Parallel Ion Parking:  Improving Conversion of Parents to First-Generation Products in Electron Transfer Dissociation

Electron-transfer dissociation (ETD) in a tandem mass spectrometer is an analytically useful ion/ion reaction technique for deriving polypeptide sequence information, but its utility can be limited by sequential reactions of the products. Sequential reactions lead to neutralization of some products,...

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Bibliographic Details
Published in:Analytical chemistry (Washington) 2005-05, Vol.77 (10), p.3411-3414
Main Authors: Chrisman, Paul A, Pitteri, Sharon J, McLuckey, Scott A
Format: Article
Language:English
Subjects:
Analytical chemistry
Angiotensin I - analysis
Angiotensin I - chemistry
Anions
Electron Transport
Ions
Mass spectrometry
Nitrobenzenes - chemistry
Peptide Fragments - analysis
Peptide Fragments - chemistry
Peptides - analysis
Peptides - chemistry
Protons
Sequence Analysis, Protein - methods
Tandem Mass Spectrometry - methods
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Summary:Electron-transfer dissociation (ETD) in a tandem mass spectrometer is an analytically useful ion/ion reaction technique for deriving polypeptide sequence information, but its utility can be limited by sequential reactions of the products. Sequential reactions lead to neutralization of some products, as well as to signals from products derived from multiple cleavages that can be difficult to interpret. A method of inhibiting sequential ETD fragmentation in a quadrupole ion trap is demonstrated here for the reaction of a triply protonated peptide with nitrobenzene anions. A tailored waveform (in this case, a filtered noise field) is applied during the ion/ion reaction time to accelerate simultaneously first-generation product ions and thereby inhibit their further reaction. This results in a ∼50% gain in the relative yield of first-generation products and allows for the conversion of more than 90% of the original parent ions into first-generation products. Gains are expected to be even larger when higher charge-state cations are used, as the rates of sequential reaction become closer to the initial reaction rate.
ISSN:0003-2700
1520-6882
DOI:10.1021/ac0503613