Comparative Analysis of Bacterial Cytochromes P450 Involved in the Biosynthesis of 16‐ Membered Ring Macrolide Antibiotics

Abstract

Members of the cytochrome P450 superfamily of monooxygenases (P450s) are some of nature's most ubiquitous and versatile enzymes for performing oxidative metabolic transformations. Their unmatched ability to selectively functionalize C–H bonds has led to their growing employment in academic and industrial settings for the production of fine and commodity chemicals. Many of the most interesting and potentially biocatalytically useful P450s come from microorganisms, where they catalyze key tailoring reactions in natural product biosynthetic pathways. While most of these enzymes act on structurally complex pathway intermediates with high selectivity, they often exhibit narrow substrate scope, thus limiting their broader application. In the present work, we biochemically and structurally characterized diverse bacterial P450s involved in the biosynthesis of 16-membered ring macrolide antibiotics with significant potential for development into robust biocatalysts for the late-stage functionalization of complex molecules. Following exploratory efforts to probe the reactivity properties of the P450 MycCI from the mycinamicin biosynthetic pathway, we discovered that the enzyme exhibits appreciable activity on several 16-membered ring macrolactones independent of their glycosylation state. These results were corroborated by performing equilibrium substrate binding and kinetics experiments along with X-ray crystallographic analysis of MycCI bound to its native substrate. We also characterized TylHI, a homologous P450 from the tylosin pathway, and showed that its substrate scope is severely restricted compared with that of MycCI. Turnover and equilibrium binding experiments with substrate analogs revealed that TylHI exhibits a strict preference for 16-membered ring macrolides bearing the deoxyamino sugar mycaminose. These results were partially explained through analysis of the X-ray crystal structure of TylHI in complex with its native substrate together with biochemical characterization of several sitedirected mutants. Comparative analysis of the MycCI/TylHI homolog ChmHI from the chalcomycin biosynthetic pathway provided a basis for constructing MycCI/TylHI chimeras in order to gain further insight into the features dictating the differences in the reactivity profiles of these two related P450s. These experiments unveiled the central role of the BC loop region in influencing the binding of 16-membered ring substrates to MycCI and TylHI. Overall, our studies have shed light on the molecular-level details underpinning the unique catalytic divergence of two homologous biosynthetic P450s and point toward specific regions in each protein that may be targeted in future efforts to rationally engineer novel P450-based biocatalysts. Support or Funding Information NSF under the CCI Center for Selective C–H Functionalization (CHE-1205646 and CHE-1700982), NIH (R01-GM078553, R35-GM118101, and T32-GM008353), University of Michigan Rackham Predoctoral Fellowship Physiological reactions catalyzed by P450s MycCI and TylHI in their respective biosynthetic pathways. This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.