EC Number |
General Information |
Reference |
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1.14.14.82 | evolution |
duplication of F3'H genes in plants, overview |
713316 |
1.14.14.82 | physiological function |
enzyme expression is associated with anthocyanin accumulation in five different sweet potato cultivars tested |
725928 |
1.14.14.82 | physiological function |
expression of CYP75B50 gene in petunia results in a more reddish flower color change. The petals expressing CYP75B50 gene contain an increased amount of 3'-hydroxylated anthocyanidin (peonodin and cyanidin) |
745636 |
1.14.14.82 | metabolism |
flavonoid 3',5'-hydroxylases and flavonoid 3'-hydroxylases competitively control the synthesis of delphinidin and cyanidin, the precursors of blue and red anthocyanins, anthocyanin profiling in strain PN40024, overview |
-, 711598 |
1.14.14.82 | physiological function |
loss of enzyme activity leads to accumulation of 3,5-di-O-(beta-glucopyranosyl)pelargonidin 6''-O-4,6'''-O-1-cyclic malate instead of 3,5-di-O-(beta-glucopyranosyl)cyanidin 6''-O-4,6'''-O-1-cyclic malate, the only difference between these two anthocyanins is a hydroxyl group present at the 3' position in the B-ring of aglycone. Loss of enzyme results in a color change in buds from purple to deep pink. Mutation is due to an active hAT type transposable element, designated Tdic101. The color change is attributed to Tdic101 insertion into the second intron of flavonoid 3'-hydroxylase |
725984 |
1.14.14.82 | metabolism |
MdF3'H genes are coordinately expressed with other genes in the anthocyanin biosynthetic pathway in apple |
713316 |
1.14.14.82 | physiological function |
mutation tt7 carrying an internal stop codon leads to the transparent testa phenotype due to lack of tannins in the seed coat |
744455 |
1.14.14.82 | physiological function |
part of flavonoid biosynthetic pathway |
701213 |
1.14.14.82 | metabolism |
role in anthocyanin regulation and flavone biosynthesis, interaction with chalcone synthase 1 as shown by yeast fusion experiment |
700856 |
1.14.14.82 | metabolism |
the dark or light brown color variation in injured leaves of sorghums is associated with the gene expression of flavone synthase II and flavonoid 3'-hydroxylase. Flavone synthase II pathway is activated to synthesize flavones (apigenin and luteolin) and the expression level of flavonoid 3'-hydroxylase changes the balance of apigenin and luteolin. Expression of flavone synthase II is related to the synthesis of flavones (apigenin and luteolin) and the expression level of flavonoid 3'-hydroxylase is related to the balance of apigenin and luteolin. Expression of flavone synthase II and flavonoid 3'-hydroxylase is thus associated with dark or light brown coloration in tan-colored injured leaves of sorghum. Expression of both flavone synthase II and flavonoid 3'-hydroxylase leads to the synthesis of apigenin and luteolin in Sorghum bicolor |
-, 742597 |