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About
What is Reactome ?
News
Team
Scientific Advisory Board
Funding
Editorial Calendar
Release Calendar
Statistics
Our Logo
License Agreement
Privacy Notice
Disclaimer
Digital Preservation
Contact us
Content
Table of Contents
DOIs
Data Schema
Reactome Research Spotlight
ORCID Integration Project
COVID-19 Disease Pathways
Docs
Userguide
Pathway Browser
How do I search ?
Details Panel
Analysis Tools
Analysis Data
Analysis Gene Expression
Species Comparison
Tissue Distribution
Diseases
Cytomics
Review Status of Reactome Events
ReactomeFIViz
Developer's Zone
Graph Database
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Pathway Diagrams
Icon Info
EHLD Specs & Guidelines
Icon Library Guidelines
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Curator Guide
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FAQ
Linking to Us
Citing us
Tools
Pathway Browser
Analyse gene list
Analyse gene expression
Species Comparison
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Go!
H+ [endoplasmic reticulum lumen]
Stable Identifier
R-ALL-156540
Type
Chemical Compound [SimpleEntity]
Compartment
endoplasmic reticulum lumen
Synonyms
hydron
Icon
Locations in the PathwayBrowser
for Species:
Homo sapiens
Bos taurus
Caenorhabditis elegans
Canis familiaris
Danio rerio
Dictyostelium discoideum
Drosophila melanogaster
Gallus gallus
Mus musculus
Plasmodium falciparum
Rattus norvegicus
Sus scrofa
Xenopus tropicalis
Expand all
Cell-Cell communication (Bos taurus)
Cell junction organization (Bos taurus)
Cell-cell junction organization (Bos taurus)
Adherens junctions interactions (Bos taurus)
Regulation of Homotypic Cell-Cell Adhesion (Bos taurus)
Regulation of Expression and Function of Type I Classical Cadherins (Bos taurus)
Regulation of CDH1 Expression and Function (Bos taurus)
Regulation of CDH1 posttranslational processing and trafficking to plasma membrane (Bos taurus)
CDH1 is O-manosylated (Bos taurus)
H+ [endoplasmic reticulum lumen]
Drug ADME (Bos taurus)
Aspirin ADME (Bos taurus)
CES1,CES2 hydrolyze ASA- to ST (Bos taurus)
H+ [endoplasmic reticulum lumen]
CES2 hydrolyzes ASA- (Bos taurus)
H+ [endoplasmic reticulum lumen]
Metabolism (Bos taurus)
Biological oxidations (Bos taurus)
Phase I - Functionalization of compounds (Bos taurus)
CES1 trimer.CES2 hydrolyse COCN to BEG (Bos taurus)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Bos taurus)
Eicosanoids (Bos taurus)
CYP4F3 20-hydroxylates LTB4 (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Bos taurus)
H+ [endoplasmic reticulum lumen]
Fatty acids (Bos taurus)
CYP2J2 oxidises ARA (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP4A11 omega-hydroxylates DDCX (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Bos taurus)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Bos taurus)
CYP2S1 4-hydroxylates atRA (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP3A43 6b-hydroxylates TEST (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Bos taurus)
H+ [endoplasmic reticulum lumen]
Vitamins (Bos taurus)
CYP26A1,B1 4-hydroxylate atRA (Bos taurus)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Bos taurus)
Aromatic amines can be N-hydroxylated or N-dealkylated by CYP1A2 (Bos taurus)
N-atom dealkylation of caffeine (Bos taurus)
H+ [endoplasmic reticulum lumen]
N-hydroxylation of 4-aminobiphenyl (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP2C19 5-hydroxylates omeprazole (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP2D6 4-hydroxylates debrisoquine (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Bos taurus)
Benzene is hydroxylated to phenol (Bos taurus)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Bos taurus)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Bos taurus)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP3A4 can N-demethylate loperamide (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP3A4,5 oxidise AFB1 to AFXBO (Bos taurus)
H+ [endoplasmic reticulum lumen]
CYP3A7 can 6beta-hydroxylate testosterone (Bos taurus)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Bos taurus)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Bos taurus)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Bos taurus)
H+ [endoplasmic reticulum lumen]
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Bos taurus)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Bos taurus)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Bos taurus)
FMO1:FAD N-oxidises TAM (Bos taurus)
H+ [endoplasmic reticulum lumen]
FMO2:FAD:Mg2+ S-oxidises MTZ (Bos taurus)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Bos taurus)
H+ [endoplasmic reticulum lumen]
Phase II - Conjugation of compounds (Bos taurus)
Methylation (Bos taurus)
CYP1A2 S-demethylates 6MMP (Bos taurus)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Bos taurus)
Fatty acid metabolism (Bos taurus)
Arachidonate metabolism (Bos taurus)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Bos taurus)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Bos taurus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Bos taurus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Bos taurus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Bos taurus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Bos taurus)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Bos taurus)
Glycosphingolipid metabolism (Bos taurus)
Glycosphingolipid biosynthesis (Bos taurus)
UGT8 transfers Gal from UDP-Gal to CERA (Bos taurus)
H+ [endoplasmic reticulum lumen]
Glycosphingolipid catabolism (Bos taurus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Bos taurus)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Bos taurus)
Metabolism of fat-soluble vitamins (Bos taurus)
Metabolism of vitamin K (Bos taurus)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Bos taurus)
H+ [endoplasmic reticulum lumen]
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Bos taurus)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Bos taurus)
Peptide hormone metabolism (Bos taurus)
Metabolism of Angiotensinogen to Angiotensins (Bos taurus)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Bos taurus)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Bos taurus)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Bos taurus)
The activation of arylsulfatases (Bos taurus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Bos taurus)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Bos taurus)
DAG1 glycosylations (Bos taurus)
DAG1 core M1 glycosylations (Bos taurus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Bos taurus)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Bos taurus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Bos taurus)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Bos taurus)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Bos taurus)
H+ [endoplasmic reticulum lumen]
POMGNT2 transfers GlcNAc to Man-DAG1 (Bos taurus)
H+ [endoplasmic reticulum lumen]
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Bos taurus)
H+ [endoplasmic reticulum lumen]
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Bos taurus)
H+ [endoplasmic reticulum lumen]
FUT10 O-fucosylates EMI domain-containing proteins (Bos taurus)
H+ [endoplasmic reticulum lumen]
FUT11 O-fucosylates EMI domain-containing proteins (Bos taurus)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Bos taurus)
POFUT2 transfers fucose to TSR domain-containing proteins (Bos taurus)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Bos taurus)
Cardiac conduction (Bos taurus)
Ion homeostasis (Bos taurus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Bos taurus)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Bos taurus)
Ion channel transport (Bos taurus)
Ion transport by P-type ATPases (Bos taurus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Bos taurus)
H+ [endoplasmic reticulum lumen]
Drug ADME (Caenorhabditis elegans)
Aspirin ADME (Caenorhabditis elegans)
CES1,CES2 hydrolyze ASA- to ST (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
CES2 hydrolyzes ASA- (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Metabolism (Caenorhabditis elegans)
Biological oxidations (Caenorhabditis elegans)
Phase I - Functionalization of compounds (Caenorhabditis elegans)
CES1 trimer.CES2 hydrolyse COCN to BEG (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Caenorhabditis elegans)
Fatty acids (Caenorhabditis elegans)
CYP2J2 oxidises ARA (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Caenorhabditis elegans)
CYP2S1 4-hydroxylates atRA (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Caenorhabditis elegans)
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
CYP2C19 5-hydroxylates omeprazole (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
CYP2D6 4-hydroxylates debrisoquine (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Caenorhabditis elegans)
Benzene is hydroxylated to phenol (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Caenorhabditis elegans)
FMO1:FAD N-oxidises TAM (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
FMO2:FAD:Mg2+ S-oxidises MTZ (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Caenorhabditis elegans)
Fatty acid metabolism (Caenorhabditis elegans)
Arachidonate metabolism (Caenorhabditis elegans)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Caenorhabditis elegans)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Caenorhabditis elegans)
Glycosphingolipid metabolism (Caenorhabditis elegans)
Glycosphingolipid biosynthesis (Caenorhabditis elegans)
UGT8 transfers Gal from UDP-Gal to CERA (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Caenorhabditis elegans)
Peptide hormone metabolism (Caenorhabditis elegans)
Metabolism of Angiotensinogen to Angiotensins (Caenorhabditis elegans)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Caenorhabditis elegans)
O-linked glycosylation (Caenorhabditis elegans)
O-glycosylation of TSR domain-containing proteins (Caenorhabditis elegans)
POFUT2 transfers fucose to TSR domain-containing proteins (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Caenorhabditis elegans)
Cardiac conduction (Caenorhabditis elegans)
Ion homeostasis (Caenorhabditis elegans)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Caenorhabditis elegans)
Ion channel transport (Caenorhabditis elegans)
Ion transport by P-type ATPases (Caenorhabditis elegans)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Caenorhabditis elegans)
H+ [endoplasmic reticulum lumen]
Cell-Cell communication (Canis familiaris)
Cell junction organization (Canis familiaris)
Cell-cell junction organization (Canis familiaris)
Adherens junctions interactions (Canis familiaris)
Regulation of Homotypic Cell-Cell Adhesion (Canis familiaris)
Regulation of Expression and Function of Type I Classical Cadherins (Canis familiaris)
Regulation of CDH1 Expression and Function (Canis familiaris)
Regulation of CDH1 posttranslational processing and trafficking to plasma membrane (Canis familiaris)
CDH1 is O-manosylated (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Drug ADME (Canis familiaris)
Aspirin ADME (Canis familiaris)
CES1,CES2 hydrolyze ASA- to ST (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CES2 hydrolyzes ASA- (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Metabolism (Canis familiaris)
Biological oxidations (Canis familiaris)
Phase I - Functionalization of compounds (Canis familiaris)
CES1 trimer.CES2 hydrolyse COCN to BEG (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Canis familiaris)
Eicosanoids (Canis familiaris)
CYP4F3 20-hydroxylates LTB4 (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Fatty acids (Canis familiaris)
