DNA cleavage by the EcoRV restriction endonuclease: roles of divalent metal ions in specificity and catalysis.

The roles of divalent metal ions in DNA cleavage by the EcoRV endonuclease were studied by using Co2+ or Mn2+ as substitutes for the natural cofactor Mg2+. In steady-state experiments with a 12 bp oligonucleotide substrate, Co2+ yielded a similar turnover rate to that with Mg2+, but Mn2+ gave a slower rate. Single turnovers of EcoRV on this substrate were analysed by stopped-flow and quench-flow methods, to determine the rates for the formation of the ternary enzyme-DNA-metal complex, the hydrolysis of the phosphodiester bonds and the dissociation of the cleaved DNA. With Co2+, all three steps had similar rates to those with Mg2+. In contrast, Mn2+ gave a faster rate for phosphodiester hydrolysis than either Mg2+ or Co2+, but a slower rate for product dissociation, thus accounting for its low turnover rate. Single turnovers on plasmids also yielded faster rates for substrate hydrolysis with Mn2+ compared to Mg2+ and Co2+. Since Mn2+ gave the most rapid rates for the hydrolytic step, despite being less electronegative than Co2+, the function of the metal ion at the active site of EcoRV cannot be just the polarisation of the scissile phosphate. Moreover, the minimal scheme for the Co2+-catalysed reaction requires two metal ions for DNA cleavage. The metal ions seem to be involved in the precise positioning of both the substrate and the water that acts as the attacking nucleophile and in activating that water molecule. A model is presented to account for how two metal ions might fulfil these functions.

Reactions of the eco RV restriction endonuclease with fluorescent oligodeoxynucleotides: identical equilibrium constants for binding to specific and non-specific DNA.

The EcoRV restriction endonuclease cleaves DNA specifically at its recognition sequence in the presence of magnesium ions, but several studies have indicated that it binds to DNA in the absence of Mg2+ without any preference for its recognition site. However, specific binding to the recognition site has also been reported. To distinguish between these reports, oligodeoxynucleotides were tagged with either dansyl or eosin fluorophores at their 5' termini and annealed to form duplexes of 12 to 16 base-pairs. For each length of duplex, one derivative had the EcoRV recognition sequence while another lacked this sequence. For the duplexes with the recognition site, the fluorophores had no effect on DNA cleavage rates by EcoRV in the presence of Mg2+. The binding of the specific and non-specific duplexes to EcoRV in the absence of Mg2+ was measured by fluorescence resonance energy transfer and by fluorescence depolarization. In both procedures, the signal from the specific complex differed from the complex with non-specific DNA, with the depolarization data indicating that non-specific DNA bound to EcoRV retains a higher rotational freedom than specific DNA. Even so, the equilibrium constant for the binding of specific DNA was identical, within error limits, to that for non-specific DNA.

Rapid-reaction analysis of plasmid DNA cleavage by the EcoRV restriction endonuclease.

Rapid-reaction methods have been used previously to identify intermediates in the reaction of the EcoRV restriction endonuclease on oligonucleotide substrates. In this study, the pathway on macromolecular DNA was elucidated by using the quench-flow method to analyze EcoRV reactions on a plasmid with one recognition site. Some reactions were carried out by first allowing the EcoRV enzyme to bind nonspecifically to the DNA and then initiating DNA cleavage by adding magnesium ions. The subsequent transfer of the enzyme from nonspecific to specific sites was extremely rapid, at a random walk rate of at least 5 x 10(5) base pairs per second. The two strands of the DNA at the EcoRV recognition site were then cleaved sequentially, at rates that were faster than the turnover number of the enzyme. The rates recorded for the cleavage steps were direct measurements of phosphodiester hydrolysis, while the turnover is limited by the dissociation of the product cleaved in both strands. Other reactions were initiated by adding EcoRV and MgCl2 to the DNA: these revealed not only the processes observed in reactions starting from DNA-bound enzyme but also the bimolecular association of the protein with the plasmid. The association rate was limited by diffusion but its rate constant, 1.2 x 10(8) M(-1) s(-1), was unusually small for the binding of a protein to DNA. The slowness of this diffusion-controlled process may be due to a rapid oscillation of the protein between closed and open conformations, with only the open form capable of binding DNA.

A general assay for restriction endonucleases and other DNA-modifying enzymes with plasmid substrates.

A procedure for measuring the activities of enzymes that alter the covalent structure of DNA is described. The assay utilizes covalently closed circles of DNA as the substrate and yields quantitative data on the fraction of this DNA converted to both open-circle and linear forms.

Interactions of the EcoRV restriction endonuclease with fluorescent oligodeoxynucleotides.

A self-complementary dodecadeoxyribonucleotide that contains the recognition sequence for the R.EcoRV ENase was synthesised with a primary amino group at its 5' terminus. The 5' amino function was labeled with the fluorescent dye 5-[dimethylamino] napthalene-1-sulfonyl chloride. The labeled oligodeoxyribonucleotide in its duplex form was shown to be a suitable substrate for kinetic studies on the ENase and that no significant dye-DNA or dye-protein interactions occurred. Finally, the binding of R.EcoRV to the labeled DNA was followed by detecting the fluorescence resonance energy transfer between the tryptophans of the protein and the fluorescent labels of the DNA.