Insights into the catalytic mechanism of Grimontia hollisae collagenase through structural and mutational analyses.

Grimontia hollisae collagenase (Ghcol) exhibits high collagen-degrading activity. To explore its catalytic mechanism, its substrate (Gly-Pro-Hyp-Gly-Pro-Hyp, GPOGPO)-complexed crystal structure was determined at 2.0 Å resolution. A water molecule was observed near the active-site zinc ion. Since this water was not observed in the product (GPO)-complexed Ghcol, it was hypothesized that the GPOGPO-complexed Ghcol structure reflects a Michaelis complex, providing a structural basis for understanding the catalytic mechanism. Analyses of the active-site geometry and site-directed mutagenesis of the active-site tyrosine residues revealed that Glu493 and Tyr564 were essential for catalysis, suggesting that Glu493 functions as an acid and base catalyst while Tyr564 stabilizes the tetrahedral complex in the transition state. These results shed light on the catalytic mechanism of bacterial collagenase.

Crystal structure of Grimontia hollisae collagenase provides insights into its novel substrate specificity toward collagen.

Collagenase from the gram-negative bacterium Grimontia hollisae strain 1706B (Ghcol) degrades collagen more efficiently even than clostridial collagenase, the most widely used industrial collagenase. However, the structural determinants facilitating this efficiency are unclear. Here, we report the crystal structures of ligand-free and Gly-Pro-hydroxyproline (Hyp)-complexed Ghcol at 2.2 and 2.4 Å resolution, respectively. These structures revealed that the activator and peptidase domains in Ghcol form a saddle-shaped structure with one zinc ion and four calcium ions. In addition, the activator domain comprises two homologous subdomains, whereas zinc-bound water was observed in the ligand-free Ghcol. In the ligand-complexed Ghcol, we found two Gly-Pro-Hyp molecules, each bind at the active site and at two surfaces on the duplicate subdomains of the activator domain facing the active site, and the nucleophilic water is replaced by the carboxyl oxygen of Hyp at the P1 position. Furthermore, all Gly-Pro-Hyp molecules bound to Ghcol have almost the same conformation as Pro-Pro-Gly motif in model collagen (Pro-Pro-Gly)10, suggesting these three sites contribute to the unwinding of the collagen triple helix. A comparison of activities revealed that Ghcol exhibits broader substrate specificity than clostridial collagenase at the P2 and P2' positions, which may be attributed to the larger space available for substrate binding at the S2 and S2' sites in Ghcol. Analysis of variants of three active-site Tyr residues revealed that mutation of Tyr564 affected catalysis, whereas mutation of Tyr476 or Tyr555 affected substrate recognition. These results provide insights into the substrate specificity and mechanism of G. hollisae collagenase.