Your search keyword '"Stix N"' showing total 2 results

1. Nucleophiles Target the Tungsten Center Over Acetylene in Biomimetic Models.

Author

Ćorović MZ, Milinkovic A, Stix N, Dupé A, and Mösch-Zanetti NC

Abstract

Inspired by the first shell mechanism proposed for the tungstoenzyme acetylene hydratase, the electrophilic reactivity of tungsten-acetylene complexes [W(CO)(C 2 H 2 )(6-MePyS) 2 ] ( 1 ) and [WO(C 2 H 2 )(6-MePyS) 2 ] ( 2 ) was investigated. The biological nucleophile water/hydroxide and tert -butyl isocyanide were employed. Our findings consistently show that, regardless of the nucleophile used, both tungsten centers W(II) and W(IV), respectively, are the preferred targets over the coordinated acetylene. Treatment of 2 with aqueous NaOH led to protonation of coordinated acetylene to ethylene, pointing toward the Brønsted basic character of the coordinated alkyne instead of the anticipated electrophilic behavior. In cases involving isocyanides as nucleophiles, the attack on the W(II) center of 1 took place first, whereas the W(IV) complex 2 remained unchanged. These experiments indicate that the direct nucleophilic attack of W-coordinated acetylene by water, as some computational studies of acetylene hydratase propose, is unlikely to occur.

Published

2024

2. Biocatalytic Heteroaromatic Amide Formation in Water Enabled by a Catalytic Tetrad and Two Access Tunnels.

Author

Zukic E, Mokos D, Weber M, Stix N, Ditrich K, Ferrario V, Müller H, Willrodt C, Gruber K, Daniel B, and Kroutil W

Abstract

The amide moiety belongs to the most common motives in pharmaceutical chemistry, present in many prescribed small-molecule pharmaceuticals. Methods for its manufacture are still in high demand, especially using water/buffer as a solvent and avoiding stoichiometric amounts of activation reagents. Herein, we identified from a library of lipases/esterases/acyltransferases and variants thereof a lipase originating from Sphingomonas sp. HXN-200 (SpL) able to form amides in aqueous solution starting from a broad scope of sterically demanding heteroaromatic ethyl esters as well as aliphatic amines, reaching isolated yields up to 99% on preparative scale and space time yields of up to 864 g L -1 d -1 ; thus, in selected cases, the amide was formed within minutes. The enzyme features an aspartate next to the canonical serine of the catalytic triad, which was essential for amide formation. Furthermore, the enzyme structure revealed two tunnels to the active site, presumably one for the ester and one for the amine, which permit the bringing together of the sterically demanding heteroaromatic esters and the amine in the active site. This work shows that biocatalytic amide formation starting from various five- and six-membered heteroaromatic ethyl esters in the buffer can serve as a platform for preparative amide synthesis., Competing Interests: The authors declare the following competing financial interest(s): E.Z., V.F., C.W. and W.K. are co-authors of a filed patent on amide formation., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024