Fluorinated Sulfilimino Iminiums: Efficient and Versatile Sources of Perfluoroalkyl Radicals under Photoredox Catalysis.

Reported herein is the use of S-perfluoroalkyl sulfilimino iminiums as a new source of RF radicals under visible-light photoredox catalysis (RF =CF3 , C4 F9 , CF2 Br, CFCl2 ). These shelf-stable perfluoroalkyl reagents, readily prepared on gram scale from the corresponding sulfoxide using a one-pot procedure, allow the efficient photoredox-induced oxyperfluoroalkylation of various alkenes using fac-Ir(ppy)3 as the photocatalyst. Importantly, spin-trapping/electron paramagnetic resonance experiments were carried out to characterize all the radical intermediates involved in this radical/cationic process.

α-Phenyl-N-cyclohexyl Nitrones: Preparation and Use as Spin-Traps.

Two bifunctional α-phenyl-N-cyclohexyl nitrones were synthesized with the expectation that the cyclohexyl ring will impart lipophilicity to the molecule, high reactivity to the nitronyl group, and stability to the spin adducts formed. The synthesis of the acid nitrone 4 and its corresponding tert-butyl ester 3 was initiated by a Michael reaction to introduce the cyclohexyl ring. A Zn/AcOH-mediated reduction of the nitro functionality followed by condensation onto benzaldehyde generated the nitronyl function. In agreement with their high lipophilicity values, nitrone 3 was insoluble in water, while nitrone 4 exhibited a poor water solubility. It was determined that the presence of the cyclohexyl ring did not affect either the reduction or oxidation potentials of the nitronyl group in comparison to the classical α-phenyl-N-tert-butylnitrone (PBN). The spin trapping ability of 3 and 4 was investigated by EPR for oxygen- and carbon-centered radicals. In most cases, the nitrones gave rise to a standard six-line EPR spectrum whose values were in agreement with the literature, accompanied by a minor second species. In DMSO, the half-lives of nitrone 3 and 4-OOH adducts were double that of PBN, suggesting that the stabilization comes from the cyclohexyl ring and/or the electronic effect of the carboxylic acid.

Combining a NHS ester and glutaraldehyde improves crosslinking prior to MALDI MS analysis of intact protein complexes.

Protein complexes play pivotal roles in cellular life. Nevertheless, their characterization remains a substantial challenge. Mass spectrometry (MS) is an emerging tool to study protein assemblies, and electrospray ionization (ESI) is often used because it preserves non-covalent interactions. Matrix-assisted laser desorption/ionization (MALDI) represents an important alternative to ESI because it is more tolerant to salts and detergents (e.g. necessary in the case of membrane complex analyses). Prior to MALDI-MS, the subunits should be crosslinked (XLed). Moreover, crosslinking (XLing) is useful when constraint distances are determined to obtain low-resolution structural information. Here we report a novel XLing approach to study protein complexes with MALDI-MS. We investigated two tetramers (i.e. alcohol dehydrogenase and aldolase) larger than 140 kDa at two pH values (7.2 and 8.0). We tested two different crosslinkers (XLers) (i.e. BS(3) and glutaraldehyde), used separately or in combination. We utilized gentle agitation and ultracentrifugation. Our data shows that the pH influenced the XLing when using a single XLer. Combining two XLers was demonstrated to be more efficient than using a reagent alone. In particular, the combination determined a higher degree of XLing and lower mass shift. This could suggest a ranking in target amino acid availability. First residues at specific distances are linked by BS(3) , then glutaraldehyde binds residues that are still available at larger distances. Ultracentrifugation and gentle agitation both provide similar degrees of XLing, but the former method determined a lower mass increment resulting from redundant XLing. To conclude, we present an efficient dual XLing approach for determining mass and stoichiometry of protein assemblies.