CYP2J2 oxidises ARA (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP4A11 omega-hydroxylates DDCX (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Canis familiaris)
CYP2S1 4-hydroxylates atRA (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP3A43 6b-hydroxylates TEST (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Vitamins (Canis familiaris)
CYP26A1,B1 4-hydroxylate atRA (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Canis familiaris)
CYP2D6 4-hydroxylates debrisoquine (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Canis familiaris)
Benzene is hydroxylated to phenol (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Canis familiaris)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP3A4 can N-demethylate loperamide (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP3A4,5 oxidise AFB1 to AFXBO (Canis familiaris)
H+ [endoplasmic reticulum lumen]
CYP3A7 can 6beta-hydroxylate testosterone (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Canis familiaris)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Canis familiaris)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Canis familiaris)
FMO1:FAD N-oxidises TAM (Canis familiaris)
H+ [endoplasmic reticulum lumen]
FMO2:FAD:Mg2+ S-oxidises MTZ (Canis familiaris)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Canis familiaris)
Fatty acid metabolism (Canis familiaris)
Arachidonate metabolism (Canis familiaris)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Canis familiaris)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Canis familiaris)
Glycosphingolipid metabolism (Canis familiaris)
Glycosphingolipid biosynthesis (Canis familiaris)
UGT8 transfers Gal from UDP-Gal to CERA (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Glycosphingolipid catabolism (Canis familiaris)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Canis familiaris)
Metabolism of fat-soluble vitamins (Canis familiaris)
Metabolism of vitamin K (Canis familiaris)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Canis familiaris)
Peptide hormone metabolism (Canis familiaris)
Metabolism of Angiotensinogen to Angiotensins (Canis familiaris)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Canis familiaris)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Canis familiaris)
The activation of arylsulfatases (Canis familiaris)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Canis familiaris)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Canis familiaris)
DAG1 glycosylations (Canis familiaris)
DAG1 core M1 glycosylations (Canis familiaris)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Canis familiaris)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Canis familiaris)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Canis familiaris)
H+ [endoplasmic reticulum lumen]
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Canis familiaris)
H+ [endoplasmic reticulum lumen]
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Canis familiaris)
H+ [endoplasmic reticulum lumen]
FUT10 O-fucosylates EMI domain-containing proteins (Canis familiaris)
H+ [endoplasmic reticulum lumen]
FUT11 O-fucosylates EMI domain-containing proteins (Canis familiaris)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Canis familiaris)
POFUT2 transfers fucose to TSR domain-containing proteins (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Canis familiaris)
Cardiac conduction (Canis familiaris)
Ion homeostasis (Canis familiaris)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Canis familiaris)
Ion channel transport (Canis familiaris)
Ion transport by P-type ATPases (Canis familiaris)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Canis familiaris)
H+ [endoplasmic reticulum lumen]
Cell-Cell communication (Danio rerio)
Cell junction organization (Danio rerio)
Cell-cell junction organization (Danio rerio)
Adherens junctions interactions (Danio rerio)
Regulation of Homotypic Cell-Cell Adhesion (Danio rerio)
Regulation of Expression and Function of Type I Classical Cadherins (Danio rerio)
Regulation of CDH1 Expression and Function (Danio rerio)
Regulation of CDH1 posttranslational processing and trafficking to plasma membrane (Danio rerio)
CDH1 is O-manosylated (Danio rerio)
H+ [endoplasmic reticulum lumen]
Drug ADME (Danio rerio)
Aspirin ADME (Danio rerio)
CES1,CES2 hydrolyze ASA- to ST (Danio rerio)
H+ [endoplasmic reticulum lumen]
CES2 hydrolyzes ASA- (Danio rerio)
H+ [endoplasmic reticulum lumen]
Metabolism (Danio rerio)
Biological oxidations (Danio rerio)
Phase I - Functionalization of compounds (Danio rerio)
CES1 trimer.CES2 hydrolyse COCN to BEG (Danio rerio)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Danio rerio)
Eicosanoids (Danio rerio)
CYP4F3 20-hydroxylates LTB4 (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Danio rerio)
H+ [endoplasmic reticulum lumen]
Fatty acids (Danio rerio)
CYP2J2 oxidises ARA (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP4A11 omega-hydroxylates DDCX (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Danio rerio)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Danio rerio)
CYP2S1 4-hydroxylates atRA (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP3A43 6b-hydroxylates TEST (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Danio rerio)
H+ [endoplasmic reticulum lumen]
Vitamins (Danio rerio)
CYP26A1,B1 4-hydroxylate atRA (Danio rerio)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Danio rerio)
Aromatic amines can be N-hydroxylated or N-dealkylated by CYP1A2 (Danio rerio)
N-atom dealkylation of caffeine (Danio rerio)
H+ [endoplasmic reticulum lumen]
N-hydroxylation of 4-aminobiphenyl (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP2D6 4-hydroxylates debrisoquine (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Danio rerio)
Benzene is hydroxylated to phenol (Danio rerio)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Danio rerio)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Danio rerio)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP3A4 can N-demethylate loperamide (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP3A4,5 oxidise AFB1 to AFXBO (Danio rerio)
H+ [endoplasmic reticulum lumen]
CYP3A7 can 6beta-hydroxylate testosterone (Danio rerio)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Danio rerio)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Danio rerio)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Danio rerio)
H+ [endoplasmic reticulum lumen]
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Danio rerio)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Danio rerio)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Danio rerio)
FMO1:FAD N-oxidises TAM (Danio rerio)
H+ [endoplasmic reticulum lumen]
FMO2:FAD:Mg2+ S-oxidises MTZ (Danio rerio)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Danio rerio)
H+ [endoplasmic reticulum lumen]
Phase II - Conjugation of compounds (Danio rerio)
Methylation (Danio rerio)
CYP1A2 S-demethylates 6MMP (Danio rerio)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Danio rerio)
Fatty acid metabolism (Danio rerio)
Arachidonate metabolism (Danio rerio)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Danio rerio)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Danio rerio)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Danio rerio)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Danio rerio)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Danio rerio)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Danio rerio)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Danio rerio)
Glycosphingolipid metabolism (Danio rerio)
Glycosphingolipid biosynthesis (Danio rerio)
UGT8 transfers Gal from UDP-Gal to CERA (Danio rerio)
H+ [endoplasmic reticulum lumen]
Glycosphingolipid catabolism (Danio rerio)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Danio rerio)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Danio rerio)
Metabolism of fat-soluble vitamins (Danio rerio)
Metabolism of vitamin K (Danio rerio)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Danio rerio)
H+ [endoplasmic reticulum lumen]
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Danio rerio)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Danio rerio)
Peptide hormone metabolism (Danio rerio)
Metabolism of Angiotensinogen to Angiotensins (Danio rerio)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Danio rerio)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Danio rerio)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Danio rerio)
The activation of arylsulfatases (Danio rerio)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Danio rerio)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Danio rerio)
DAG1 glycosylations (Danio rerio)
DAG1 core M1 glycosylations (Danio rerio)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Danio rerio)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Danio rerio)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Danio rerio)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Danio rerio)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Danio rerio)
H+ [endoplasmic reticulum lumen]
POMGNT2 transfers GlcNAc to Man-DAG1 (Danio rerio)
H+ [endoplasmic reticulum lumen]
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Danio rerio)
H+ [endoplasmic reticulum lumen]
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Danio rerio)
H+ [endoplasmic reticulum lumen]
FUT10 O-fucosylates EMI domain-containing proteins (Danio rerio)
H+ [endoplasmic reticulum lumen]
FUT11 O-fucosylates EMI domain-containing proteins (Danio rerio)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Danio rerio)
POFUT2 transfers fucose to TSR domain-containing proteins (Danio rerio)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Danio rerio)
Cardiac conduction (Danio rerio)
Ion homeostasis (Danio rerio)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Danio rerio)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Danio rerio)
Ion channel transport (Danio rerio)
Ion transport by P-type ATPases (Danio rerio)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Danio rerio)
H+ [endoplasmic reticulum lumen]
Drug ADME (Dictyostelium discoideum)
Aspirin ADME (Dictyostelium discoideum)
CES1,CES2 hydrolyze ASA- to ST (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
CES2 hydrolyzes ASA- (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Metabolism (Dictyostelium discoideum)
Biological oxidations (Dictyostelium discoideum)
Phase I - Functionalization of compounds (Dictyostelium discoideum)
CES1 trimer.CES2 hydrolyse COCN to BEG (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Dictyostelium discoideum)
Fatty acids (Dictyostelium discoideum)
CYP2J2 oxidises ARA (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Dictyostelium discoideum)
CYP2S1 4-hydroxylates atRA (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Dictyostelium discoideum)
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
CYP2C19 5-hydroxylates omeprazole (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
CYP2D6 4-hydroxylates debrisoquine (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Dictyostelium discoideum)
Benzene is hydroxylated to phenol (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Dictyostelium discoideum)
Fatty acid metabolism (Dictyostelium discoideum)
Arachidonate metabolism (Dictyostelium discoideum)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Dictyostelium discoideum)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Dictyostelium discoideum)
Peptide hormone metabolism (Dictyostelium discoideum)
Metabolism of Angiotensinogen to Angiotensins (Dictyostelium discoideum)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Dictyostelium discoideum)
