Substrate-dependent allosteric regulation by switchable catalytic molecular tweezers

• Published in: Communications chemistry Vol. 2; no. 1
• Main Authors: Benda, Lorien, Doistau, Benjamin, Rossi-Gendron, Caroline, Chamoreau, Lise-Marie, Hasenknopf, Bernold, Vives, Guillaume
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 20.12.2019; Nature Publishing Group; Nature Research
• Subjects: 639/638/541; 639/638/77; 639/638/911; Acetylation; Bimetals; Binding sites; Catalysts; Catalytic activity; Chemical Sciences; Chemistry; Chemistry and Materials Science; Chemistry/Food Science; Closed form solutions; Deactivation; Exact solutions; Isomers; Lewis acid; Mathematical analysis; Reagents; Selectivity; Substrate inhibition; Zinc; Coordination chemistry; Catalysis; Supramolecular chemistry
• ISSN: 2399-3669; 2399-3669
• DOI: 10.1038/s42004-019-0246-9

Allosteric regulation is exploited by biological systems to regulate the activity and/or selectivity of enzymatic reactions but remains a challenge for artificial catalysts. Here we report switchable terpy(Zn-salphen) 2 molecular tweezers and their metal-dependent allosteric regulation of the acetylation of pyridinemethanol isomers. Zinc-salphen moieties can both act as a Lewis acid to activate the anhydride reagents and provide a binding site for pyridinemethanol substrates. The tweezers’ conformation can be reversibly switched between an open and a closed form by a metal ion stimulus. Both states offer distinct catalytic profiles, with closed tweezers showing superior catalytic activity towards ortho substrates, while open tweezers presenting higher rate for the acetylation of meta and para substrates. This notable substrate dependent allosteric response is rationalized by a combination of experimental results and calculations supporting a bimetallic reaction in the closed form for ortho substrate and an inhibition of the cavity for meta and para substrates. ‘Molecular tweezers' offer a powerful design strategy for catalysts that can be activated or deactivated by conformational change. Here this design is extended to allow a regioselective allosteric effect upon binding of zinc ions.