Ashok Dongre scite author profile

Relative energetics of fragmentation of protonated peptides are investigated by using electrospray ionization/ surface-induced dissociation (ESI/SID) tandem mass spectrometry. ESI/SID fragmentation efficiency curves (percent fragmentation versus laboratory collision energy) are presented for 20 oligopeptides and are a measure of how easily a peptide fragments. The relative positions of the ESI/SID fragmentation efficiency curves depend on several parameters which include peptide composition (e.g., presence/absence of a basic amino acid residue) and peptide size. The ESI/SID fragmentation efficiency curves, in combination with quantum chemical calculations, provide a unique approach to substantiate and refine the mobile proton model for peptide fragmentation. Selected peptides are also investigated to further test and confirm the mobile proton model; these include doubly-protonated peptides and chemically-modified peptides (i.e., acetylated and fixed-charge derivatized peptides). Doubly-protonated peptides fragment more easily than the singly-protonated forms of the same peptides, with a sequence dependence for the difference in energy required for the fragmentation of singly-vs doubly-protonated peptides. Acetylation at the amino terminus and arginine side chain leads to a decrease in basicity and a corresponding lower energy onset for fragmentation than for the unmodified form of the peptide. Fixing the site of charge by addition of trimethylammonium acetyl to the amino terminus, i.e., eliminating the mobile proton, results in a higher energy onset than that for the protonated form of the same peptide. Curves for doubly protonated peptides with two adjacent basic residues (Arg, Arg) suggest the localization of the two protons at the two basic side chains rather than at opposite termini of the peptide.

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Fragmentation of protonated peptides: surface-induced dissociation in conjunction with a quantum mechanical approach

McCormack¹,

Somogyi²,

Dongre³

et al. 1993

Anal. Chem.

198

206

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This paper describes the results of a systematic investigation designed to assess the utility of surface-induced dissociation in the structural analysis of small peptides (500-1800u). A number of different peptides, ranging in mass and amino acid sequence, are fragmented by collision with a surface in a tandem mass spectrometer and the spectra are compared with data obtained by gas-phase collisional activation. The surface-induced dissociation spectra provide ample sequence information for the peptides. Side-chain cleavage ions of type w, which are generally detected upon kiloelectronvolt collisions with gaseous targets but not upon electronvolt collisions with gaseous targets, are detected in the ion-surface collision experiments. A theoretical approach based on MNDO bond order calculations is suggested for the description of peptide fragmentation. This model, supplemented by ab initio calculations, serves as a complement to the experimental work described in the paper and explains (i) the easy cleavage of the amide bond, (ii) charge-remote backbone and side-chain cleavages, and (iii) the influence of intramolecular H-bonding.

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Surfaceinduced Dissociation: An Effective Tool to Probe Structure, Energetics and Fragmentation Mechanisms of Protonated Peptides

1996

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The utility of surface-induced dissociation (SID) to probe the structure, energetics and fragmentation mechanisms of protonated peptides is discussed and demonstrated. High internal energy deposition provided by low-energy (eV range) ion-surface collisions yields extensive fragmentation of protonated peptides, allowing relatively uncomplicated and rapid sequence analysis of oligopeptides. SID of multiply protonated peptides is illustrated for peptides with molecular mass of up to approximately 5000 u. It is also illustrated that SID combined with electrospray ionization (ESI) provides a distinctive experimental technique to determine the energetics and mechanisms of peptide fragmentation. The relative position of ESI/SID fragmentation efficiency curves (plots of percentage fragmentation vs. laboratory collision energy) for peptides can be utilized to estimate relative energetics of peptide fragmentation and even to predict proton localization sites. The observed trends support the essential role of the mobile proton model in understanding peptide fragmentation by low-energy tandem mass spectrometry.

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Biomarker Discovery in Urine by Proteomics

et al. 2002

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A hypothesis was formed that it would be possible to isolate an adequate amount of protein from a patient, having normal renal function, to identify biological markers of a particular disease state using a variety of proteomics techniques. To support this hypothesis, three samples of urine were collected from a volunteer: first when healthy, later when experiencing acute inflammation due to a pilonidal abcess, and again later still after successful recovery from the condition. The urine from these samples was processed by solid-phase extraction to concentrate and desalt the endogenous proteins and peptides. The proteins and peptides from these urine samples were analyzed in three different experiments: (1) traditional two-dimensional gel electrophoresis followed by proteolysis and mass spectrometric identification of various protein spots, (2) whole mixture proteolysis followed by one-dimensional packed capillary liquid chromatography and tandem mass spectrometry, (3) whole mixture proteolysis followed by two-dimensional capillary liquid chromatography and tandem mass spectrometry. In all three cases, a set of proteins was identified representing putative biomarkers. Each of these proteins was then found to have been previously linked in the scientific literature to inflammation. One acute phase reactant in particular, orosomucoid, was readily observed in all three experiments to dramatically increase in abundance, thereby supporting the hypothesis.

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Sequence Dependence of Peptide Fragmentation Efficiency Curves Determined by Electrospray Ionization/Surface-Induced Dissociation Mass Spectrometry

Jones¹,

Dongre²,

Somogyi³

et al. 1994

J. Am. Chem. Soc.

178

193

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Ashok Dongre

Influence of Peptide Composition, Gas-Phase Basicity, and Chemical Modification on Fragmentation Efficiency: Evidence for the Mobile Proton Model

Fragmentation of protonated peptides: surface-induced dissociation in conjunction with a quantum mechanical approach

Surfaceinduced Dissociation: An Effective Tool to Probe Structure, Energetics and Fragmentation Mechanisms of Protonated Peptides

Biomarker Discovery in Urine by Proteomics

Sequence Dependence of Peptide Fragmentation Efficiency Curves Determined by Electrospray Ionization/Surface-Induced Dissociation Mass Spectrometry

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