CYP701A8: A Rice <i>ent</i>-Kaurene Oxidase Paralog Diverted to More Specialized Diterpenoid Metabolism

Wang, Qiang; Hillwig, Matthew L.; Wu, Yisheng; Peters, Reuben J.

doi:10.1104/pp.111.187518

Cited by 109 publications

(110 citation statements)

References 46 publications

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“…With the exception of the moss Physcomitrella, which lacks GA phytohormones, the product of CYP701A is further oxidized in higher land plants by a second P450 to GA 12 . In the genome of rice (O. sativa), five CYP701A subfamily members are found, while only one, CYP701A6, fulfils the vital function of ent-kaurene oxidation en route to GA phytohormones [44]. Additionally, the five P450s are organized in one genomic cluster of 115 kb on chromosome 6.…”

Section: The Cyp71 Clan: Cradle Of Monoterpenoid and Sesquiterpenoid mentioning

confidence: 99%

Plant P450s as versatile drivers for evolution of species-specific chemical diversity

Hamberger

Bak

2013

Phil. Trans. R. Soc. B

267

231

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The irreversible nature of reactions catalysed by P450s makes these enzymes landmarks in the evolution of plant metabolic pathways. Founding members of P450 families are often associated with general (i.e. primary) metabolic pathways, restricted to single copy or very few representatives, indicative of purifying selection. Recruitment of those and subsequent blooms into multi-member gene families generates genetic raw material for functional diversification, which is an inherent characteristic of specialized (i.e. secondary) metabolism. However, a growing number of highly specialized P450s from not only the CYP71 clan indicate substantial contribution of convergent and divergent evolution to the observed general and specialized metabolite diversity. We will discuss examples of how the genetic and functional diversification of plant P450s drives chemical diversity in light of plant evolution. Even though it is difficult to predict the function or substrate of a P450 based on sequence similarity, grouping with a family or subfamily in phylogenetic trees can indicate association with metabolism of particular classes of compounds. Examples will be given that focus on multi-member gene families of P450s involved in the metabolic routes of four classes of specialized metabolites: cyanogenic glucosides, glucosinolates, mono-to triterpenoids and phenylpropanoids.

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Section: The Cyp71 Clan: Cradle Of Monoterpenoid and Sesquiterpenoid mentioning

confidence: 99%

Plant P450s as versatile drivers for evolution of species-specific chemical diversity

Hamberger

Bak

2013

Phil. Trans. R. Soc. B

267

231

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“…The ensuing diTPS products often undergo further structural modifications through the activity of P450 enzymes, as exemplified in rice by the P450-catalyzed formation of several bioactive diterpenoid metabolites (Swaminathan et al, 2009;Wang et al, 2011Wang et al, , 2012aWang et al, , 2012b. Comparatively, less was known about the complexity of maize diterpenoid biosynthesis.…”

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confidence: 99%

Discovery, Biosynthesis and Stress-Related Accumulation of Dolabradiene-Derived Defenses in Maize

et al. 2018

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“…The difference between the activity exhibited by AtKO and OsKO2 may reflect their distinct evolutionary contexts. In particular, although Arabidopsis seems to be representative of the Brassicaceae plant family, which does not produce any more specialized LRDs, only GA, and contains just one CYP701 family member, rice is representative of the Poaceae plant family, where it has been indicated that more specialized LRDs arose early, with widespread retention (20), and rice contains a number of CYP701A subfamily members with distinct function (9)(10)(11). This presumably exerted differing selective pressures on these genes, which was examined by molecular phylogenetic analysis of all characterized members of the CYP701 family ( Fig.…”

Section: Resultsmentioning

confidence: 99%

Probing the promiscuity of ent -kaurene oxidases via combinatorial biosynthesis

Mafu

Jia

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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The substrate specificity of enzymes from natural products' metabolism is a topic of considerable interest, with potential biotechnological use implicit in the discovery of promiscuous enzymes. However, such studies are often limited by the availability of substrates and authentic standards for identification of the resulting products. Here, a modular metabolic engineering system is used in a combinatorial biosynthetic approach toward alleviating this restriction. In particular, for studies of the multiply reactive cytochrome P450, ent-kaurene oxidase (KO), which is involved in production of the diterpenoid plant hormone gibberellin. Many, but not all, plants make a variety of related diterpenes, whose structural similarity to ent-kaurene makes them potential substrates for KO. Use of combinatorial biosynthesis enabled analysis of more than 20 such potential substrates, as well as structural characterization of 12 resulting unknown products, providing some insight into the underlying structure-function relationships. These results highlight the utility of this approach for investigating the substrate specificity of enzymes from complex natural products' biosynthesis.labdane-related diterpenoids | cytochrome P450 monooxygenases | natural products | enzyme specificity | gibberellins

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CYP701A8: A Rice ent-Kaurene Oxidase Paralog Diverted to More Specialized Diterpenoid Metabolism

Cited by 109 publications

References 46 publications

Plant P450s as versatile drivers for evolution of species-specific chemical diversity

Plant P450s as versatile drivers for evolution of species-specific chemical diversity

Discovery, Biosynthesis and Stress-Related Accumulation of Dolabradiene-Derived Defenses in Maize

Probing the promiscuity of ent -kaurene oxidases via combinatorial biosynthesis

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