H+ [endoplasmic reticulum lumen]
Drug ADME (Drosophila melanogaster)
Aspirin ADME (Drosophila melanogaster)
CES1,CES2 hydrolyze ASA- to ST (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
CES2 hydrolyzes ASA- (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Metabolism (Drosophila melanogaster)
Biological oxidations (Drosophila melanogaster)
Phase I - Functionalization of compounds (Drosophila melanogaster)
CES1 trimer.CES2 hydrolyse COCN to BEG (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Drosophila melanogaster)
Eicosanoids (Drosophila melanogaster)
CYP4F3 20-hydroxylates LTB4 (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Fatty acids (Drosophila melanogaster)
CYP4A11 omega-hydroxylates DDCX (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Drosophila melanogaster)
CYP2U1 19-hydroxylates ARA (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Drosophila melanogaster)
Fatty acid metabolism (Drosophila melanogaster)
Arachidonate metabolism (Drosophila melanogaster)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Drosophila melanogaster)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Drosophila melanogaster)
Glycosphingolipid metabolism (Drosophila melanogaster)
Glycosphingolipid biosynthesis (Drosophila melanogaster)
UGT8 transfers Gal from UDP-Gal to CERA (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Glycosphingolipid catabolism (Drosophila melanogaster)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Drosophila melanogaster)
Metabolism of fat-soluble vitamins (Drosophila melanogaster)
Metabolism of vitamin K (Drosophila melanogaster)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Drosophila melanogaster)
Peptide hormone metabolism (Drosophila melanogaster)
Metabolism of Angiotensinogen to Angiotensins (Drosophila melanogaster)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Drosophila melanogaster)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Drosophila melanogaster)
The activation of arylsulfatases (Drosophila melanogaster)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Drosophila melanogaster)
DAG1 glycosylations (Drosophila melanogaster)
DAG1 core M1 glycosylations (Drosophila melanogaster)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Drosophila melanogaster)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Drosophila melanogaster)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Drosophila melanogaster)
POFUT2 transfers fucose to TSR domain-containing proteins (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Drosophila melanogaster)
Cardiac conduction (Drosophila melanogaster)
Ion homeostasis (Drosophila melanogaster)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Drosophila melanogaster)
Ion channel transport (Drosophila melanogaster)
Ion transport by P-type ATPases (Drosophila melanogaster)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Drosophila melanogaster)
H+ [endoplasmic reticulum lumen]
Cell-Cell communication (Gallus gallus)
Cell junction organization (Gallus gallus)
Cell-cell junction organization (Gallus gallus)
Adherens junctions interactions (Gallus gallus)
Regulation of Homotypic Cell-Cell Adhesion (Gallus gallus)
Regulation of Expression and Function of Type I Classical Cadherins (Gallus gallus)
Regulation of CDH1 Expression and Function (Gallus gallus)
Regulation of CDH1 posttranslational processing and trafficking to plasma membrane (Gallus gallus)
CDH1 is O-manosylated (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Drug ADME (Gallus gallus)
Aspirin ADME (Gallus gallus)
CES1,CES2 hydrolyze ASA- to ST (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Metabolism (Gallus gallus)
Biological oxidations (Gallus gallus)
Phase I - Functionalization of compounds (Gallus gallus)
CES1 trimer.CES2 hydrolyse COCN to BEG (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Gallus gallus)
Eicosanoids (Gallus gallus)
CYP4F3 20-hydroxylates LTB4 (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Fatty acids (Gallus gallus)
CYP2J2 oxidises ARA (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP4A11 omega-hydroxylates DDCX (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Gallus gallus)
CYP2U1 19-hydroxylates ARA (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP3A43 6b-hydroxylates TEST (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Vitamins (Gallus gallus)
CYP26A1,B1 4-hydroxylate atRA (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Gallus gallus)
CYP2D6 4-hydroxylates debrisoquine (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Gallus gallus)
Benzene is hydroxylated to phenol (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Gallus gallus)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP3A4 can N-demethylate loperamide (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP3A4,5 oxidise AFB1 to AFXBO (Gallus gallus)
H+ [endoplasmic reticulum lumen]
CYP3A7 can 6beta-hydroxylate testosterone (Gallus gallus)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Gallus gallus)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Gallus gallus)
FMO1:FAD N-oxidises TAM (Gallus gallus)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Gallus gallus)
Fatty acid metabolism (Gallus gallus)
Arachidonate metabolism (Gallus gallus)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Gallus gallus)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Gallus gallus)
Glycosphingolipid metabolism (Gallus gallus)
Glycosphingolipid biosynthesis (Gallus gallus)
UGT8 transfers Gal from UDP-Gal to CERA (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Glycosphingolipid catabolism (Gallus gallus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Gallus gallus)
Metabolism of fat-soluble vitamins (Gallus gallus)
Metabolism of vitamin K (Gallus gallus)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Gallus gallus)
Peptide hormone metabolism (Gallus gallus)
Metabolism of Angiotensinogen to Angiotensins (Gallus gallus)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Gallus gallus)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Gallus gallus)
The activation of arylsulfatases (Gallus gallus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Gallus gallus)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Gallus gallus)
DAG1 glycosylations (Gallus gallus)
DAG1 core M1 glycosylations (Gallus gallus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Gallus gallus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Gallus gallus)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Gallus gallus)
H+ [endoplasmic reticulum lumen]
POMGNT2 transfers GlcNAc to Man-DAG1 (Gallus gallus)
H+ [endoplasmic reticulum lumen]
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Gallus gallus)
H+ [endoplasmic reticulum lumen]
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Gallus gallus)
H+ [endoplasmic reticulum lumen]
FUT10 O-fucosylates EMI domain-containing proteins (Gallus gallus)
H+ [endoplasmic reticulum lumen]
FUT11 O-fucosylates EMI domain-containing proteins (Gallus gallus)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Gallus gallus)
POFUT2 transfers fucose to TSR domain-containing proteins (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Gallus gallus)
Cardiac conduction (Gallus gallus)
Ion homeostasis (Gallus gallus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Gallus gallus)
Ion channel transport (Gallus gallus)
Ion transport by P-type ATPases (Gallus gallus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Gallus gallus)
H+ [endoplasmic reticulum lumen]
Cell-Cell communication (Homo sapiens)
Cell junction organization (Homo sapiens)
Cell-cell junction organization (Homo sapiens)
Adherens junctions interactions (Homo sapiens)
Regulation of Homotypic Cell-Cell Adhesion (Homo sapiens)
Regulation of Expression and Function of Type I Classical Cadherins (Homo sapiens)
Regulation of CDH1 Expression and Function (Homo sapiens)
Regulation of CDH1 posttranslational processing and trafficking to plasma membrane (Homo sapiens)
CDH1 is O-manosylated (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Disease (Homo sapiens)
Diseases of metabolism (Homo sapiens)
Metabolic disorders of biological oxidation enzymes (Homo sapiens)
Defective CYP26B1 causes RHFCA (Homo sapiens)
Defective CYP26B1 does not 4-hydroxylate atRA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Defective CYP2U1 causes SPG56 (Homo sapiens)
Defective CYP2U1 does not omega-hydroxylate ARA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Defective FMO3 causes TMAU (Homo sapiens)
Defective FMO3 does not N-oxidise TMA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Infectious disease (Homo sapiens)
Viral Infection Pathways (Homo sapiens)
SARS-CoV Infections (Homo sapiens)
SARS-CoV-1 Infection (Homo sapiens)
Translation of Structural Proteins (Homo sapiens)
Maturation of protein E (Homo sapiens)
E protein gets N-glycosylated (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Maturation of protein M (Homo sapiens)
M protein gets N-glycosylated (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Maturation of spike protein (Homo sapiens)
Spike protein gets N-glycosylated (Homo sapiens)
H+ [endoplasmic reticulum lumen]
SARS-CoV-2 Infection (Homo sapiens)
Late SARS-CoV-2 Infection Events (Homo sapiens)
Translation of Structural Proteins (Homo sapiens)
Maturation of protein E (Homo sapiens)
E protein gets N-glycosylated (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Maturation of protein M (Homo sapiens)
M protein gets N-glycosylated (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Drug ADME (Homo sapiens)
Aspirin ADME (Homo sapiens)
CES1,CES2 hydrolyze ASA- to ST (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CES2 hydrolyzes ASA- (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Metabolism (Homo sapiens)
Biological oxidations (Homo sapiens)
Phase I - Functionalization of compounds (Homo sapiens)
CES1 trimer.CES2 hydrolyse COCN to BEG (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Homo sapiens)
Eicosanoids (Homo sapiens)
CYP4F3 20-hydroxylates LTB4 (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Fatty acids (Homo sapiens)
CYP2J2 oxidises ARA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP4A11 omega-hydroxylates DDCX (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Homo sapiens)
CYP2S1 4-hydroxylates atRA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP3A43 6b-hydroxylates TEST (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Vitamins (Homo sapiens)
CYP26A1,B1 4-hydroxylate atRA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Homo sapiens)
Aromatic amines can be N-hydroxylated or N-dealkylated by CYP1A2 (Homo sapiens)
N-atom dealkylation of caffeine (Homo sapiens)
H+ [endoplasmic reticulum lumen]
N-hydroxylation of 4-aminobiphenyl (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP2C19 5-hydroxylates omeprazole (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP2D6 4-hydroxylates debrisoquine (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Homo sapiens)
Benzene is hydroxylated to phenol (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Homo sapiens)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP3A4 can N-demethylate loperamide (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP3A4,5 oxidise AFB1 to AFXBO (Homo sapiens)
H+ [endoplasmic reticulum lumen]
CYP3A7 can 6beta-hydroxylate testosterone (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Homo sapiens)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Homo sapiens)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Homo sapiens)
FMO1:FAD N-oxidises TAM (Homo sapiens)
