The base excision repair enzyme thymine DNA glycosylase (TDG) protects against mutations by removing thymine or uracil from guanine mispairs and functions in active DNA demethylation by excising 5-formylcytosine (fC) and 5-carboxylcytosine (caC). Post-translational modification of TDG by SUMO (small ubiquitin-like modifier) reduces its glycosylase activity but the mechanism remains unclear. We investigated this problem using biochemical and biophysical approaches and a TDG construct comprising residues 82-340 (of 410) that includes the SUMOylation site and the motif for non-covalent SUMO binding. Single turnover kinetics experiments were collected at multiple enzyme concentrations ([E]) and the hyperbolic dependence of activity (kobs) on [E] yielded the maximal glycosylase activity (kmax), the enzyme concentration giving half-maximal activity (K0.5), and the catalytic efficiency (kmax/K0.5). Sumoylation of TDG (or TDG82-340) causes large reductions in catalytic efficiency for G·T, G·U, G·fC, and G·caC DNA substrates, due largely to weakened substrate affinity (increased K0.5). 19F NMR experiments show that sumoylation of TDG82-340 reduces productive binding to G·U mispairs and dramatically impairs binding to G·T mispairs. A mutation in the TDG SUMO-interacting motif (SIM), E310Q, shown previously to perturb noncovalent binding of SUMO to unmodified TDG, rescues the glycosylase activity of sumoylated TDG82-340. Similarly, NMR studies show the mutation restores productive binding of sumoylated TDG82-340 to G·U and G·T pairs. Together, the results indicate that intramolecular SUMO-SIM interactions mediate the adverse effect of sumoylation on TDG activity and suggest a model whereby the disruption of SUMO-SIM interactions enables productive binding of sumoylated TDG to substrate sites in DNA.
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