The genome analysis of Tripterygium wilfordii reveals TwCYP712K1 and TwCYP712K2 responsible for oxidation of friedelin in celastrol biosynthesis pathway
Genome analysis of Tripterygium wilfordii for celastrol biosynthesis.
The genome analysis of Tripterygium wilfordii reveals TwCYP712K1 and TwCYP712K2 responsible for oxidation of friedelin in celastrol biosynthesis pathway
Summary
Genome analysis of Tripterygium wilfordii for celastrol biosynthesis.
Observation
Genome, transcriptome, and metabolite analyses of T. wilfordii.
Findings
TwCYP712K1 and TwCYP712K2 oxidize friedelin in celastrol biosynthesis.
{
"@type": "Dataset",
"go_id": [
"https://identifiers.org/GO:0009058"
],
"go_kw": [
"biosynthesis"
],
"integmet_study": "MTBLS1080",
"source_id": "https://identifiers.org/metabolights:MTBLS1080",
"study_findings": "TwCYP712K1 and TwCYP712K2 oxidize friedelin in celastrol biosynthesis.",
"study_observation": "Genome, transcriptome, and metabolite analyses of T. wilfordii.",
"study_summary": "Genome analysis of Tripterygium wilfordii for celastrol biosynthesis.",
"study_title_original": "The genome analysis of Tripterygium wilfordii reveals TwCYP712K1 and TwCYP712K2 responsible for oxidation of friedelin in celastrol biosynthesis pathway"
}