H+ [endoplasmic reticulum lumen]
FMO2:FAD:Mg2+ S-oxidises MTZ (Homo sapiens)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Phase II - Conjugation of compounds (Homo sapiens)
Methylation (Homo sapiens)
CYP1A2 S-demethylates 6MMP (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Homo sapiens)
Fatty acid metabolism (Homo sapiens)
Arachidonate metabolism (Homo sapiens)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Homo sapiens)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Synthesis of Prostaglandins (PG) and Thromboxanes (TX) (Homo sapiens)
TXB2 is converted to 11dh-TXB2 by TXDH (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Homo sapiens)
Glycosphingolipid metabolism (Homo sapiens)
Glycosphingolipid biosynthesis (Homo sapiens)
UGT8 transfers Gal from UDP-Gal to CERA (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Glycosphingolipid catabolism (Homo sapiens)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Homo sapiens)
Metabolism of fat-soluble vitamins (Homo sapiens)
Metabolism of vitamin K (Homo sapiens)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Homo sapiens)
Peptide hormone metabolism (Homo sapiens)
Metabolism of Angiotensinogen to Angiotensins (Homo sapiens)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Homo sapiens)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Homo sapiens)
The activation of arylsulfatases (Homo sapiens)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Homo sapiens)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Homo sapiens)
DAG1 glycosylations (Homo sapiens)
DAG1 core M1 glycosylations (Homo sapiens)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Homo sapiens)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Homo sapiens)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Homo sapiens)
H+ [endoplasmic reticulum lumen]
POMGNT2 transfers GlcNAc to Man-DAG1 (Homo sapiens)
H+ [endoplasmic reticulum lumen]
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Homo sapiens)
H+ [endoplasmic reticulum lumen]
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Homo sapiens)
H+ [endoplasmic reticulum lumen]
FUT10 O-fucosylates EMI domain-containing proteins (Homo sapiens)
H+ [endoplasmic reticulum lumen]
FUT11 O-fucosylates EMI domain-containing proteins (Homo sapiens)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Homo sapiens)
POFUT2 transfers fucose to TSR domain-containing proteins (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Homo sapiens)
Cardiac conduction (Homo sapiens)
Ion homeostasis (Homo sapiens)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Homo sapiens)
Ion channel transport (Homo sapiens)
Ion transport by P-type ATPases (Homo sapiens)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Homo sapiens)
H+ [endoplasmic reticulum lumen]
Cell-Cell communication (Mus musculus)
Cell junction organization (Mus musculus)
Cell-cell junction organization (Mus musculus)
Adherens junctions interactions (Mus musculus)
Regulation of Homotypic Cell-Cell Adhesion (Mus musculus)
Regulation of Expression and Function of Type I Classical Cadherins (Mus musculus)
Regulation of CDH1 Expression and Function (Mus musculus)
Regulation of CDH1 posttranslational processing and trafficking to plasma membrane (Mus musculus)
CDH1 is O-manosylated (Mus musculus)
H+ [endoplasmic reticulum lumen]
Drug ADME (Mus musculus)
Aspirin ADME (Mus musculus)
CES1,CES2 hydrolyze ASA- to ST (Mus musculus)
H+ [endoplasmic reticulum lumen]
CES2 hydrolyzes ASA- (Mus musculus)
H+ [endoplasmic reticulum lumen]
Metabolism (Mus musculus)
Biological oxidations (Mus musculus)
Phase I - Functionalization of compounds (Mus musculus)
CES1 trimer.CES2 hydrolyse COCN to BEG (Mus musculus)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Mus musculus)
Eicosanoids (Mus musculus)
CYP4F3 20-hydroxylates LTB4 (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Mus musculus)
H+ [endoplasmic reticulum lumen]
Fatty acids (Mus musculus)
CYP2J2 oxidises ARA (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP4A11 omega-hydroxylates DDCX (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Mus musculus)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Mus musculus)
CYP2S1 4-hydroxylates atRA (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP3A43 6b-hydroxylates TEST (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Mus musculus)
H+ [endoplasmic reticulum lumen]
Vitamins (Mus musculus)
CYP26A1,B1 4-hydroxylate atRA (Mus musculus)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Mus musculus)
Aromatic amines can be N-hydroxylated or N-dealkylated by CYP1A2 (Mus musculus)
N-atom dealkylation of caffeine (Mus musculus)
H+ [endoplasmic reticulum lumen]
N-hydroxylation of 4-aminobiphenyl (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP2C19 5-hydroxylates omeprazole (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP2D6 4-hydroxylates debrisoquine (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Mus musculus)
Benzene is hydroxylated to phenol (Mus musculus)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Mus musculus)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Mus musculus)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP3A4 can N-demethylate loperamide (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP3A4,5 oxidise AFB1 to AFXBO (Mus musculus)
H+ [endoplasmic reticulum lumen]
CYP3A7 can 6beta-hydroxylate testosterone (Mus musculus)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Mus musculus)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Mus musculus)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Mus musculus)
H+ [endoplasmic reticulum lumen]
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Mus musculus)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Mus musculus)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Mus musculus)
FMO1:FAD N-oxidises TAM (Mus musculus)
H+ [endoplasmic reticulum lumen]
FMO2:FAD:Mg2+ S-oxidises MTZ (Mus musculus)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Mus musculus)
H+ [endoplasmic reticulum lumen]
Phase II - Conjugation of compounds (Mus musculus)
Methylation (Mus musculus)
CYP1A2 S-demethylates 6MMP (Mus musculus)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Mus musculus)
Fatty acid metabolism (Mus musculus)
Arachidonate metabolism (Mus musculus)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Mus musculus)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Mus musculus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Mus musculus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Mus musculus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Mus musculus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Mus musculus)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Mus musculus)
Glycosphingolipid metabolism (Mus musculus)
Glycosphingolipid biosynthesis (Mus musculus)
UGT8 transfers Gal from UDP-Gal to CERA (Mus musculus)
H+ [endoplasmic reticulum lumen]
Glycosphingolipid catabolism (Mus musculus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Mus musculus)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Mus musculus)
Metabolism of fat-soluble vitamins (Mus musculus)
Metabolism of vitamin K (Mus musculus)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Mus musculus)
H+ [endoplasmic reticulum lumen]
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Mus musculus)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Mus musculus)
Peptide hormone metabolism (Mus musculus)
Metabolism of Angiotensinogen to Angiotensins (Mus musculus)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Mus musculus)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Mus musculus)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Mus musculus)
The activation of arylsulfatases (Mus musculus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Mus musculus)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Mus musculus)
DAG1 glycosylations (Mus musculus)
DAG1 core M1 glycosylations (Mus musculus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Mus musculus)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Mus musculus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Mus musculus)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Mus musculus)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Mus musculus)
H+ [endoplasmic reticulum lumen]
POMGNT2 transfers GlcNAc to Man-DAG1 (Mus musculus)
H+ [endoplasmic reticulum lumen]
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Mus musculus)
H+ [endoplasmic reticulum lumen]
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Mus musculus)
H+ [endoplasmic reticulum lumen]
FUT10 O-fucosylates EMI domain-containing proteins (Mus musculus)
H+ [endoplasmic reticulum lumen]
FUT11 O-fucosylates EMI domain-containing proteins (Mus musculus)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Mus musculus)
POFUT2 transfers fucose to TSR domain-containing proteins (Mus musculus)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Mus musculus)
Cardiac conduction (Mus musculus)
Ion homeostasis (Mus musculus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Mus musculus)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Mus musculus)
Ion channel transport (Mus musculus)
Ion transport by P-type ATPases (Mus musculus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Mus musculus)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Plasmodium falciparum)
Post-translational protein modification (Plasmodium falciparum)
O-linked glycosylation (Plasmodium falciparum)
O-glycosylation of TSR domain-containing proteins (Plasmodium falciparum)
POFUT2 transfers fucose to TSR domain-containing proteins (Plasmodium falciparum)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Plasmodium falciparum)
Cardiac conduction (Plasmodium falciparum)
Ion homeostasis (Plasmodium falciparum)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Plasmodium falciparum)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Plasmodium falciparum)
Ion channel transport (Plasmodium falciparum)
Ion transport by P-type ATPases (Plasmodium falciparum)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Plasmodium falciparum)
H+ [endoplasmic reticulum lumen]
Cell-Cell communication (Rattus norvegicus)
Cell junction organization (Rattus norvegicus)
Cell-cell junction organization (Rattus norvegicus)
Adherens junctions interactions (Rattus norvegicus)
Regulation of Homotypic Cell-Cell Adhesion (Rattus norvegicus)
Regulation of Expression and Function of Type I Classical Cadherins (Rattus norvegicus)
Regulation of CDH1 Expression and Function (Rattus norvegicus)
Regulation of CDH1 posttranslational processing and trafficking to plasma membrane (Rattus norvegicus)
CDH1 is O-manosylated (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Drug ADME (Rattus norvegicus)
Aspirin ADME (Rattus norvegicus)
CES1,CES2 hydrolyze ASA- to ST (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CES2 hydrolyzes ASA- (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Metabolism (Rattus norvegicus)
Biological oxidations (Rattus norvegicus)
Phase I - Functionalization of compounds (Rattus norvegicus)
CES1 trimer.CES2 hydrolyse COCN to BEG (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Rattus norvegicus)
Eicosanoids (Rattus norvegicus)
CYP4F3 20-hydroxylates LTB4 (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Fatty acids (Rattus norvegicus)
CYP2J2 oxidises ARA (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP4A11 omega-hydroxylates DDCX (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Rattus norvegicus)
CYP2S1 4-hydroxylates atRA (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP3A43 6b-hydroxylates TEST (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Vitamins (Rattus norvegicus)
