Shahida A Mitu1,2, Steven M Ogbourne1,2, Anne H Klein1,2, Trong D Tran1, Paul W Reddell3, Scott F Cummins4,5. 1. GeneCology Research Centre, University of the Sunshine Coast, Maroochydore DC, Queensland, 4558, Australia. 2. School of Science, Technology and Engineering, University of the Sunshine Coast, Maroochydore DC, Queensland, 4558, Australia. 3. EcoBiotics Ltd, Yungaburra, Queensland, 4884, Australia. 4. GeneCology Research Centre, University of the Sunshine Coast, Maroochydore DC, Queensland, 4558, Australia. scummins@usc.edu.au. 5. School of Science, Technology and Engineering, University of the Sunshine Coast, Maroochydore DC, Queensland, 4558, Australia. scummins@usc.edu.au.
Abstract
BACKGROUND: Cytochrome P450s (P450s) are enzymes that play critical roles in the biosynthesis of physiologically important compounds across all organisms. Although they have been characterised in a large number of plant species, no information relating to these enzymes are available from the genus Fontainea (family Euphorbiaceae). Fontainea is significant as the genus includes species that produce medicinally significant epoxy-tigliane natural products, one of which has been approved as an anti-cancer therapeutic. RESULTS: A comparative species leaf metabolome analysis showed that Fontainea species possess a chemical profile different from various other plant species. The diversity and expression profiles of Fontainea P450s were investigated from leaf and root tissue. A total of 103 and 123 full-length P450 genes in Fontainea picrosperma and Fontainea venosa, respectively (and a further 127/125 partial-length) that were phylogenetically classified into clans, families and subfamilies. The majority of P450 identified are most active within root tissue (66.2% F. picrosperma, 65.0% F. venosa). Representatives within the CYP71D and CYP726A were identified in Fontainea that are excellent candidates for diterpenoid synthesis, of which CYP726A1, CYP726A2 and CYP71D1 appear to be exclusive to Fontainea species and were significantly more highly expressed in root tissue compared to leaf tissue. CONCLUSION: This study presents a comprehensive overview of the P450 gene family in Fontainea that may provide important insights into the biosynthesis of the medicinally significant epoxy-tigliane diterpenes found within the genus.
BACKGROUND: Cytochrome P450s (P450s) are enzymes that play critical roles in the biosynthesis of physiologically important compounds across all organisms. Although they have been characterised in a large number of plant species, no information relating to these enzymes are available from the genus Fontainea (family Euphorbiaceae). Fontainea is significant as the genus includes species that produce medicinally significant epoxy-tigliane natural products, one of which has been approved as an anti-cancer therapeutic. RESULTS: A comparative species leaf metabolome analysis showed that Fontainea species possess a chemical profile different from various other plant species. The diversity and expression profiles of Fontainea P450s were investigated from leaf and root tissue. A total of 103 and 123 full-length P450 genes in Fontainea picrosperma and Fontainea venosa, respectively (and a further 127/125 partial-length) that were phylogenetically classified into clans, families and subfamilies. The majority of P450 identified are most active within root tissue (66.2% F. picrosperma, 65.0% F. venosa). Representatives within the CYP71D and CYP726A were identified in Fontainea that are excellent candidates for diterpenoid synthesis, of which CYP726A1, CYP726A2 and CYP71D1 appear to be exclusive to Fontainea species and were significantly more highly expressed in root tissue compared to leaf tissue. CONCLUSION: This study presents a comprehensive overview of the P450 gene family in Fontainea that may provide important insights into the biosynthesis of the medicinally significant epoxy-tigliane diterpenes found within the genus.
Authors: David R Nelson; Mary A Schuler; Suzanne M Paquette; Daniele Werck-Reichhart; Søren Bak Journal: Plant Physiol Date: 2004-06 Impact factor: 8.340
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Authors: Benedict J Panizza; Paul de Souza; Adam Cooper; Aflah Roohullah; Christos S Karapetis; Jason D Lickliter Journal: EBioMedicine Date: 2019-12-03 Impact factor: 8.143
Authors: Shahida A Mitu; Praphaporn Stewart; Trong D Tran; Paul W Reddell; Scott F Cummins; Steven M Ogbourne Journal: Molecules Date: 2022-06-21 Impact factor: 4.927