Probing d- and l-Adrenaline Binding to β2-Adrenoreceptor Peptide Motifs by Gas-Phase Photodissociation Cross-Linking and Ion Mobility Mass Spectrometry

Nitrile Imines as Peptide and Oligonucleotide Photo-Cross-Linkers in Gas-Phase Ions

Nitrile imines produced by photodissociation of 2,5-diaryltetrazoles undergo cross-linking reactions with amide groups in peptide-tetrazole (tet-peptide) conjugates and a tet-peptide-dinucleotide complex. Tetrazole photodissociation in gas-phase ions is efficient, achieving ca. 50% conversion with 2 laser pulses at 250 nm. The formation of cross-links was detected by CID-MS3 that showed structure-significant dissociations by loss of side-chain groups and internal peptide segments. The structure and composition of cross-linking products were established by a combination of UV-vis action spectroscopy and cyclic ion mobility mass spectrometry (c-IMS). The experimental absorption bands were found to match the bands calculated for vibronic absorption spectra of nitrile imines and cross-linked hydrazone isomers. The calculated collision cross sections (CCSth) for these ions were related to the matching experimental CCSexp from multipass c-IMS measurements. Loss of N2 from tet-peptide conjugates was calculated to be a mildly endothermic reaction with ΔH0 = 80 kJ mol-1 in the gas phase. The excess energy in the photolytically formed nitrile imine is thought to drive endothermic proton transfer, followed by exothermic cyclization to a sterically accessible peptide amide group. The exothermic nitrile imine reaction with peptide amides is promoted by proton transfer and may involve an initial [3 + 2] cycloaddition followed by cleavage of the oxadiazole intermediate. Nucleophilic groups, such as cysteine thiol, did not compete with the amide cyclization. Nitrile imine cross-linking to 2'-deoxycytidylguanosine was found to be >80% efficient and highly specific in targeting guanine. The further potential for exploring nitrile-imine cross-linking for biomolecular structure analysis is discussed.

Covalent crosslinking in gas-phase biomolecular ions. An account and perspective

Photochemical crosslinking in gas-phase ion complexes has been introduced as a method to study biomolecular structures and dynamics. Emphasis has been on carbene-based crosslinking induced by photodissociation of diazirine-tagged ions. The features that characterize gas-phase crosslinking include (1) complex formation in electrospray droplets that allows for library-type screening; (2) well defined stoichiometry of the complexes due to mass-selective isolation; (3) facile reaction monitoring and yield determination, and (4) post-crosslinking structure analysis by tandem mass spectrometry that has been combined with hydrogen-deuterium exchange, UV-vis action spectroscopy, and ion mobility measurements. In this account, examples are given of peptide-peptide, peptide-nucleotide, and peptide-ligand crosslinking that chiefly used carbene-based reactions. The pros and cons of gas-phase crosslinking are discussed. Nitrile-imine based crosslinking in gas-phase ions is introduced as a promising new approach to ion structure analysis that offers high efficiency and has the potential for wide ranging applications.

Carbene Cross-Linking in Gas-Phase Peptide Ion Scaffolds

Scaffolds consisting of a peptide, a phthalate linker, and a 4,4-azipentyl group were synthesized and used to study intramolecular peptide-carbene cross-linking in gas-phase cations. Carbene intermediates were generated by UV-laser photodissociation at 355 nm of the diazirine ring in mass-selected ions, and the cross-linked products were detected and quantified by collision-induced dissociation tandem mass spectrometry (CID-MSⁿ, n = 3-5). Peptide scaffolds containing Ala and Leu residues with a C-terminal Gly gave 21-26% yields of cross-linked products, while the presence of the Pro and His residues decreased the yields. Experiments using hydrogen-deuterium-hydrogen exchange, carboxyl group blocking, and analysis of CID-MSⁿ spectra of reference synthetic products revealed that a significant fraction of cross-links involved the Gly amide and carboxyl groups. Interpretation of the cross-linking results was aided by Born-Oppenheimer molecular dynamics (BOMD) and density functional theory calculations that allowed us to establish the protonation sites and conformations of the precursor ions. Analysis of long (100 ps) BOMD trajectories was used to count close contacts between the incipient carbene and peptide atoms, and the counting statistics was correlated with the results of gas-phase cross-linking.

Exploiting Self-Association to Evaluate Enantiomeric Composition by Cyclic Ion Mobility–Mass Spectrometry

The characterization of enantiomers is an important analytical challenge in the chemical and life sciences. Thorough evaluation of the purity of chiral molecules is particularly required in the pharmaceutical industry where safety concerns are paramount. Assessment of the enantiomeric composition is still challenging and time-consuming, meaning that alternative approaches are required. In this study, we exploit the formation of dimers as diastereomeric pairs of enantiomers to affect separation by high resolution cyclic ion mobility–mass spectrometry. Using the example of (R/S)-thalidomide, we show that even though this is not an enantiomer separation, we can determine which enantiomer is in excess and obtain quantitative information on the enantiomer composition without the need for a chiral modifier. Further examples of the approach are presented, including d/l-tryptophan and (R/S)-propanolol, and demonstrate the need for mobility resolving power in excess of 400 (CCS/ΔCCS).