CYP26A1,B1 4-hydroxylate atRA (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Rattus norvegicus)
Aromatic amines can be N-hydroxylated or N-dealkylated by CYP1A2 (Rattus norvegicus)
N-atom dealkylation of caffeine (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
N-hydroxylation of 4-aminobiphenyl (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP2C19 5-hydroxylates omeprazole (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP2D6 4-hydroxylates debrisoquine (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Rattus norvegicus)
Benzene is hydroxylated to phenol (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP3A4 can N-demethylate loperamide (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP3A4,5 oxidise AFB1 to AFXBO (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
CYP3A7 can 6beta-hydroxylate testosterone (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Rattus norvegicus)
FMO1:FAD N-oxidises TAM (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
FMO2:FAD:Mg2+ S-oxidises MTZ (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Phase II - Conjugation of compounds (Rattus norvegicus)
Methylation (Rattus norvegicus)
CYP1A2 S-demethylates 6MMP (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Rattus norvegicus)
Fatty acid metabolism (Rattus norvegicus)
Arachidonate metabolism (Rattus norvegicus)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Rattus norvegicus)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Rattus norvegicus)
Glycosphingolipid metabolism (Rattus norvegicus)
Glycosphingolipid biosynthesis (Rattus norvegicus)
UGT8 transfers Gal from UDP-Gal to CERA (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Glycosphingolipid catabolism (Rattus norvegicus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Rattus norvegicus)
Metabolism of fat-soluble vitamins (Rattus norvegicus)
Metabolism of vitamin K (Rattus norvegicus)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Rattus norvegicus)
Peptide hormone metabolism (Rattus norvegicus)
Metabolism of Angiotensinogen to Angiotensins (Rattus norvegicus)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Rattus norvegicus)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Rattus norvegicus)
The activation of arylsulfatases (Rattus norvegicus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Rattus norvegicus)
DAG1 glycosylations (Rattus norvegicus)
DAG1 core M1 glycosylations (Rattus norvegicus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Rattus norvegicus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Rattus norvegicus)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
POMGNT2 transfers GlcNAc to Man-DAG1 (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
FUT10 O-fucosylates EMI domain-containing proteins (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
FUT11 O-fucosylates EMI domain-containing proteins (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Rattus norvegicus)
POFUT2 transfers fucose to TSR domain-containing proteins (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Rattus norvegicus)
Cardiac conduction (Rattus norvegicus)
Ion homeostasis (Rattus norvegicus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Rattus norvegicus)
Ion channel transport (Rattus norvegicus)
Ion transport by P-type ATPases (Rattus norvegicus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Rattus norvegicus)
H+ [endoplasmic reticulum lumen]
Cell-Cell communication (Sus scrofa)
Cell junction organization (Sus scrofa)
Cell-cell junction organization (Sus scrofa)
Adherens junctions interactions (Sus scrofa)
Regulation of Homotypic Cell-Cell Adhesion (Sus scrofa)
Regulation of Expression and Function of Type I Classical Cadherins (Sus scrofa)
Regulation of CDH1 Expression and Function (Sus scrofa)
Regulation of CDH1 posttranslational processing and trafficking to plasma membrane (Sus scrofa)
CDH1 is O-manosylated (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Drug ADME (Sus scrofa)
Aspirin ADME (Sus scrofa)
CES1,CES2 hydrolyze ASA- to ST (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Metabolism (Sus scrofa)
Biological oxidations (Sus scrofa)
Phase I - Functionalization of compounds (Sus scrofa)
CES1 trimer.CES2 hydrolyse COCN to BEG (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Sus scrofa)
Eicosanoids (Sus scrofa)
CYP4F3 20-hydroxylates LTB4 (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Fatty acids (Sus scrofa)
CYP2J2 oxidises ARA (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP4A11 omega-hydroxylates DDCX (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Sus scrofa)
CYP2S1 4-hydroxylates atRA (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP3A43 6b-hydroxylates TEST (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Vitamins (Sus scrofa)
CYP26A1,B1 4-hydroxylate atRA (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Sus scrofa)
Aromatic amines can be N-hydroxylated or N-dealkylated by CYP1A2 (Sus scrofa)
N-atom dealkylation of caffeine (Sus scrofa)
H+ [endoplasmic reticulum lumen]
N-hydroxylation of 4-aminobiphenyl (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP2D6 4-hydroxylates debrisoquine (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Sus scrofa)
Benzene is hydroxylated to phenol (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Sus scrofa)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP3A4 can N-demethylate loperamide (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP3A4,5 oxidise AFB1 to AFXBO (Sus scrofa)
H+ [endoplasmic reticulum lumen]
CYP3A7 can 6beta-hydroxylate testosterone (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Sus scrofa)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Sus scrofa)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Sus scrofa)
FMO1:FAD N-oxidises TAM (Sus scrofa)
H+ [endoplasmic reticulum lumen]
FMO2:FAD:Mg2+ S-oxidises MTZ (Sus scrofa)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Phase II - Conjugation of compounds (Sus scrofa)
Methylation (Sus scrofa)
CYP1A2 S-demethylates 6MMP (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Sus scrofa)
Fatty acid metabolism (Sus scrofa)
Arachidonate metabolism (Sus scrofa)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Sus scrofa)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Sus scrofa)
Glycosphingolipid metabolism (Sus scrofa)
Glycosphingolipid biosynthesis (Sus scrofa)
UGT8 transfers Gal from UDP-Gal to CERA (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Glycosphingolipid catabolism (Sus scrofa)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Sus scrofa)
Metabolism of fat-soluble vitamins (Sus scrofa)
Metabolism of vitamin K (Sus scrofa)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Sus scrofa)
Peptide hormone metabolism (Sus scrofa)
Metabolism of Angiotensinogen to Angiotensins (Sus scrofa)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Sus scrofa)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Sus scrofa)
The activation of arylsulfatases (Sus scrofa)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Sus scrofa)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Sus scrofa)
DAG1 glycosylations (Sus scrofa)
DAG1 core M1 glycosylations (Sus scrofa)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Sus scrofa)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Sus scrofa)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Sus scrofa)
H+ [endoplasmic reticulum lumen]
POMGNT2 transfers GlcNAc to Man-DAG1 (Sus scrofa)
H+ [endoplasmic reticulum lumen]
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Sus scrofa)
H+ [endoplasmic reticulum lumen]
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Sus scrofa)
H+ [endoplasmic reticulum lumen]
FUT10 O-fucosylates EMI domain-containing proteins (Sus scrofa)
H+ [endoplasmic reticulum lumen]
FUT11 O-fucosylates EMI domain-containing proteins (Sus scrofa)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Sus scrofa)
POFUT2 transfers fucose to TSR domain-containing proteins (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Sus scrofa)
Cardiac conduction (Sus scrofa)
Ion homeostasis (Sus scrofa)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Sus scrofa)
Ion channel transport (Sus scrofa)
Ion transport by P-type ATPases (Sus scrofa)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Sus scrofa)
H+ [endoplasmic reticulum lumen]
Cell-Cell communication (Xenopus tropicalis)
Cell junction organization (Xenopus tropicalis)
Cell-cell junction organization (Xenopus tropicalis)
Adherens junctions interactions (Xenopus tropicalis)
Regulation of Homotypic Cell-Cell Adhesion (Xenopus tropicalis)
Regulation of Expression and Function of Type I Classical Cadherins (Xenopus tropicalis)
Regulation of CDH1 Expression and Function (Xenopus tropicalis)
Regulation of CDH1 posttranslational processing and trafficking to plasma membrane (Xenopus tropicalis)
CDH1 is O-manosylated (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Drug ADME (Xenopus tropicalis)
Aspirin ADME (Xenopus tropicalis)
CES1,CES2 hydrolyze ASA- to ST (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Metabolism (Xenopus tropicalis)
Biological oxidations (Xenopus tropicalis)
Phase I - Functionalization of compounds (Xenopus tropicalis)
CES1 trimer.CES2 hydrolyse COCN to BEG (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Cytochrome P450 - arranged by substrate type (Xenopus tropicalis)
Eicosanoids (Xenopus tropicalis)
CYP4F3 20-hydroxylates LTB4 (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP4F8 19-hydroxylates PGH2 (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Fatty acids (Xenopus tropicalis)
CYP4A11 omega-hydroxylates DDCX (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP4B1 12-hydroxylates ARA (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP4F12 18-hydroxylates ARA (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Miscellaneous substrates (Xenopus tropicalis)
CYP2S1 4-hydroxylates atRA (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP2U1 19-hydroxylates ARA (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP2W1 oxidises INDOL (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP3A43 6b-hydroxylates TEST (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP4F11 16-hydroxylates 3OH-PALM (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Vitamins (Xenopus tropicalis)
CYP26A1,B1 4-hydroxylate atRA (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Xenobiotics (Xenopus tropicalis)
CYP2D6 4-hydroxylates debrisoquine (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP2E1 reactions (Xenopus tropicalis)
Benzene is hydroxylated to phenol (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
MEOS oxidizes ethanol to acetaldehyde (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP2F1 dehydrogenates 3-methylindole (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP3A4 can N-demethylate loperamide (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP3A4,5 oxidise AFB1 to AFXBO (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
CYP3A7 can 6beta-hydroxylate testosterone (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A13 (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Coumarin is 7-hydroxylated by CYP2A6 (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
O-atom dealkylation of dextromethorphan (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
FMO oxidises nucleophiles (Xenopus tropicalis)
FMO1:FAD N-oxidises TAM (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
FMO2:FAD:Mg2+ S-oxidises MTZ (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
