Metabolite details
Reactome pathways
- No Reactome pathways listed for this metabolite.
Observed in studies
- Absence of tmRNA Increases the Persistence to Cefotaxime and the Intercellular Accumulation of Metabolite GlcNAc in <i>Aeromonas veronii</i>.
- Absence of tmRNA increases the persistence to cefotaxime by upregulating the metabolites GlcNAc in Aeromonas veronii
- Hfq Regulates Efflux Pump Expression and Purine Metabolic Pathway to Increase the Trimethoprim Resistance in Aeromonas veronii
- Effect of L-carnitine administration on lipid and metabolite content in sheep infraspinatus muscle after tendon release
- Four layer multi-omics reveals molecular responses to aneuploidy in <i>Leishmania</i>
- How Does the Seed Pre-germinative Metabolism Fight against Imbibition Damage; Emerging Roles of Fatty Acid Cohort and Antioxidant Defence
- Metabolic Dynamics of In Vitro CD8+ T Cell Activation.
- Metabolomic Insights into the Browning of the Peel of Bagging ‘Rui Xue’ Apple Fruit
- Microbial Diversity and Non-volatile Metabolites Profile of Low-Temperature Sausage Stored at Room Temperature
- Anti-anemia drug FG4592 retards the AKI to CKD transition by improving vascular regeneration and anti-oxidative capability (day 10)
- Chronic sleep loss sensitizes Drosophila melanogaster to nitrogen stress
- The Manchurian Walnut Genome: Insights into Juglone and Lipid Biosynthesis.
- Diallyl disulfide (DADS) ameliorates intestinal Candida albicans infection by modulating the gut microbiota and metabolites and providing intestinal protection in mice
- Exercise-generated β-aminoisobutyric acid (BAIBA) reduces cardiomyocytes metabolic stress and apoptosis caused by mitochondrial dysfunction through the miR-208b/AMPK pathway
- Metabolic profilings of rat INS-1 β-cells under changing levels of essential amino acids
- Phosphoproteomic and Metabolomic Profiling Uncovers the Roles of CcPmk1 in the Pathogenicity of <i>Cytospora chrysosperma</i>
- AMPK activation orchestrated replicative senescence of periodontal ligament stem cells via regulating metabolomics
- Limited nutrient availability in the tumor microenvironment renders pancreatic tumors sensitive to allosteric IDH1 inhibitors
- Intergenerational Association of Gut Microbiota and Metabolism between Perinatal Folic Acid Metabolism and Neural Tube Defects (Feces metabolomics)
- Interaction between Cervical Microbiota and Host Gene Regulation in Caesarean Section Scar Diverticulum
- Mechanism of interventional effect and targets of Zhuyu Pill in regulating and suppressing colitis and cholestasis
- Multiomic analysis revealed the potential role of rumen microbes in heat stress
- Effect of heat stress on serum enzyme activity, antioxidant capacity and immune parameter metabolomics datasets in Holstein cows at different growth stages
- PKM2 methylation by CARM1 activates aerobic glycolysis to promote tumorigenesis.
- Integrated Proteomic and Metabolomic Analyses Show Differential Effects of Glucose Availability in Marine <i>Synechococcus</i> and <i>Prochlorococcus</i>.
- DNA-PKcs drives CKD progression by activating TAF7/RAPTOR/mTORC1 signaling-mediated metabolic reprogramming
- GABA regulates IL-1β production in macrophages
- Transcriptomics and metabolomics analysis reveal the anti-oxidation and immune boosting effects of mulberry leaves in growing mutton sheep
- Extracellular-acidosis restricts one-carbon metabolism and preserves T cell stemness
- Metabolic changes associated with tick-microbe interactions
- Unraveling the metabolic effects of benzophenone-3 on the endosymbiotic dinoflagellate Cladocopium goreaui
- Genetic mapping and molecular mechanism behind color variation in the Asian vine snake
- L-leucine increases the sensitivity of drug-resistant Salmonella to sarafloxacin by stimulating central carbon metabolism and increasing intracellular reactive oxygen species level (LC-MS positive mode)
- Integrated multi-omics analysis of adverse cardiac remodeling and metabolic inflexibility upon ErbB2 and ERRα deficiency.
Observed in differential profiles
- Wild_Type_vs_tmRNA_Deletion
- Wild_Type_vs_tmRNA_Knockout
- Wild_type_vs_hfq
- Control_16.6_months_vs_Treatment_16.6_months
- Nepalese_BPK173_vs_Nepalese_BPK178
- Dry_Seed_vs_8h_Imbibed_Seed
- G3_Experimental_Sample_0h_vs_G11_Experimental_Sample_96h
- G3_Experimental_Sample_0h_vs_G11_Experimental_Sample_96h
- Non_Bagged_Fruits_vs_Bagged_Fruits_With_Browning
- Control_vs_Day_12
- Sham_vs_UIR
- Iso31_Control_vs_Fumin_Homozygous_Sleep_Mutants
- Embryo_S1_vs_Embryo_S4
- G1_PBS_vs_G2_DSS
- Sham_vs_Heart_Failure_Sedentary
- G1_Control_vs_G2_Arginine_Addition
- CcPmk1_vs_Wild_type
- Passage_4_vs_Passage_20
- Wild_Type_vs_Gene_Knockout
- Normal_vs_Neural_Tube_Defect
- Control_vs_CSD
- Control_vs_ZYP_High_Dose
- Dc-N_vs_Dc-HS
- Dcs_N_vs_Dcs_HS
- MCF-7_WT_vs_MCF-7_PKM2_KO
- SS120_Control_vs_SS120_5mM
- SS120_Control_vs_SS120_5mM
- SS120_Control_vs_SS120_5mM
- SS120_Control_vs_SS120_5mM
- SS120_Control_vs_SS120_5mM
- SS120_Control_vs_SS120_5mM
- DNA-PK_KO_UUO_vs_DNA-PK_KO_Control
- Control_0h_vs_GABA_0h
- Control_vs_Fermented_Mulberry_Leaves
- Control_vs_Lactic_Acid
- Uninfected_1h_vs_Anaplasma_phagocytophilum_1h
- Control_vs_BP3_Low_Concentration
- Yellow_Skin_vs_Green_Skin
- SAR-S_vs_SAR-R
- WT_vs_ErbB2_KI