Resolving the contributions of two cooperative mechanisms to the DNA binding of AGT

The O(6)-alkylguanine DNA alkyltransferase (AGT) is a DNA repair enzyme that binds DNA with moderate cooperativity. This cooperativity is important for its search for alkylated bases. A structural model of the cooperative complex of AGT with DNA predicts short-range interactions between nearest protein neighbors and long-range interactions between proteins separated in the array. DNA substrates ranging from 11bp to 30bp allowed us to use differences in binding stoichiometry to resolve short- and long-range protein contributions to the stability of AGT complexes. We found that the short-range component of ΔG°(coop) was nearly independent of DNA length and protein packing density. In contrast the long-range component oscillated with DNA length, with a period equal to the occluded binding site size (4bp). The amplitude of the long-range component decayed from ∼-4 kcal/mole of interaction to ∼-1.2 kcal/mol of interaction as the size of cooperative unit increased from 4 to 7 proteins, suggesting a mechanism to limit the size of cooperative clusters. These features allow us to make testable predictions about AGT distributions and interactions with chromatin structures in vivo.