Formation of cationic peptide radicals by gas-phase redox reactions with trivalent chromium, manganese, iron, and cobalt complexes.
about
Dissociation behavior of a bifunctional tempo-active ester reagent for peptide structure analysis by free radical initiated peptide sequencing (FRIPS) mass spectrometry.Radical induced fragmentation of amino acid esters using triphenylcorrole(CuIII) complexes.Gas-phase ion/ion reactions of transition metal complex cations with multiply charged oligodeoxynucleotide anions.Radical-directed dissociation of peptides and proteins by infrared multiphoton dissociation and sustained off-resonance irradiation collision-induced dissociation with Fourier transform ion cyclotron resonance mass spectrometryStrategies for generating peptide radical cations via ion/ion reactions.Formation, isomerization, and dissociation of ε- and α-carbon-centered tyrosylglycylglycine radical cations.Transformation of [M + 2H](2+) Peptide Cations to [M - H](+), [M + H + O](+), and M(+•) Cations via Ion/Ion Reactions: Reagent Anions Derived from Persulfate.Isomerization versus dissociation of phenylalanylglycyltryptophan radical cations.Formation and dissociation of phosphorylated peptide radical cations.Formation of peptide radical ions through dissociative electron transfer in ternary metal-ligand-peptide complexes.Radical-driven peptide backbone dissociation tandem mass spectrometry.TEMPO-Assisted Free Radical-Initiated Peptide Sequencing Mass Spectrometry (FRIPS MS) in Q-TOF and Orbitrap Mass Spectrometers: Single-Step Peptide Backbone Dissociations in Positive Ion Mode.Surface-induced dissociation: a unique tool for studying energetics and kinetics of the gas-phase fragmentation of large ions.Novel Cβ-Cγ bond cleavages of tryptophan-containing peptide radical cations.Charge remote fragmentation in electron capture and electron transfer dissociation.The dehydroalanine effect in the fragmentation of ions derived from polypeptides.Mobile protons versus mobile radicals: gas-phase unimolecular chemistry of radical cations of cysteine-containing peptides.Fragmentation of alpha-radical cations of arginine-containing peptides.Mechanistic investigation of phosphate ester bond cleavages of glycylphosphoserinyltryptophan radical cations under low-energy collision-induced dissociation.Radical-driven dissociation of odd-electron peptide radical ions produced in 157 nm photodissociation.Electron capture dissociation of hydrogen-deficient peptide radical cations.Kinetics for tautomerizations and dissociations of triglycine radical cations.Experimental and computational studies of the macrocyclic effect of an auxiliary ligand on electron and proton transfers within ternary copper(II)-histidine complexes.Gas-phase fragmentation of long-lived cysteine radical cations formed via NO loss from protonated S-nitrosocysteine.Photoinduced intermolecular cross-linking of gas phase triacylglycerol lipid ions.Fragmentation of singly, doubly, and triply charged hydrogen deficient peptide radical cations in infrared multiphoton dissociation and electron induced dissociation.Radical additions to aromatic residues in peptides facilitate unexpected side chain and backbone losses.Gas-phase tyrosine-to-cysteine radical migration in model systems.The Generation of Dehydroalanine Residues in Protonated Polypeptides: Ion/Ion Reactions for Introducing Selective Cleavages.Formation of anionic peptide radicals in vacuo.Formation of curcumin molecular ion under electrospray ionisation conditions in the presence of metal cations.Stability of Odd- Versus Even-Electron Gas-Phase (Quasi)Molecular Ions Derived from Pyridine-Substituted N-Heterotriangulenes
P2860
Q30316695-21B36A2E-0736-4B00-83FA-59081B07A8EFQ33276751-B6317477-59F2-470B-969A-8889D3E381E4Q33310555-0943CE0E-000B-4CE5-A1D3-468FA5DA8FACQ34541209-2EA9A4ED-0FC8-40EB-94E7-D2038AB84123Q35214972-11AC6CC6-369D-4551-A7D4-832880DCBA22Q35310829-CCB9D3C0-C78B-4353-AEB1-5070579D1F1CQ35762950-A03684AF-6CC5-4F2C-9D02-55CEBEBE24B6Q36410063-993A31F9-AB22-412A-8FD2-00BB82BA8CF8Q36446313-18C736A6-5E26-4D54-AC9E-F3D5F3E07327Q37978547-3CB1E09C-A05B-4734-A039-CDB4D8F1690EQ38215119-49DA3877-581E-4A92-A343-2727AE003A41Q38410286-E89B287C-6EC5-494F-B0E5-F414A0D78AE9Q40606854-999A683F-36E5-4F3D-B042-2986E95495F8Q40620125-E12D2F02-F7AE-4225-93DD-8D3DB6DE4473Q40950915-AD26D792-D31A-4C15-8479-E69A715DF715Q41649461-327F26F3-F866-4F54-A888-3B9C57FFE7FCQ43147250-59CA536F-83B5-4911-8948-E3E9AAA18E7CQ43170407-47D90FF9-103B-4B3F-8CE8-B8E7DF014A73Q45060002-42836DDD-E6DE-4CE6-BA2E-E40C334B6EB7Q45992369-142F0FC4-FAFC-4A6A-B952-EEBFEB7F0A33Q46044061-1384BAE8-A520-40A3-9250-DF163DFFD880Q46103090-9639BE9C-858D-43F9-AB24-20FAE8A6F595Q46115686-8D8516B8-33D3-400D-8686-999B610FAEB4Q46122092-8E0C1282-617F-4C26-83A9-029EC109D659Q46242128-919D2A9C-01D6-4E75-9614-C9A964BDDDDFQ46337521-68BE0A2F-43C5-48CF-9835-30B0FE039C17Q46406420-BC9D28FD-AAD5-43E0-8D33-4B3959A83E39Q46679404-E32BFD59-40FB-49A7-85F7-6B7FAAC2E0A7Q48154331-ABDCAAC1-011A-48CD-B27B-5DCFF16DB7F6Q53614589-A42B4762-75EC-4005-8F33-04E00A77DAA1Q54775962-70EE9CB5-45C2-4C62-B159-D697BB55B91BQ57397666-EE576E54-8BBA-4C5F-8D6D-34C9C26602B1
P2860
Formation of cationic peptide radicals by gas-phase redox reactions with trivalent chromium, manganese, iron, and cobalt complexes.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh
2005年學術文章
@zh-hant
name
Formation of cationic peptide ...... e, iron, and cobalt complexes.
@en
Formation of cationic peptide ...... e, iron, and cobalt complexes.
@nl
type
label
Formation of cationic peptide ...... e, iron, and cobalt complexes.
@en
Formation of cationic peptide ...... e, iron, and cobalt complexes.
@nl
prefLabel
Formation of cationic peptide ...... e, iron, and cobalt complexes.
@en
Formation of cationic peptide ...... e, iron, and cobalt complexes.
@nl
P356
P1476
Formation of cationic peptide ...... se, iron, and cobalt complexes
@en
P2093
W David McFadyen
P304
P356
10.1021/JA043088F
P407
P577
2005-04-01T00:00:00Z