Efficient and directed peptide bond formation in the gas phase via ion/ion reactions

McGee, William M.; McLuckey, Scott A.

doi:10.1073/pnas.1317914111

Cited by 25 publications

(27 citation statements)

References 43 publications

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“…Formation of covalent bonds in gas-phase ion complexes has been reported for several systems that relied on collision-induced chemical reactions between an anion and a cation in a complex that mimicked chemical methods used in solution [23,24]. In addition, covalent bond formation in gasphase ion complexes with 18-crown-6-ether has been accomplished by collision-induced dissociation of diazomalonate derivatives [25] or photodissociation of a diazirine labeled peptide [26] in which reactive carbenes played the role of reactive intermediates.…”

Section: Introductionmentioning

confidence: 99%

Efficient Covalent Bond Formation in Gas-Phase Peptide–Peptide Ion Complexes with the Photoleucine Stapler

Shaffer

Andrikopoulos

Řezáč

et al. 2016

J. Am. Soc. Mass Spectrom.

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Abstract. Noncovalent complexes of hydrophobic peptides GLLLG and GLLLK with photoleucine (L*) tagged peptides G(L* n L m )K (n = 1,3, m = 2,0) were generated as singly charged ions in the gas phase and probed by photodissociation at 355 nm. Carbene intermediates produced by photodissociative loss of N 2 from the L* diazirine rings underwent insertion into X−H bonds of the target peptide moiety, forming covalent adducts with yields reaching 30%. Gas-phase sequencing of the covalent adducts revealed preferred bond formation at the C-terminal residue of the target peptide. Site-selective carbene insertion was achieved by placing the L* residue in different positions along the photopeptide chain, and the residues in the target peptide undergoing carbene insertion were identified by gas-phase ion sequencing that was aided by specific 13 C labeling. Density functional theory calculations indicated that noncovalent binding to GL*L*L*K resulted in substantial changes of the (GLLLK + H) + ground state conformation. The peptide moieties in [GL*L*LK + GLLLK + H] + ion complexes were held together by hydrogen bonds, whereas dispersion interactions of the nonpolar groups were only secondary in ground-state 0 K structures. Born-Oppenheimer molecular dynamics for 100 ps trajectories of several different conformers at the 310 K laboratory temperature showed that noncovalent complexes developed multiple, residue-specific contacts between the diazirine carbons and GLLLK residues. The calculations pointed to the substantial fluidity of the nonpolar side chains in the complexes. Diazirine photochemistry in combination with Born-Oppenheimer molecular dynamics is a promising tool for investigations of peptide-peptide ion interactions in the gas phase.

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Section: Introductionmentioning

confidence: 99%

Efficient Covalent Bond Formation in Gas-Phase Peptide–Peptide Ion Complexes with the Photoleucine Stapler

Shaffer

Andrikopoulos

Řezáč

et al. 2016

J. Am. Soc. Mass Spectrom.

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“…35 Benefits of this approach include significantly shorter reaction times, reduced chemical noise via mass selection of reactants, and control over the extent of modification. 35 Recent examples of covalent modification ion/ion reactions include the synthesis of peptide bonds via N -hydroxysuccinimide 36 and Woodward’s Reagent K 37 conjugation chemistry, “Click” chemistry reactions between alkynes and azides, 38 and esterification of carboxylate groups via alkyl cation transfer from fixed charge cation reagents. 39 …”

Section: Introductionmentioning

confidence: 99%

Selective Gas-Phase Oxidation and Localization of Alkylated Cysteine Residues in Polypeptide Ions via Ion/Ion Chemistry

2016

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The thiol group in cysteine residues is susceptible to several post-translational modifications (PTMs), including prenylation, nitrosylation, palmitoylation, and the formation of disulfide bonds. Additionally, cysteine residues involved in disulfide bonds are commonly reduced and alkylated prior to mass spectrometric analysis. Several of these cysteine modifications, specifically S-alkyl modifications, are susceptible to gas-phase oxidation via selective ion/ion reactions with periodate anions. Multiply protonated peptides containing modified cysteine residues undergo complex formation upon ion/ion reaction with periodate anions. Activation of the ion/ion complexes results in oxygen transfer from the reagent to the modified sulfur residue to create a sulfoxide functionality. Further activation of the sulfoxide derivative yields abundant losses of the modification with the oxidized sulfur as a sulfenic acid (namely, XSOH) to generate a dehydroalanine residue. This loss immediately indicates the presence of an S-alkyl cysteine residue, and the mass of the loss can be used to easily deduce the type of modification. An additional step of activation can be used to localize the modification to a specific residue within the peptide. Selective cleavage to create c- and z-ions N-terminal to the dehydroalanine residue is often noted. As these types of ions are not typically observed upon collision-induced dissociation (CID), they can be used to immediately indicate where in the peptide the PTM was originally located.

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“…Recent examples of these modifications include the esterification of carboxylate groups via cation transfer [ 14 ], gas-phase conjugation of alkynes and azides via ‘Click’ chemistry reactions [15], the N- and C-terminal extension of peptides via conjugation with N-hydroxysuccinimide esters [ 16 ] and Woodward’s Reagent K [ 17 ], respectively, and the conjugation of aldehydes and amines via gas-phase Schiff base chemistry [18,19,20,21,22]. Gas-phase ion/ion reactions have several benefits over traditional solution-phase derivatizations including much shorter reaction times (<1 sec), reduction of side reactions via mass isolation of reactants, and control over the extent of reaction (viz., amount of product formed and number of modifications that occur) [1].…”

Section: Introductionmentioning

confidence: 99%

Gas-Phase Oxidation of Neutral Basic Residues in Polypeptide Cations by Periodate

Pilo

McLuckey

2016

J. Am. Soc. Mass Spectrom.

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The gas-phase oxidation of doubly protonated peptides containing neutral basic residues to various products, including [M+H+O]+, [M-H]+, and [M-H-NH3]+, is demonstrated here via ion/ion reactions with periodate. It was previously demonstrated that periodate anions are capable of oxidizing disulfide bonds and methionine, tryptophan, and S-alkyl cysteine residues. However, in the absence of these easily oxidized sites, we show here that systems containing neutral basic residues can undergo oxidation. Furthermore, we show that these neutral basic residues primarily undergo different types of oxidation (e.g., hydrogen abstraction) reactions than those observed previously (i.e., oxygen transfer to yield the [M+H+O]+ species) upon gas-phase ion/ion reactions with periodate anions. This chemistry is illustrated with a variety of systems including a series of model peptides, a cell-penetrating peptide containing a large number of unprotonated basic sites, and ubiquitin, a roughly 8.6 kDa protein.

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Efficient and directed peptide bond formation in the gas phase via ion/ion reactions

Cited by 25 publications

References 43 publications

Efficient Covalent Bond Formation in Gas-Phase Peptide–Peptide Ion Complexes with the Photoleucine Stapler

Efficient Covalent Bond Formation in Gas-Phase Peptide–Peptide Ion Complexes with the Photoleucine Stapler

Selective Gas-Phase Oxidation and Localization of Alkylated Cysteine Residues in Polypeptide Ions via Ion/Ion Chemistry

Gas-Phase Oxidation of Neutral Basic Residues in Polypeptide Cations by Periodate

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