Synthetic Models for the Zinc Sites in the Methionine Synthases

Abstract

The syntheses and molecular structures of a series of tetrahedral zinc complexes designed to model the active sites in Escherichia coli methionine synthases are reported. [PhTt^tBu]ZnBr (PhTt^tBu = phenyltris((tert-butylthio)methyl)borate) was prepared and characterized crystallographically to provide entry into [S₃]ZnX complexes. Metathesis with KSPh yielded the phenylthiolato complex, [PhTt^tBu]Zn(SPh), which represents a structural mimic of the homocysteine ligated form of the enzyme. Alternatively, [S₂N]ZnX (X = Br, CH₃, SPh) species were prepared using the new mixed-donor ligands, [Ph(pz)Bt^tBu] (phenyl(pyrazolyl)bis((tert-butylthio)methyl)borate) and [Ph(pz^tBu)Bt^tBu] (phenyl(3-tert-butylpyrazolyl)bis((tert-butylthio)methyl)borate). Protonolysis of [Ph(pz^tBu)Bt^tBu]Zn(CH₃) by PhSH in toluene yielded [Ph(pz^tBu)Bt^tBu]Zn(SPh), a synthetic analogue of the homocysteine ligated form of cobalamin-independent methionine synthase (Met E). The average Zn−S bond distance in [Ph(pz^tBu)Bt^tBu]Zn(SPh) of 2.37 Å compares well with the EXAFS-derived distance of 2.31 Å found in the homocysteine-bound form of Met E.