The Effect of Selenium-Based Ligands on Tungsten Acetylene Complexes.

Bioinspired tungsten acetylene complexes containing pyridine-2-selenolato (PySe) or 6-methyl-pyridine-2-selenolato (6-MePySe) ligands were synthesized. Se NMR spectroscopy allowed for an assessment of the resonance structures in the pyridine-2-selenolato ligands and the rationalization of chemoselectivity observed in regard to 1,2 migratory insertion of HC≡CH. [W(CO)(CH)(CHCH-PySe)(PySe)] is formed exclusively via insertion of HC≡CH into the W-N bond, while the use of bulkier 6-MePySe allows for the isolation of [W(CO)(CH)(6-MePySe)], which only partially reacts with excess HC≡CH to give [W(CO)(CH)(CHCH-6-MePySe)(6-MePySe)]. Oxidation of [W(CO)(CH)(6-MePySe)] with pyridine--oxide gave the tungsten(IV) complex [WO(CH)(6-MePySe)]. Complexes [W(CO)(CH)(6-MePySe)] and [WO(CH)(6-MePySe)] react with trimethyl phosphine to carbyne complex [W(CO)(CCHPMe)(PMe)(6-MePySe)]Cl and alkylidene complex [WO(CHCHPMe)(PMe)(6-MePySe)]Cl, respectively. The addition of substituted alkynes to [W(CO)(PySe)] via thermal decarbonylation gave complexes [W(CO)(MeC≡CMe)(PySe)] and [W(CO)(HC≡C-Bu)(PySe)], respectively. The here presented complexes are relevant for the modeling of the active site of acetylene hydratase from , in which a tungsten atom is enclosed in a sulfur-rich coordination sphere. A recently published theoretical study concluded that the exchange of sulfur for selenium would increase the activity of the enzyme. Our findings contrast this claim as comparative analysis concludes negligible structural and electronic differences between the selenium-based and previously published sulfur-based complexes.