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How PspGI, catalytic domain of EcoRII and Ecl18kI acquire specificities for different DNA targets

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Bochtler,  Matthias
Max Planck Institute of Molecular Cell Biology and Genetics, Max Planck Society;

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Citation

Tamulaitis, G., Zaremba, M., Szczepanowski, R. H., Bochtler, M., & Siksnys, V. (2008). How PspGI, catalytic domain of EcoRII and Ecl18kI acquire specificities for different DNA targets. Nucleic Acids Research, 36(19), 6101-6108.


Cite as: https://hdl.handle.net/21.11116/0000-0001-0E26-6
Abstract
Restriction endonucleases Ecl18kI and PspGI/catalytic domain of EcoRII recognize CCNGG and CCWGG sequences (W stands for A or T), respectively. The enzymes are structurally similar, interact identically with the palindromic CC:GG parts of their recognition sequences and flip the nucleotides at their centers. Specificity for the central nucleotides could be influenced by the strength/stability of the base pair to be disrupted and/or by direct interactions of the enzymes with the flipped bases. Here, we address the importance of these contributions. We demonstrate that wt Ecl18kI cleaves oligoduplexes containing canonical, mismatched and abasic sites in the central position of its target sequence CCNGG with equal efficiencies. In contrast, substitutions in the binding pocket for the extrahelical base alter the Ecl18kI preference for the target site: the W61Y mutant prefers only certain mismatched substrates, and the W61A variant cuts exclusively at abasic sites, suggesting that pocket interactions play a major role in base discrimination. PspGI and catalytic domain of EcoRII probe the stability of the central base pair and the identity of the flipped bases in the pockets. This 'double check' mechanism explains their extraordinary specificity for an A/T pair in the flipping position.