Divalent metal ions at the active sites of the EcoRV and EcoRI restriction endonucleases

Influence of the phosphate backbone on the recognition and hydrolysis of DNA by the EcoRV restriction endonuclease. A study using oligodeoxynucleotide phosphorothioates

A set of phosphorothioate-containing oligonucleotides based on pGACGATATCGTC, a self-complementary dodecamer that contains the EcoRV recognition sequence (GATATC), has been prepared. The phosphorothioate group has been individually introduced at the central nine phosphate positions and the two diastereomers produced at each site separated and purified. The Km and Vmax values found for each of these modified DNA molecules with the EcoRV restriction endonuclease have been determined and compared with those seen for the unmodified all-phosphate-containing dodecamer. This has enabled an evaluation of the roles that both of the non-esterified oxygen atoms in the individual phosphates play in DNA binding and hydrolysis by the endonuclease. The results have also been compared with crystal structures of the EcoRV endonuclease, complexed with an oligodeoxynucleotide, to allow further definition of phosphate group function during substrate binding and turnover. For further study, see the related article "Probing the Indirect Readout of the Restriction Enzyme EcoRV: Mutational Analysis of Contacts to the DNA Backbone" (Wenz, A., Jeltsch, A., and Pingoud, A. (1996) J. Biol. Chem. 271, 5565-5573).

Asp-59 is not important for the catalytic activity of the restriction endonuclease EcoRI

The amino acid Asp-59 was proposed to be involved in EcoRI catalyzed DNA cleavage (Cheng et al., EMBO J. 13, 3927-35, 1994). We have tested this hypothesis by site directed mutagenesis experiments. The four mutants D59A, D59E, D59G, and D59N bind with similar stability to the specific recognition sequence as wild type EcoRI. The D59E mutant cleaves DNA as fast as the wild type enzyme. Specific activities of the other three mutants are five to tenfold lower. Therefore, we conclude that Asp-59 is not involved in catalysis of the EcoRI restriction endonuclease. Consequences for catalytic mechanisms of EcoRI and other restriction enzymes are discussed.

The EcoRV modification methylase causes considerable bending of DNA upon binding to its recognition sequence GATATC

The EcoRV methyltransferase modifies DNA by the introduction of a methyl group at the 6-NH2 position of the first deoxyadenosine in GATATC sequences. The enzyme forms a stable and specific complex with GATATC sequences in the presence of a nonreactive analogue, such as sinefungin, of its natural cofactor S-adenosyl-L-methionine. Using circular permutation band mobility shift analysis (in which the distance between the GATATC sequence and the end of the DNA is varied) of protein-DNA-cofactor complexes we have shown the methylase induces a bend of just over 60 degrees in the bound DNA. This was confirmed by phasing analysis, in which the spacing between the GATATC site and a poly(dA) tract is varied through a helical turn, which showed that the orientation of the induced curve was toward the major groove. There was no significant difference in the bend angle measured using unmethylated GATATC sequences and hemimethylated sequences which contain G6-Me ATATC in one strand only. These are the natural substates for the enzyme. The EcoRV endonuclease, a very well characterized protein, served as a positive control. DNA bending by this protein has been previously determined both by crystallographic and solution methods. The two proteins bend DNA toward the major groove but the bend angle produced by the methylase, slightly greater than 60 degree, is a little larger than that observed with the endonuclease, which is approximately 44 degrees.

Site-directed mutagenesis in the catalytic center of the restriction endonuclease EcoRI

The catalytic center of the restriction endonuclease (ENase) EcoRI is structurally homologous to that of EcoRV, BamHI and PvuII. Each of these ENases contains a short motif of three to four amino acid (aa) residues which are positioned in a similar orientation to the scissile phosphodiester bond. We have mutated these aa (Pro90, Asp91, Glu111 and Lys113) in EcoRI to determine their individual roles in catalysis. The replacement of Asp91 and Lys113, respectively, by conservative mutations (Ala91, Asn91, Ala113, Gln113, His113 and Leu113) resulted in a reduction of binding affinity and complete loss of cleavage activity. Only Lys113-->Arg substitution still allows to cleave DNA, albeit with a rate reduced by at least four orders of magnitude. Lys113 seems to stabilize the structure of the wild-type (wt) ENase since all five ENase variants with mutations at this position show a strongly enhanced tendency to aggregate. The Ala and Gln mutants of Glu111 bind the recognition sequence slightly stronger than wt EcoRI and cleave it with a low, but detectable rate. Only the Glu111-->Lys mutant, in which the charge is reversed, shows neither binding nor cleavage activity. Pro90 is not important for catalysis, because the Ala90 mutant cleaves DNA with an only slightly reduced rate. Under star conditions, however, this mutant is even more active than wt EcoRI. Therefore, the charged aa Asp91, Glu111 and Lys113 are essential for catalytic activity of the EcoRI ENase.(ABSTRACT TRUNCATED AT 250 WORDS)