Robert Sharp scite author profile

Serine integrases catalyze the integration of bacteriophage DNA into a host genome by site-specific recombination between ‘attachment sites’ in the phage (attP) and the host (attB). The reaction is highly directional; the reverse excision reaction between the product attL and attR sites does not occur in the absence of a phage-encoded factor, nor does recombination occur between other pairings of attachment sites. A mechanistic understanding of how these enzymes achieve site-selectivity and directionality has been limited by a lack of structural models. Here, we report the structure of the C-terminal domains of a serine integrase bound to an attP DNA half-site. The structure leads directly to models for understanding how the integrase-bound attP and attB sites differ, why these enzymes preferentially form attP × attB synaptic complexes to initiate recombination, and how attL × attR recombination is prevented. In these models, different domain organizations on attP vs. attB half-sites allow attachment-site specific interactions to form between integrase subunits via an unusual protruding coiled-coil motif. These interactions are used to preferentially synapse integrase-bound attP and attB and inhibit synapsis of integrase-bound attL and attR. The results provide a structural framework for understanding, testing and engineering serine integrase function.

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Requirements for catalysis in the Cre recombinase active site

Gibb

Gupta

Ghosh

et al. 2010

102

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Members of the tyrosine recombinase (YR) family of site-specific recombinases catalyze DNA rearrangements using phosphoryl transfer chemistry that is identical to that used by the type IB topoisomerases (TopIBs). To better understand the requirements for YR catalysis and the relationship between the YRs and the TopIBs, we have analyzed the in vivo and in vitro recombination activities of all substitutions of the seven active site residues in Cre recombinase. We have also determined the structure of a vanadate transition state mimic for the Cre–loxP reaction that facilitates interpretation of mutant activities and allows for a comparison with similar structures from the related topoisomerases. We find that active site residues shared by the TopIBs are most sensitive to substitution. Only two, the tyrosine nucleophile and a conserved lysine residue that activates the 5′-hydroxyl leaving group, are strictly required to achieve >5% of wild-type activity. The two conserved arginine residues each tolerate one substitution that results in modest recombination activity and the remaining three active site positions can be substituted with several alternative amino acids while retaining a significant amount of activity. The results are discussed in the context of YR and TopIB structural models and data from related YR systems.

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Robert Sharp

Attachment site recognition and regulation of directionality by the serine integrases

Requirements for catalysis in the Cre recombinase active site

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