A Two-Site Mechanism for ATP Hydrolysis by the Asymmetric Rep Dimer P2S As Revealed by Site-Specific Inhibition with ADP−AlF4

Abstract

The Escherichia coli Rep helicase is a dimeric motor protein that catalyzes the transient unwinding of duplex DNA to form single-stranded (ss) DNA using energy derived from the binding and hydrolysis of ATP. In an effort to understand this mechanism of energy transduction, we have used pre-steady-state methods to study the kinetics of ATP binding and hydrolysis by an important intermediate in the DNA unwinding reactionthe asymmetric Rep dimer state, P₂S, where ss DNA [dT(pT)₁₅] is bound to only one subunit of the Rep dimer. To differentiate between the two potential ATPase active sites inherent in the dimer, we constructed dimers with one subunit covalently cross-linked to ss DNA and where one or the other of the ATPase sites was selectively complexed to the tightly bound transition state analog ADP−AlF₄. We found that when ADP−AlF₄ is bound to the Rep subunit in trans from the subunit bound to ss DNA, steady-state ATPase activity of 18 s^-1 per dimer (equivalent to wild-type P₂S) was recovered. However, when the ADP−AlF₄ and ss DNA are both bound to the same subunit (cis), then a titratable burst of ATP hydrolysis is observed corresponding to a single turnover of ATP. Rapid chemical quenched-flow techniques were used to resolve the following minimal mechanism for ATP hydrolysis by the unligated Rep subunit of the cis dimer: E + ATP ⇄ E−ATP ⇄ E‘−ATP ⇄ E‘−ADP−P_i ⇄ E−ADP−P_i ⇄ E−ADP + P_i ⇄ E + ADP + P_i, with K₁ = (2.0 ± 0.85) × 10⁵ M^-1, k₂ = 22 ± 3.5 s^-1, k_-2 < 0.12 s^-1, K₃ = 4.0 ± 0.4 (k₃ > 200 s^-1), k₄ = 1.2 ± 0.14 s^-1, k_-4 << 1.2 s^-1, K₅ = 1.0 ± 0.2 mM, and K₆ = 80 ± 8 μM. A salient feature of this mechanism is the presence of a kinetically trapped long-lived tight nucleotide binding state, E‘-ADP−P_i. In the context of our “subunit switching” model for Rep dimer translocation during processive DNA unwinding [Bjornson, K. B., Wong, I., & Lohman, T. M. (1996) J. Mol. Biol.263, 411−422], this state may serve an energy storage function, allowing the energy from the binding and hydrolysis of ATP to be harnessed and held in reserve for DNA unwinding.