Recruitment of specific flavonoid B-ring hydroxylases for two independent biosynthesis pathways of flavone-derived metabolites in grasses

In rice (Oryza sativa), OsF2H and OsFNSII direct flavanones to independent pathways that form soluble flavone C-glycosides and tricin-type metabolites (both soluble and lignin-bound), respectively. Production of soluble tricin metabolites requires CYP75B4 as a chrysoeriol 5′-hydroxylase. Meanwhile,...

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Published in:The New phytologist 2019-07, Vol.223 (1), p.204-219
Main Authors: Lam, Pui Ying, Lui, Andy C.W., Yamamura, Masaomi, Wang, Lanxiang, Takeda, Yuri, Suzuki, Shiro, Liu, Hongjia, Zhu, Fu-Yuan, Chen, Mo-Xian, Zhang, Jianhua, Umezawa, Toshiaki, Tobimatsu, Yuki, Lo, Clive
Format: Article
Language:English
Subjects:
Anatomical structures
Biofuels
biomass saccharification
Biomaterials
Biomedical materials
Biosynthesis
Biosynthetic Pathways
Carbohydrate Metabolism
Catalysis
Cell Wall - metabolism
Cell walls
CRISPR/Cas9
Cytochrome P-450 Enzyme System - genetics
Cytochrome P-450 Enzyme System - metabolism
Digestibility
flavone C‐glycosides
Flavones - chemistry
Flavones - metabolism
Flavonoids
Flavonoids - chemistry
Flavonoids - metabolism
Gene Expression Regulation, Plant
Glycosides
Glycosides - metabolism
Grasses
Homology
Hydroxylase
Hydroxylation
Lignin
Lignin - metabolism
Magnetic Resonance Spectroscopy
Metabolites
Metabolome
Mixed Function Oxygenases - metabolism
Mutants
Mutation
Mutation - genetics
Oryza - metabolism
Oryza sativa
Panicum - metabolism
pathway‐specific flavonoid B‐ring hydroxylases
Poaceae - metabolism
Profiles
rice (Oryza sativa)
Solubility
Sorghum
Sorghum - metabolism
Tissue
tricin–lignins
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Summary:In rice (Oryza sativa), OsF2H and OsFNSII direct flavanones to independent pathways that form soluble flavone C-glycosides and tricin-type metabolites (both soluble and lignin-bound), respectively. Production of soluble tricin metabolites requires CYP75B4 as a chrysoeriol 5′-hydroxylase. Meanwhile, the close homologue CYP75B3 is a canonical flavonoid 3′-hydroxylase (F3′H). However, their precise roles in the biosynthesis of soluble flavone C-glycosides and tricin–lignins in cell walls remain unknown. We examined CYP75B3 and CYP75B4 expression in vegetative tissues, analyzed extractable flavonoid profiles, cell wall structure and digestibility of their mutants, and investigated catalytic activities of CYP75B4 orthologues in grasses. CYP75B3 and CYP75B4 showed co-expression patterns with OsF2H and OsFNSII, respectively. CYP75B3 is the sole F3′H in flavone C-glycosides biosynthesis, whereas CYP75B4 alone provides sufficient 3′,5′-hydroxylation for tricin–lignin deposition. CYP75B4 mutation results in production of apigenin-incorporated lignin and enhancement of cell wall digestibility. Moreover, tricin pathway-specific 3′,5′-hydroxylation activities are conserved in sorghum CYP75B97 and switchgrass CYP75B11. CYP75B3 and CYP75B4 represent two different pathway-specific enzymes recruited together with OsF2H and OsFNSII, respectively. Interestingly, the OsF2H-CYP75B3 and OsFNSII-CYP75B4 pairs appear to be conserved in grasses. Finally, manipulation of tricin biosynthesis through CYP75B4 orthologues can be a promising strategy to improve digestibility of grass biomass for biofuel and biomaterial production.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.15795