OleP is a bacterial cytochrome P450 involved in oleandomycin biosynthesis as it catalyzes regioselective epoxidation on macrolide intermediates. OleP has recently been reported to convert lithocholic acid (LCA) into murideoxycholic acid through a highly regioselective reaction and to unspecifically hydroxylate testosterone (TES). Since LCA and TES mainly differ by the substituent group at the C17, here we used X-ray crystallography, equilibrium binding assays, and molecular dynamics simulations to investigate the molecular basis of the diverse reactivity observed with the two steroids. We found that the differences in the structure of TES and LCA affect the capability of these molecules to directly form hydrogen bonds with N-terminal residues of OleP internal helix I. The establishment of these contacts, by promoting the bending of helix I, fosters an efficient trigger of the open-to-closed structural transition that occurs upon substrate binding to OleP and contributes to the selectivity of the subsequent monooxygenation reaction.
Binding of steroid substrates reveals the key to the productive transition of the cytochrome P450 OleP / Costanzo, Antonella; Fata, Francesca; Freda, Ida; DE SCISCIO, MARIA LAURA; Gugole, Elena; Bulfaro, Giovanni; DI RENZO, Matteo; Barbizzi, Luca; Exertier, Cécile; Parisi, Giacomo; D’Abramo, Marco; Vallone, Beatrice; Savino, Carmelinda; Montemiglio, LINDA CELESTE. - In: STRUCTURE. - ISSN 0969-2126. - 32:9(2024), pp. 1465-1476. [10.1016/j.str.2024.06.005]
Binding of steroid substrates reveals the key to the productive transition of the cytochrome P450 OleP
Antonella CostanzoCo-primo
;Ida FredaCo-primo
;Maria Laura De Sciscio;Elena Gugole;Giovanni Bulfaro;Matteo Di Renzo;Luca Barbizzi;Giacomo Parisi;Marco D’Abramo;Beatrice Vallone
;Carmelinda Savino
;Linda Celeste Montemiglio
Ultimo
2024
Abstract
OleP is a bacterial cytochrome P450 involved in oleandomycin biosynthesis as it catalyzes regioselective epoxidation on macrolide intermediates. OleP has recently been reported to convert lithocholic acid (LCA) into murideoxycholic acid through a highly regioselective reaction and to unspecifically hydroxylate testosterone (TES). Since LCA and TES mainly differ by the substituent group at the C17, here we used X-ray crystallography, equilibrium binding assays, and molecular dynamics simulations to investigate the molecular basis of the diverse reactivity observed with the two steroids. We found that the differences in the structure of TES and LCA affect the capability of these molecules to directly form hydrogen bonds with N-terminal residues of OleP internal helix I. The establishment of these contacts, by promoting the bending of helix I, fosters an efficient trigger of the open-to-closed structural transition that occurs upon substrate binding to OleP and contributes to the selectivity of the subsequent monooxygenation reaction.File | Dimensione | Formato | |
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