Mechanisms of Interactions of the Nucleotide Cofactor with the RepA Protein of Plasmid RSF1010. Binding Dynamics Studied Using the Fluorescence Stopped-Flow Method

Abstract

The dynamics of the nucleotide binding to a single, noninteracting nucleotide-binding site of the hexameric helicase RepA protein of plasmid RSF1010 has been examined, using the fluorescence stopped-flow method. The experiments have been performed with fluorescent analogues of ATP and ADP, TNP-ATP and TNP-ADP, respectively. In the presence of Mg(2+), the association of the cofactors proceeds as a sequential three-step process [Formula: see text] The sequential nature of the mechanism indicates the lack of significant conformational equilibria of the helicase prior to nucleotide binding. The major conformational change of the RepA helicase-nucleotide complex occurs in the formation of (H-N)(2), which is characterized by a very high value of the partial equilibrium constant and large positive changes in the apparent enthalpy and entropy. Strong stabilizing interactions between subunits of the RepA hexamer contribute to the observed dynamics and energetics of the internal transitions of the formed complexes. Magnesium cations mediate the efficient and fast conformational transitions of the protein, in a manner independent of the structure of the cofactor phosphate group. The ssDNA bound to the enzyme preferentially selects a single intermediate of the RepA-ATP analogue complex, (H-N)(2), while the DNA has no effect on the intermediates of the RepA-ADP complex. Allosteric interactions between the nucleotide- and DNA-binding site are established in the initial stages of formation of the complex. Moreover, in the presence of the single-stranded DNA, all the transitions in the nucleotide binding to the helicase become sensitive to the structure of the phosphate group of the cofactor.