{"@type":"Dataset","go_id":["https://identifiers.org/GO:0042278","https://identifiers.org/GO:0009085","https://identifiers.org/GO:0006554","https://identifiers.org/GO:0043039","https://identifiers.org/GO:0006749","https://identifiers.org/GO:0006213"],"go_kw":["purine metabolism","lysine biosynthesis","lysine degradation","aminoacyl-tRNA biosynthesis","glutathione metabolism","pyrimidine metabolism"],"integmet_study":"MTBLS6663","mesh_chemical_id":["https://identifiers.org/mesh:D008239","https://identifiers.org/mesh:D008055","https://identifiers.org/mesh:D012346","https://identifiers.org/mesh:D005978","https://identifiers.org/mesh:D001241"],"mesh_chemical_pubtator_kw":["lysine","lipid","aminoacyl-tRNA","glutathione","aspirin"],"ncbi_taxonomy_id":["https://identifiers.org/taxonomy:159736"],"ncbi_taxonomy_pubtator_kw":["Macrobrachium nipponense","M. nipponense"],"source_id":"https://identifiers.org/metabolights:MTBLS6663","study_findings":"Feed efficiency affected by amino acid, lipid, nucleotide metabolism.","study_observation":"Differently expressed metabolites in hepatopancreas and muscle.","study_summary":"Metabolome analysis of prawn feed efficiency.","study_title_original":"Metabolome analysis reveal key regulatory pathways of feed conversion efficiency of oriental river prawn Macrobrachium nipponense"}
