid disulfide-containing protein structural analysis

Zheng

Zhang

Chen

2013

International Journal of Mass Spectrometry

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“…Consequently, the use of cleavable cross‐linkers has been the subject of much current research, especially collision‐induced dissociation (CID) cleavable reagents . These may eject a reporter ion of known m / z , or result in cleavage of a labile bond in the reagent to afford product ions corresponding to each of the cross‐linked peptides . Identification of the peptide fragments and determination of the residue modified by the cross‐linking reagent is then achieved by MS n experiments.…”

Section: Methodsmentioning

confidence: 99%

Negative ion fragmentations of disulfide‐containing cross‐linking reagents are competitive with aspartic acid side‐chain‐induced cleavages

Calabrese

Wang

Bowie

et al. 2012

Rapid Comm Mass Spectrometry

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Low-energy cleavage processes from aspartic acid that compete with cross-linker fragmentations occur in the negative ion MS/MS spectra of the cross-linked peptides, irrespective of the spacer arm length. Other fragmentation pathways do not significantly interfere with low-energy disulfide cleavage, making the presence of additional product ions in the MS/MS spectrum diagnostic for the presence of aspartic acid.

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“…The structures of the other intermolecular peptides shown in Scheme are determined in similar fashion. The facile negative‐ion cleavages of the intermolecular disulfide group have also been used to identify cross‐linked peptides and proteins (Calabrese et al, , ).…”

Section: Introductionmentioning

confidence: 99%

Negative ion cleavages of (M–H)⁻ anions of peptides. Part 3. Post‐translational modifications

Wang

Tran

Andreazza

et al. 2016

Mass Spectrometry Reviews

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It is now 25 years since we commenced the study of the negative-ion fragmentations of peptides and we have recently concluded this research with investigations of the negative-ion chemistry of most post-translational functional groups. Our first negative-ion peptide review (Bowie, Brinkworth, & Dua, 2002) dealt with the characteristic backbone fragmentations and side-chain cleavages from (M-H) ions of underivatized peptides, while the second (Bilusich & Bowie, 2009) included negative-ion backbone cleavages for Ser and Cys and some initial data on some post-translational groups including disulfides. This third and final review provides a brief summary of the major backbone and side chain cleavages outlined before (Bowie, Brinkworth, & Dua, 2002) and describes the quantum mechanical hydrogen tunneling associated with some proton transfers in enolate anion/enolate systems. The review then describes, in more depth, the negative-ion cleavages of the post-translational groups Kyn, isoAsp, pyroglu, disulfides, phosphates, and sulfates. Particular emphasis is devoted to disulfides (both intra- and intermolecular) and phosphates because of the extensive and spectacular anion chemistry shown by these groups. © 2016 Wiley Periodicals, Inc. Mass Spec Rev.

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A Negative Ion Mass Spectrometry Approach to Identify Cross-Linked Peptides Utilizing Characteristic Disulfide Fragmentations

Cited by 15 publications

References 49 publications

Integration of online digestion and electrolytic reduction with mass spectrometry for rapid disulfide-containing protein structural analysis

Integration of online digestion and electrolytic reduction with mass spectrometry for rapid disulfide-containing protein structural analysis

Negative ion fragmentations of disulfide‐containing cross‐linking reagents are competitive with aspartic acid side‐chain‐induced cleavages

Negative ion cleavages of (M–H)⁻ anions of peptides. Part 3. Post‐translational modifications

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A Negative Ion Mass Spectrometry Approach to Identify Cross-Linked Peptides Utilizing Characteristic Disulfide Fragmentations

Cited by 15 publications

References 49 publications

Integration of online digestion and electrolytic reduction with mass spectrometry for rapid disulfide-containing protein structural analysis

Integration of online digestion and electrolytic reduction with mass spectrometry for rapid disulfide-containing protein structural analysis

Negative ion fragmentations of disulfide‐containing cross‐linking reagents are competitive with aspartic acid side‐chain‐induced cleavages

Negative ion cleavages of (M–H)− anions of peptides. Part 3. Post‐translational modifications

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Negative ion cleavages of (M–H)⁻ anions of peptides. Part 3. Post‐translational modifications