FMO3:FAD N-oxidises TMA to TMAO (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Metabolism of lipids (Xenopus tropicalis)
Fatty acid metabolism (Xenopus tropicalis)
Arachidonate metabolism (Xenopus tropicalis)
Synthesis of (16-20)-hydroxyeicosatetraenoic acids (HETE) (Xenopus tropicalis)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Sphingolipid metabolism (Xenopus tropicalis)
Glycosphingolipid metabolism (Xenopus tropicalis)
Glycosphingolipid catabolism (Xenopus tropicalis)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Metabolism of vitamins and cofactors (Xenopus tropicalis)
Metabolism of fat-soluble vitamins (Xenopus tropicalis)
Metabolism of vitamin K (Xenopus tropicalis)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Metabolism of proteins (Xenopus tropicalis)
Peptide hormone metabolism (Xenopus tropicalis)
Metabolism of Angiotensinogen to Angiotensins (Xenopus tropicalis)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Post-translational protein modification (Xenopus tropicalis)
Gamma carboxylation, hypusinylation, hydroxylation, and arylsulfatase activation (Xenopus tropicalis)
The activation of arylsulfatases (Xenopus tropicalis)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
O-linked glycosylation (Xenopus tropicalis)
DAG1 glycosylations (Xenopus tropicalis)
DAG1 core M1 glycosylations (Xenopus tropicalis)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
DAG1 core M2 glycosylations (Xenopus tropicalis)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
DAG1 core M3 glycosylations (Xenopus tropicalis)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
POMGNT2 transfers GlcNAc to Man-DAG1 (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
O-glycosylation of TSR domain-containing proteins (Xenopus tropicalis)
POFUT2 transfers fucose to TSR domain-containing proteins (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Muscle contraction (Xenopus tropicalis)
Cardiac conduction (Xenopus tropicalis)
Ion homeostasis (Xenopus tropicalis)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
Transport of small molecules (Xenopus tropicalis)
Ion channel transport (Xenopus tropicalis)
Ion transport by P-type ATPases (Xenopus tropicalis)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Xenopus tropicalis)
H+ [endoplasmic reticulum lumen]
External Reference Information
External Reference
hydron [ChEBI:15378]
Participates
as an input of
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Gallus gallus)
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Danio rerio)
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Sus scrofa)
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Bos taurus)
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Canis familiaris)
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Rattus norvegicus)
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Mus musculus)
Arachidonate is hydroxylated to 17-HETE by CYP(1) (Homo sapiens)
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Gallus gallus)
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Danio rerio)
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Sus scrofa)
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Bos taurus)
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Canis familiaris)
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Rattus norvegicus)
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Mus musculus)
Arachidonate is hydroxylated to 18-HETE by CYP(1) (Homo sapiens)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Dictyostelium discoideum)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Caenorhabditis elegans)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Drosophila melanogaster)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Gallus gallus)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Xenopus tropicalis)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Danio rerio)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Sus scrofa)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Bos taurus)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Canis familiaris)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Rattus norvegicus)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Mus musculus)
Arachidonate is hydroxylated to 19-HETE by CYP(2) (Homo sapiens)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Dictyostelium discoideum)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Caenorhabditis elegans)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Drosophila melanogaster)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Gallus gallus)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Xenopus tropicalis)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Danio rerio)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Sus scrofa)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Bos taurus)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Canis familiaris)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Rattus norvegicus)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Mus musculus)
Arachidonate is hydroxylated to 20-HETE by CYP(3) (Homo sapiens)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Gallus gallus)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Danio rerio)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Sus scrofa)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Bos taurus)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Canis familiaris)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Rattus norvegicus)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Mus musculus)
Arachidonate is hydroxylated to 16-HETE by CYP(1) (Homo sapiens)
Defective FMO3 does not N-oxidise TMA (Homo sapiens)
Defective CYP2U1 does not omega-hydroxylate ARA (Homo sapiens)
Defective CYP26B1 does not 4-hydroxylate atRA (Homo sapiens)
CYP26A1,B1 4-hydroxylate atRA (Gallus gallus)
CYP26A1,B1 4-hydroxylate atRA (Xenopus tropicalis)
CYP26A1,B1 4-hydroxylate atRA (Danio rerio)
CYP26A1,B1 4-hydroxylate atRA (Sus scrofa)
CYP26A1,B1 4-hydroxylate atRA (Bos taurus)
CYP26A1,B1 4-hydroxylate atRA (Canis familiaris)
CYP26A1,B1 4-hydroxylate atRA (Rattus norvegicus)
CYP26A1,B1 4-hydroxylate atRA (Mus musculus)
CYP26A1,B1 4-hydroxylate atRA (Homo sapiens)
CYP2D6 4-hydroxylates debrisoquine (Dictyostelium discoideum)
CYP2D6 4-hydroxylates debrisoquine (Caenorhabditis elegans)
CYP2D6 4-hydroxylates debrisoquine (Gallus gallus)
CYP2D6 4-hydroxylates debrisoquine (Xenopus tropicalis)
CYP2D6 4-hydroxylates debrisoquine (Danio rerio)
CYP2D6 4-hydroxylates debrisoquine (Sus scrofa)
CYP2D6 4-hydroxylates debrisoquine (Bos taurus)
CYP2D6 4-hydroxylates debrisoquine (Canis familiaris)
CYP2D6 4-hydroxylates debrisoquine (Rattus norvegicus)
CYP2D6 4-hydroxylates debrisoquine (Mus musculus)
CYP2D6 4-hydroxylates debrisoquine (Homo sapiens)
MEOS oxidizes ethanol to acetaldehyde (Dictyostelium discoideum)
MEOS oxidizes ethanol to acetaldehyde (Caenorhabditis elegans)
MEOS oxidizes ethanol to acetaldehyde (Gallus gallus)
MEOS oxidizes ethanol to acetaldehyde (Xenopus tropicalis)
MEOS oxidizes ethanol to acetaldehyde (Danio rerio)
MEOS oxidizes ethanol to acetaldehyde (Sus scrofa)
MEOS oxidizes ethanol to acetaldehyde (Bos taurus)
MEOS oxidizes ethanol to acetaldehyde (Canis familiaris)
MEOS oxidizes ethanol to acetaldehyde (Rattus norvegicus)
MEOS oxidizes ethanol to acetaldehyde (Mus musculus)
MEOS oxidizes ethanol to acetaldehyde (Homo sapiens)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Dictyostelium discoideum)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Caenorhabditis elegans)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Gallus gallus)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Xenopus tropicalis)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Danio rerio)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Sus scrofa)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Bos taurus)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Canis familiaris)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Rattus norvegicus)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Mus musculus)
Dehalogenation of the poly-halogenated hydrocarbon Halothane to form the acylhalide Trifluoroacetlychloride and hydrogen bromide (Homo sapiens)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Dictyostelium discoideum)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Caenorhabditis elegans)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Gallus gallus)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Xenopus tropicalis)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Danio rerio)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Sus scrofa)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Bos taurus)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Canis familiaris)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Rattus norvegicus)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Mus musculus)
Vinyl chloride is oxidized to 2-Chloroethylene oxide (Homo sapiens)
Benzene is hydroxylated to phenol (Dictyostelium discoideum)
Benzene is hydroxylated to phenol (Caenorhabditis elegans)
Benzene is hydroxylated to phenol (Gallus gallus)
Benzene is hydroxylated to phenol (Xenopus tropicalis)
Benzene is hydroxylated to phenol (Danio rerio)
Benzene is hydroxylated to phenol (Sus scrofa)
Benzene is hydroxylated to phenol (Bos taurus)
Benzene is hydroxylated to phenol (Canis familiaris)
Benzene is hydroxylated to phenol (Rattus norvegicus)
Benzene is hydroxylated to phenol (Mus musculus)
Benzene is hydroxylated to phenol (Homo sapiens)
CYP2C19 5-hydroxylates omeprazole (Dictyostelium discoideum)
CYP2C19 5-hydroxylates omeprazole (Caenorhabditis elegans)
CYP2C19 5-hydroxylates omeprazole (Bos taurus)
CYP2C19 5-hydroxylates omeprazole (Rattus norvegicus)
CYP2C19 5-hydroxylates omeprazole (Mus musculus)
CYP2C19 5-hydroxylates omeprazole (Homo sapiens)
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Dictyostelium discoideum)
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Caenorhabditis elegans)
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Bos taurus)
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Rattus norvegicus)
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Mus musculus)
CYP2C9 inactivates tolbutamide by 4methyl-hydroxylation (Homo sapiens)
N-atom dealkylation of caffeine (Danio rerio)
N-atom dealkylation of caffeine (Sus scrofa)
N-atom dealkylation of caffeine (Bos taurus)
N-atom dealkylation of caffeine (Rattus norvegicus)
N-atom dealkylation of caffeine (Mus musculus)
N-atom dealkylation of caffeine (Homo sapiens)
CYP3A4,5 oxidise AFB1 to AFXBO (Gallus gallus)
CYP3A4,5 oxidise AFB1 to AFXBO (Xenopus tropicalis)
CYP3A4,5 oxidise AFB1 to AFXBO (Danio rerio)
CYP3A4,5 oxidise AFB1 to AFXBO (Sus scrofa)
CYP3A4,5 oxidise AFB1 to AFXBO (Bos taurus)
CYP3A4,5 oxidise AFB1 to AFXBO (Canis familiaris)
CYP3A4,5 oxidise AFB1 to AFXBO (Rattus norvegicus)
CYP3A4,5 oxidise AFB1 to AFXBO (Mus musculus)
CYP3A4,5 oxidise AFB1 to AFXBO (Homo sapiens)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Dictyostelium discoideum)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Caenorhabditis elegans)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Xenopus tropicalis)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Danio rerio)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Sus scrofa)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Bos taurus)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Canis familiaris)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Rattus norvegicus)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Mus musculus)
