Binding Kinetics and Footprinting of TaqI Endonuclease: Effects of Metal Cofactors on Sequence-Specific Interactions

Abstract

Restriction endonucleases achieve sequence-specific recognition and strand cleavage through the interplay of base, phosphate backbone, and metal cofactor interactions. In this study, we investigate the binding kinetics of TaqI endonuclease using the wild-type enzyme and a binding proficient, catalysis deficient mutant TaqI-D137A both in the absence of a metal cofactor and in the presence of Mg²⁺ or Ca²⁺. As demonstrated by gel mobility shift analyses, TaqI endonuclease requires a metal cofactor for achieving high-affinity specific binding to its cognate sequence, TCGA. In the absence of a metal cofactor, the enzyme binds all DNA sequences (TaqI cognate site, star site, and nonspecific site) with essentially equal affinity, thereby exhibiting little discrimination. The dissociation constant of the cognate sequence in the presence of Mg²⁺ at 60 °C is 0.26 nM, a value comparable to our previously reported K_m of 0.5 nM measured under steady-state conditions. The TaqI−TCGA−Mg²⁺ complex is stable, with a half-life of 21 min at 60 °C. The boundary of the protein−DNA interface is approximated to be about 18 bp as determined by DNase I footprinting. Data from this study support the notion that a metal cofactor plays a critical role for achieving sequence-specific discrimination in a subset of nucleases, including TaqI, EcoRV, and others.