{"@type":"Dataset","go_id":["https://identifiers.org/GO:0009812","https://identifiers.org/GO:0008152","https://identifiers.org/GO:0009058","https://identifiers.org/GO:0009813","https://identifiers.org/GO:0009631"],"go_kw":["flavonoid metabolism","metabolism","biosynthesis","flavonoid biosynthesis","cold acclimation"],"integmet_study":"MTBLS3184","mesh_chemical_id":["https://identifiers.org/mesh:D005419","https://identifiers.org/mesh:D044948","https://identifiers.org/mesh:D047309","https://identifiers.org/mesh:D002734"],"mesh_chemical_pubtator_kw":["flavonoid","flavonoids","flavonols","flavones","chlorophyll"],"mesh_disease_id":["https://identifiers.org/mesh:D014075"],"mesh_disease_pubtator_kw":["needle discoloration","discoloration"],"ncbi_taxonomy_id":["https://identifiers.org/taxonomy:207839"],"ncbi_taxonomy_pubtator_kw":["C. fortunei"],"source_id":"https://identifiers.org/metabolights:MTBLS3184","study_findings":"Flavonoid metabolism influences needle discoloration and cold resistance in C. fortunei.","study_observation":"Pigment content, ultrastructure, transcriptomic and metabolomic analyses of C. fortunei needles.","study_summary":"Flavonoids affect needle color and cold resistance.","study_title_original":"Transcriptome and metabolome changes in Chinese cedar during cold acclimation reveal the roles of flavonoids in needle discoloration and cold resistance."}