Cyclophosphamide is 4-hydroxylated by CYP2B6 (Homo sapiens)
CYP3A4 can N-demethylate loperamide (Gallus gallus)
CYP3A4 can N-demethylate loperamide (Xenopus tropicalis)
CYP3A4 can N-demethylate loperamide (Danio rerio)
CYP3A4 can N-demethylate loperamide (Sus scrofa)
CYP3A4 can N-demethylate loperamide (Bos taurus)
CYP3A4 can N-demethylate loperamide (Canis familiaris)
CYP3A4 can N-demethylate loperamide (Rattus norvegicus)
CYP3A4 can N-demethylate loperamide (Mus musculus)
CYP3A4 can N-demethylate loperamide (Homo sapiens)
Coumarin is 7-hydroxylated by CYP2A13 (Dictyostelium discoideum)
Coumarin is 7-hydroxylated by CYP2A13 (Caenorhabditis elegans)
Coumarin is 7-hydroxylated by CYP2A13 (Xenopus tropicalis)
Coumarin is 7-hydroxylated by CYP2A13 (Danio rerio)
Coumarin is 7-hydroxylated by CYP2A13 (Sus scrofa)
Coumarin is 7-hydroxylated by CYP2A13 (Bos taurus)
Coumarin is 7-hydroxylated by CYP2A13 (Canis familiaris)
Coumarin is 7-hydroxylated by CYP2A13 (Rattus norvegicus)
Coumarin is 7-hydroxylated by CYP2A13 (Mus musculus)
Coumarin is 7-hydroxylated by CYP2A13 (Homo sapiens)
CYP3A7 can 6beta-hydroxylate testosterone (Gallus gallus)
CYP3A7 can 6beta-hydroxylate testosterone (Xenopus tropicalis)
CYP3A7 can 6beta-hydroxylate testosterone (Danio rerio)
CYP3A7 can 6beta-hydroxylate testosterone (Sus scrofa)
CYP3A7 can 6beta-hydroxylate testosterone (Bos taurus)
CYP3A7 can 6beta-hydroxylate testosterone (Canis familiaris)
CYP3A7 can 6beta-hydroxylate testosterone (Rattus norvegicus)
CYP3A7 can 6beta-hydroxylate testosterone (Mus musculus)
CYP3A7 can 6beta-hydroxylate testosterone (Homo sapiens)
O-atom dealkylation of dextromethorphan (Dictyostelium discoideum)
O-atom dealkylation of dextromethorphan (Caenorhabditis elegans)
O-atom dealkylation of dextromethorphan (Gallus gallus)
O-atom dealkylation of dextromethorphan (Xenopus tropicalis)
O-atom dealkylation of dextromethorphan (Danio rerio)
O-atom dealkylation of dextromethorphan (Sus scrofa)
O-atom dealkylation of dextromethorphan (Bos taurus)
O-atom dealkylation of dextromethorphan (Canis familiaris)
O-atom dealkylation of dextromethorphan (Rattus norvegicus)
O-atom dealkylation of dextromethorphan (Mus musculus)
O-atom dealkylation of dextromethorphan (Homo sapiens)
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Dictyostelium discoideum)
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Caenorhabditis elegans)
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Sus scrofa)
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Bos taurus)
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Rattus norvegicus)
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Mus musculus)
CYP2C18 initiates bioactivation of phenytoin by 4-hydroxylation (Homo sapiens)
CYP2F1 dehydrogenates 3-methylindole (Dictyostelium discoideum)
CYP2F1 dehydrogenates 3-methylindole (Caenorhabditis elegans)
CYP2F1 dehydrogenates 3-methylindole (Xenopus tropicalis)
CYP2F1 dehydrogenates 3-methylindole (Danio rerio)
CYP2F1 dehydrogenates 3-methylindole (Sus scrofa)
CYP2F1 dehydrogenates 3-methylindole (Bos taurus)
CYP2F1 dehydrogenates 3-methylindole (Canis familiaris)
CYP2F1 dehydrogenates 3-methylindole (Rattus norvegicus)
CYP2F1 dehydrogenates 3-methylindole (Mus musculus)
CYP2F1 dehydrogenates 3-methylindole (Homo sapiens)
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Dictyostelium discoideum)
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Caenorhabditis elegans)
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Bos taurus)
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Rattus norvegicus)
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Mus musculus)
CYP2C8 inactivates paclitaxel by 6alpha-hydroxylation (Homo sapiens)
Coumarin is 7-hydroxylated by CYP2A6 (Dictyostelium discoideum)
Coumarin is 7-hydroxylated by CYP2A6 (Caenorhabditis elegans)
Coumarin is 7-hydroxylated by CYP2A6 (Xenopus tropicalis)
Coumarin is 7-hydroxylated by CYP2A6 (Danio rerio)
Coumarin is 7-hydroxylated by CYP2A6 (Sus scrofa)
Coumarin is 7-hydroxylated by CYP2A6 (Bos taurus)
Coumarin is 7-hydroxylated by CYP2A6 (Canis familiaris)
Coumarin is 7-hydroxylated by CYP2A6 (Rattus norvegicus)
Coumarin is 7-hydroxylated by CYP2A6 (Mus musculus)
Coumarin is 7-hydroxylated by CYP2A6 (Homo sapiens)
CYP2J2 oxidises ARA (Dictyostelium discoideum)
CYP2J2 oxidises ARA (Caenorhabditis elegans)
CYP2J2 oxidises ARA (Gallus gallus)
CYP2J2 oxidises ARA (Danio rerio)
CYP2J2 oxidises ARA (Sus scrofa)
CYP2J2 oxidises ARA (Bos taurus)
CYP2J2 oxidises ARA (Canis familiaris)
CYP2J2 oxidises ARA (Rattus norvegicus)
CYP2J2 oxidises ARA (Mus musculus)
CYP2J2 oxidises ARA (Homo sapiens)
CYP4B1 12-hydroxylates ARA (Drosophila melanogaster)
CYP4B1 12-hydroxylates ARA (Gallus gallus)
CYP4B1 12-hydroxylates ARA (Xenopus tropicalis)
CYP4B1 12-hydroxylates ARA (Danio rerio)
CYP4B1 12-hydroxylates ARA (Sus scrofa)
CYP4B1 12-hydroxylates ARA (Bos taurus)
CYP4B1 12-hydroxylates ARA (Canis familiaris)
CYP4B1 12-hydroxylates ARA (Rattus norvegicus)
CYP4B1 12-hydroxylates ARA (Mus musculus)
CYP4B1 12-hydroxylates ARA (Homo sapiens)
CYP4F12 18-hydroxylates ARA (Drosophila melanogaster)
CYP4F12 18-hydroxylates ARA (Gallus gallus)
CYP4F12 18-hydroxylates ARA (Xenopus tropicalis)
CYP4F12 18-hydroxylates ARA (Danio rerio)
CYP4F12 18-hydroxylates ARA (Sus scrofa)
CYP4F12 18-hydroxylates ARA (Bos taurus)
CYP4F12 18-hydroxylates ARA (Canis familiaris)
CYP4F12 18-hydroxylates ARA (Rattus norvegicus)
CYP4F12 18-hydroxylates ARA (Mus musculus)
CYP4F12 18-hydroxylates ARA (Homo sapiens)
CYP4A11 omega-hydroxylates DDCX (Drosophila melanogaster)
CYP4A11 omega-hydroxylates DDCX (Gallus gallus)
CYP4A11 omega-hydroxylates DDCX (Xenopus tropicalis)
CYP4A11 omega-hydroxylates DDCX (Danio rerio)
CYP4A11 omega-hydroxylates DDCX (Sus scrofa)
CYP4A11 omega-hydroxylates DDCX (Bos taurus)
CYP4A11 omega-hydroxylates DDCX (Canis familiaris)
CYP4A11 omega-hydroxylates DDCX (Rattus norvegicus)
CYP4A11 omega-hydroxylates DDCX (Mus musculus)
CYP4A11 omega-hydroxylates DDCX (Homo sapiens)
CYP4F8 19-hydroxylates PGH2 (Drosophila melanogaster)
CYP4F8 19-hydroxylates PGH2 (Gallus gallus)
CYP4F8 19-hydroxylates PGH2 (Xenopus tropicalis)
CYP4F8 19-hydroxylates PGH2 (Danio rerio)
CYP4F8 19-hydroxylates PGH2 (Sus scrofa)
CYP4F8 19-hydroxylates PGH2 (Bos taurus)
CYP4F8 19-hydroxylates PGH2 (Canis familiaris)
CYP4F8 19-hydroxylates PGH2 (Rattus norvegicus)
CYP4F8 19-hydroxylates PGH2 (Mus musculus)
CYP4F8 19-hydroxylates PGH2 (Homo sapiens)
CYP4F3 20-hydroxylates LTB4 (Drosophila melanogaster)
CYP4F3 20-hydroxylates LTB4 (Gallus gallus)
CYP4F3 20-hydroxylates LTB4 (Xenopus tropicalis)
CYP4F3 20-hydroxylates LTB4 (Danio rerio)
CYP4F3 20-hydroxylates LTB4 (Sus scrofa)
CYP4F3 20-hydroxylates LTB4 (Bos taurus)
CYP4F3 20-hydroxylates LTB4 (Canis familiaris)
CYP4F3 20-hydroxylates LTB4 (Rattus norvegicus)
CYP4F3 20-hydroxylates LTB4 (Mus musculus)
CYP4F3 20-hydroxylates LTB4 (Homo sapiens)
CYP2U1 19-hydroxylates ARA (Dictyostelium discoideum)
CYP2U1 19-hydroxylates ARA (Caenorhabditis elegans)
CYP2U1 19-hydroxylates ARA (Drosophila melanogaster)
CYP2U1 19-hydroxylates ARA (Gallus gallus)
CYP2U1 19-hydroxylates ARA (Xenopus tropicalis)
CYP2U1 19-hydroxylates ARA (Danio rerio)
CYP2U1 19-hydroxylates ARA (Sus scrofa)
CYP2U1 19-hydroxylates ARA (Bos taurus)
CYP2U1 19-hydroxylates ARA (Canis familiaris)
CYP2U1 19-hydroxylates ARA (Rattus norvegicus)
CYP2U1 19-hydroxylates ARA (Mus musculus)
CYP2U1 19-hydroxylates ARA (Homo sapiens)
CYP4F11 16-hydroxylates 3OH-PALM (Drosophila melanogaster)
CYP4F11 16-hydroxylates 3OH-PALM (Gallus gallus)
CYP4F11 16-hydroxylates 3OH-PALM (Xenopus tropicalis)
CYP4F11 16-hydroxylates 3OH-PALM (Danio rerio)
CYP4F11 16-hydroxylates 3OH-PALM (Sus scrofa)
CYP4F11 16-hydroxylates 3OH-PALM (Bos taurus)
CYP4F11 16-hydroxylates 3OH-PALM (Canis familiaris)
CYP4F11 16-hydroxylates 3OH-PALM (Rattus norvegicus)
CYP4F11 16-hydroxylates 3OH-PALM (Mus musculus)
CYP4F11 16-hydroxylates 3OH-PALM (Homo sapiens)
CYP3A43 6b-hydroxylates TEST (Gallus gallus)
CYP3A43 6b-hydroxylates TEST (Xenopus tropicalis)
CYP3A43 6b-hydroxylates TEST (Danio rerio)
CYP3A43 6b-hydroxylates TEST (Sus scrofa)
CYP3A43 6b-hydroxylates TEST (Bos taurus)
CYP3A43 6b-hydroxylates TEST (Canis familiaris)
CYP3A43 6b-hydroxylates TEST (Rattus norvegicus)
CYP3A43 6b-hydroxylates TEST (Mus musculus)
CYP3A43 6b-hydroxylates TEST (Homo sapiens)
CYP2W1 oxidises INDOL (Dictyostelium discoideum)
CYP2W1 oxidises INDOL (Caenorhabditis elegans)
CYP2W1 oxidises INDOL (Gallus gallus)
CYP2W1 oxidises INDOL (Xenopus tropicalis)
CYP2W1 oxidises INDOL (Sus scrofa)
CYP2W1 oxidises INDOL (Bos taurus)
CYP2W1 oxidises INDOL (Canis familiaris)
CYP2W1 oxidises INDOL (Rattus norvegicus)
CYP2W1 oxidises INDOL (Mus musculus)
CYP2W1 oxidises INDOL (Homo sapiens)
CYP2S1 4-hydroxylates atRA (Dictyostelium discoideum)
CYP2S1 4-hydroxylates atRA (Caenorhabditis elegans)
CYP2S1 4-hydroxylates atRA (Xenopus tropicalis)
CYP2S1 4-hydroxylates atRA (Danio rerio)
CYP2S1 4-hydroxylates atRA (Sus scrofa)
CYP2S1 4-hydroxylates atRA (Bos taurus)
CYP2S1 4-hydroxylates atRA (Canis familiaris)
CYP2S1 4-hydroxylates atRA (Rattus norvegicus)
CYP2S1 4-hydroxylates atRA (Mus musculus)
CYP2S1 4-hydroxylates atRA (Homo sapiens)
FMO2:FAD:Mg2+ S-oxidises MTZ (Caenorhabditis elegans)
FMO2:FAD:Mg2+ S-oxidises MTZ (Xenopus tropicalis)
FMO2:FAD:Mg2+ S-oxidises MTZ (Danio rerio)
FMO2:FAD:Mg2+ S-oxidises MTZ (Sus scrofa)
FMO2:FAD:Mg2+ S-oxidises MTZ (Bos taurus)
FMO2:FAD:Mg2+ S-oxidises MTZ (Canis familiaris)
FMO2:FAD:Mg2+ S-oxidises MTZ (Rattus norvegicus)
FMO2:FAD:Mg2+ S-oxidises MTZ (Mus musculus)
FMO2:FAD:Mg2+ S-oxidises MTZ (Homo sapiens)
FMO1:FAD N-oxidises TAM (Caenorhabditis elegans)
FMO1:FAD N-oxidises TAM (Gallus gallus)
FMO1:FAD N-oxidises TAM (Xenopus tropicalis)
FMO1:FAD N-oxidises TAM (Danio rerio)
FMO1:FAD N-oxidises TAM (Sus scrofa)
FMO1:FAD N-oxidises TAM (Bos taurus)
FMO1:FAD N-oxidises TAM (Canis familiaris)
FMO1:FAD N-oxidises TAM (Rattus norvegicus)
FMO1:FAD N-oxidises TAM (Mus musculus)
FMO1:FAD N-oxidises TAM (Homo sapiens)
FMO3:FAD N-oxidises TMA to TMAO (Caenorhabditis elegans)
FMO3:FAD N-oxidises TMA to TMAO (Gallus gallus)
FMO3:FAD N-oxidises TMA to TMAO (Xenopus tropicalis)
FMO3:FAD N-oxidises TMA to TMAO (Danio rerio)
FMO3:FAD N-oxidises TMA to TMAO (Sus scrofa)
FMO3:FAD N-oxidises TMA to TMAO (Bos taurus)
FMO3:FAD N-oxidises TMA to TMAO (Canis familiaris)
FMO3:FAD N-oxidises TMA to TMAO (Rattus norvegicus)
FMO3:FAD N-oxidises TMA to TMAO (Mus musculus)
FMO3:FAD N-oxidises TMA to TMAO (Homo sapiens)
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Gallus gallus)
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Xenopus tropicalis)
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Danio rerio)
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Sus scrofa)
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Bos taurus)
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Canis familiaris)
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Rattus norvegicus)
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Mus musculus)
VKORC1L1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Homo sapiens)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Drosophila melanogaster)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Gallus gallus)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Danio rerio)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Xenopus tropicalis)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Sus scrofa)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Bos taurus)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Canis familiaris)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Rattus norvegicus)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Mus musculus)
VKORC1 reduces vitamin K epoxide to MK4 (vitamin K hydroquinone) (Homo sapiens)
N-hydroxylation of 4-aminobiphenyl (Danio rerio)
N-hydroxylation of 4-aminobiphenyl (Sus scrofa)
N-hydroxylation of 4-aminobiphenyl (Bos taurus)
N-hydroxylation of 4-aminobiphenyl (Rattus norvegicus)
N-hydroxylation of 4-aminobiphenyl (Mus musculus)
N-hydroxylation of 4-aminobiphenyl (Homo sapiens)
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Danio rerio)
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Sus scrofa)
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Bos taurus)
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Rattus norvegicus)
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Mus musculus)
Ethylene is oxidized to Ethylene oxide by CYP1A1 (Homo sapiens)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Plasmodium falciparum)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Caenorhabditis elegans)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Drosophila melanogaster)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Gallus gallus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Xenopus tropicalis)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Danio rerio)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Sus scrofa)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Bos taurus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Canis familiaris)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Rattus norvegicus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Mus musculus)
ATP2A1-3 transport Ca2+ from cytosol to ER lumen (Homo sapiens)
CYP1A2 S-demethylates 6MMP (Rattus norvegicus)
CYP1A2 S-demethylates 6MMP (Homo sapiens)
CYP1A2 S-demethylates 6MMP (Mus musculus)
CYP1A2 S-demethylates 6MMP (Bos taurus)
CYP1A2 S-demethylates 6MMP (Sus scrofa)
CYP1A2 S-demethylates 6MMP (Danio rerio)
as an output of
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Dictyostelium discoideum)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Caenorhabditis elegans)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Drosophila melanogaster)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Gallus gallus)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Xenopus tropicalis)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Danio rerio)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Sus scrofa)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Bos taurus)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Canis familiaris)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Rattus norvegicus)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Mus musculus)
CES1 trimer hydrolyses ACEI pro-drugs to ACEIs (Homo sapiens)
TXB2 is converted to 11dh-TXB2 by TXDH (Homo sapiens)
FUT10 O-fucosylates EMI domain-containing proteins (Gallus gallus)
FUT10 O-fucosylates EMI domain-containing proteins (Danio rerio)
FUT10 O-fucosylates EMI domain-containing proteins (Sus scrofa)
FUT10 O-fucosylates EMI domain-containing proteins (Bos taurus)
FUT10 O-fucosylates EMI domain-containing proteins (Canis familiaris)
FUT10 O-fucosylates EMI domain-containing proteins (Rattus norvegicus)
FUT10 O-fucosylates EMI domain-containing proteins (Mus musculus)
FUT10 O-fucosylates EMI domain-containing proteins (Homo sapiens)
FUT11 O-fucosylates EMI domain-containing proteins (Gallus gallus)
FUT11 O-fucosylates EMI domain-containing proteins (Danio rerio)
FUT11 O-fucosylates EMI domain-containing proteins (Sus scrofa)
FUT11 O-fucosylates EMI domain-containing proteins (Bos taurus)
FUT11 O-fucosylates EMI domain-containing proteins (Canis familiaris)
FUT11 O-fucosylates EMI domain-containing proteins (Rattus norvegicus)
FUT11 O-fucosylates EMI domain-containing proteins (Mus musculus)
FUT11 O-fucosylates EMI domain-containing proteins (Homo sapiens)
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Gallus gallus)
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Xenopus tropicalis)
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Danio rerio)
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Sus scrofa)
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Bos taurus)
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Canis familiaris)
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Rattus norvegicus)
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Mus musculus)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Gallus gallus)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Xenopus tropicalis)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Danio rerio)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Sus scrofa)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Bos taurus)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Canis familiaris)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Rattus norvegicus)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Mus musculus)
POMGNT2 transfers GlcNAc to Man-DAG1 (Gallus gallus)
POMGNT2 transfers GlcNAc to Man-DAG1 (Xenopus tropicalis)
POMGNT2 transfers GlcNAc to Man-DAG1 (Danio rerio)
POMGNT2 transfers GlcNAc to Man-DAG1 (Sus scrofa)
POMGNT2 transfers GlcNAc to Man-DAG1 (Bos taurus)
POMGNT2 transfers GlcNAc to Man-DAG1 (Rattus norvegicus)
POMGNT2 transfers GlcNAc to Man-DAG1 (Mus musculus)
POMGNT2 transfers GlcNAc to Man-DAG1 (Homo sapiens)
B3GALNT2 transfers GalNAc to GlcNAc-Man-DAG1 (Homo sapiens)
POMK 6-phosphorylates mannose in GalNAc-GlcNAc-Man-DAG1 (Homo sapiens)
POFUT2 transfers fucose to TSR domain-containing proteins (Plasmodium falciparum)
POFUT2 transfers fucose to TSR domain-containing proteins (Caenorhabditis elegans)
POFUT2 transfers fucose to TSR domain-containing proteins (Drosophila melanogaster)
POFUT2 transfers fucose to TSR domain-containing proteins (Gallus gallus)
POFUT2 transfers fucose to TSR domain-containing proteins (Xenopus tropicalis)
POFUT2 transfers fucose to TSR domain-containing proteins (Danio rerio)
POFUT2 transfers fucose to TSR domain-containing proteins (Sus scrofa)
POFUT2 transfers fucose to TSR domain-containing proteins (Bos taurus)
POFUT2 transfers fucose to TSR domain-containing proteins (Canis familiaris)
POFUT2 transfers fucose to TSR domain-containing proteins (Rattus norvegicus)
POFUT2 transfers fucose to TSR domain-containing proteins (Mus musculus)
POFUT2 transfers fucose to TSR domain-containing proteins (Homo sapiens)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Drosophila melanogaster)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Gallus gallus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Xenopus tropicalis)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Danio rerio)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Sus scrofa)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Bos taurus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Canis familiaris)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Rattus norvegicus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Mus musculus)
POMT1:POMT2 transfers Man from Dol-P-Man to DAG1(30-653) (Homo sapiens)
CES1 trimer.CES2 hydrolyse COCN to BEG (Dictyostelium discoideum)
CES1 trimer.CES2 hydrolyse COCN to BEG (Caenorhabditis elegans)
CES1 trimer.CES2 hydrolyse COCN to BEG (Drosophila melanogaster)
CES1 trimer.CES2 hydrolyse COCN to BEG (Gallus gallus)
CES1 trimer.CES2 hydrolyse COCN to BEG (Xenopus tropicalis)
CES1 trimer.CES2 hydrolyse COCN to BEG (Danio rerio)
CES1 trimer.CES2 hydrolyse COCN to BEG (Sus scrofa)
CES1 trimer.CES2 hydrolyse COCN to BEG (Bos taurus)
CES1 trimer.CES2 hydrolyse COCN to BEG (Canis familiaris)
CES1 trimer.CES2 hydrolyse COCN to BEG (Rattus norvegicus)
CES1 trimer.CES2 hydrolyse COCN to BEG (Mus musculus)
CES1 trimer.CES2 hydrolyse COCN to BEG (Homo sapiens)
CES1,CES2 hydrolyze ASA- to ST (Dictyostelium discoideum)
CES1,CES2 hydrolyze ASA- to ST (Caenorhabditis elegans)
CES1,CES2 hydrolyze ASA- to ST (Drosophila melanogaster)
CES1,CES2 hydrolyze ASA- to ST (Gallus gallus)
CES1,CES2 hydrolyze ASA- to ST (Xenopus tropicalis)
CES1,CES2 hydrolyze ASA- to ST (Danio rerio)
CES1,CES2 hydrolyze ASA- to ST (Sus scrofa)
CES1,CES2 hydrolyze ASA- to ST (Bos taurus)
CES1,CES2 hydrolyze ASA- to ST (Canis familiaris)
CES1,CES2 hydrolyze ASA- to ST (Rattus norvegicus)
CES1,CES2 hydrolyze ASA- to ST (Mus musculus)
CES1,CES2 hydrolyze ASA- to ST (Homo sapiens)
E protein gets N-glycosylated (Homo sapiens)
E protein gets N-glycosylated (Homo sapiens)
CES2 hydrolyzes ASA- (Dictyostelium discoideum)
CES2 hydrolyzes ASA- (Caenorhabditis elegans)
Spike protein gets N-glycosylated (Homo sapiens)
M protein gets N-glycosylated (Homo sapiens)
M protein gets N-glycosylated (Homo sapiens)
CDH1 is O-manosylated (Homo sapiens)
CDH1 is O-manosylated (Mus musculus)
CDH1 is O-manosylated (Rattus norvegicus)
CDH1 is O-manosylated (Canis familiaris)
CDH1 is O-manosylated (Bos taurus)
CDH1 is O-manosylated (Sus scrofa)
CDH1 is O-manosylated (Danio rerio)
CDH1 is O-manosylated (Xenopus tropicalis)
CDH1 is O-manosylated (Gallus gallus)
UGT8 transfers Gal from UDP-Gal to CERA (Sus scrofa)
UGT8 transfers Gal from UDP-Gal to CERA (Homo sapiens)
UGT8 transfers Gal from UDP-Gal to CERA (Mus musculus)
UGT8 transfers Gal from UDP-Gal to CERA (Rattus norvegicus)
UGT8 transfers Gal from UDP-Gal to CERA (Canis familiaris)
UGT8 transfers Gal from UDP-Gal to CERA (Bos taurus)
UGT8 transfers Gal from UDP-Gal to CERA (Danio rerio)
UGT8 transfers Gal from UDP-Gal to CERA (Gallus gallus)
UGT8 transfers Gal from UDP-Gal to CERA (Drosophila melanogaster)
UGT8 transfers Gal from UDP-Gal to CERA (Caenorhabditis elegans)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Mus musculus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Homo sapiens)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Rattus norvegicus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Canis familiaris)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Bos taurus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Sus scrofa)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Danio rerio)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Xenopus tropicalis)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Gallus gallus)
SUMF1 mediates the oxidation of cysteine to formylglycine, producing active arylsulfatases (Drosophila melanogaster)
CES2 hydrolyzes ASA- (Homo sapiens)
CES2 hydrolyzes ASA- (Mus musculus)
CES2 hydrolyzes ASA- (Rattus norvegicus)
CES2 hydrolyzes ASA- (Canis familiaris)
CES2 hydrolyzes ASA- (Bos taurus)
CES2 hydrolyzes ASA- (Danio rerio)
CES2 hydrolyzes ASA- (Drosophila melanogaster)
Other forms of this molecule
H+ [early endosome]
H+ [synaptic vesicle lumen]
H+ [periplasmic space]
H+ [platelet dense tubular network lumen]
H+ [sperm flagellum]
H+ [secretory granule lumen]
H+ [late endosome lumen]
H+ [early endosome lumen]
H+ [synaptic vesicle]
H+ [phagolysosome]
H+ [cytoplasm]
H+ [phagocytic vesicle lumen]
H+ [clathrin-sculpted acetylcholine transport vesicle lumen]
H+ [nuclear envelope]
H+ [endocytic vesicle lumen]
H+ [Golgi lumen]
H+ [mitochondrial inner membrane]
H+ [mitochondrial intermembrane space]
H+ [lysosomal lumen]
H+ [mitochondrial matrix]
H+ [peroxisomal matrix]
H+ [endolysosome lumen]
H+ [endoplasmic reticulum-Golgi intermediate compartment]
H+ [endosome lumen]
H+ [extracellular region]
H+ [clathrin-sculpted monoamine transport vesicle lumen]
H+ [cytosol]
H+ [nucleoplasm]
Cross References
COMPOUND
C00080
PubChem Substance
8145820
HMDB Metabolite
HMDB0059597
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![H+ [endoplasmic reticulum lumen] icon](/icon/R-ICO-012841.svg){kind=icon}
