Information on Organism Aspergillus oryzae

TaxTree of Organism Aspergillus oryzae
Condensed Tree View
Eukaryota can be found in Brenda BRENDA pathways(superkingdom)
Fungi can be found in Brenda BRENDA pathways(kingdom)
Dikarya can be found in Brenda BRENDA pathways(subkingdom)
Ascomycota can be found in Brenda BRENDA pathways(phylum)
Pezizomycotina can be found in Brenda BRENDA pathways(subphylum)
Circumdati can be found in Brenda (subgenus)
Circumdati can be found in Brenda (subgenus)
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EC NUMBER
COMMENTARY hide
PATHWAY
BRENDA Link
KEGG Link
MetaCyc Link
(1'S,5'S)-averufin biosynthesis
-
-
(1,4)-beta-D-xylan degradation
-
-
(3R)-linalool biosynthesis
-
-
(3S)-linalool biosynthesis
-
-
(4Z,7Z,10Z,13Z,16Z)-docosapentaenoate biosynthesis (6-desaturase)
-
-
(8E,10E)-dodeca-8,10-dienol biosynthesis
-
-
(aminomethyl)phosphonate degradation
-
-
(R)- and (S)-3-hydroxybutanoate biosynthesis (engineered)
-
-
(R)-cysteate degradation
-
-
(S)-lactate fermentation to propanoate, acetate and hydrogen
-
-
(S)-propane-1,2-diol degradation
-
-
(S)-reticuline biosynthesis I
-
-
1,3-propanediol biosynthesis (engineered)
-
-
1,5-anhydrofructose degradation
-
-
1-butanol autotrophic biosynthesis (engineered)
-
-
10-cis-heptadecenoyl-CoA degradation (yeast)
-
-
10-trans-heptadecenoyl-CoA degradation (MFE-dependent, yeast)
-
-
10-trans-heptadecenoyl-CoA degradation (reductase-dependent, yeast)
-
-
2'-deoxymugineic acid phytosiderophore biosynthesis
-
-
2,3-dihydroxybenzoate biosynthesis
-
-
2-amino-3-hydroxycyclopent-2-enone biosynthesis
-
-
2-arachidonoylglycerol biosynthesis
-
-
2-carboxy-1,4-naphthoquinol biosynthesis
-
-
2-deoxy-D-glucose 6-phosphate degradation
-
-
2-deoxy-D-ribose degradation II
-
-
2-methyl-branched fatty acid beta-oxidation
-
-
2-methylpropene degradation
-
-
2-nitrotoluene degradation
-
-
3-(4-hydroxyphenyl)pyruvate biosynthesis
-
-
3-hydroxy-4-methyl-anthranilate biosynthesis I
-
-
3-hydroxy-4-methyl-anthranilate biosynthesis II
-
-
3-hydroxypropanoate cycle
-
-
3-hydroxypropanoate/4-hydroxybutanate cycle
-
-
3-methylbutanol biosynthesis (engineered)
-
-
4-aminobutanoate degradation V
-
-
4-ethylphenol degradation (anaerobic)
-
-
4-hydroxy-2-nonenal detoxification
-
-
4-hydroxybenzoate biosynthesis I (eukaryotes)
-
-
4-hydroxybenzoate biosynthesis III (plants)
-
-
4-hydroxymandelate degradation
4-oxopentanoate degradation
-
-
5'-deoxyadenosine degradation I
-
-
8-amino-7-oxononanoate biosynthesis I
-
-
8-amino-7-oxononanoate biosynthesis II
-
-
8-amino-7-oxononanoate biosynthesis III
-
-
9-cis, 11-trans-octadecadienoyl-CoA degradation (isomerase-dependent, yeast)
-
-
ABH and Lewis epitopes biosynthesis from type 1 precursor disaccharide
-
-
Ac/N-end rule pathway
-
-
acetaldehyde biosynthesis I
-
-
acetaldehyde biosynthesis II
-
-
acetate conversion to acetyl-CoA
-
-
acetate fermentation
-
-
acetoacetate degradation (to acetyl CoA)
-
-
acetone degradation I (to methylglyoxal)
-
-
acetone degradation III (to propane-1,2-diol)
-
-
acetyl-CoA biosynthesis from citrate
-
-
acetyl-CoA fermentation to butanoate II
-
-
acetylene degradation (anaerobic)
-
-
acrylonitrile degradation I
-
-
acyl-CoA hydrolysis
-
-
acyl-[acyl-carrier protein] thioesterase pathway
-
-
adenine and adenosine salvage I
-
-
adenine and adenosine salvage II
-
-
adenine and adenosine salvage III
-
-
adenine and adenosine salvage V
-
-
adenine salvage
-
-
adenosine nucleotides degradation I
-
-
adenosine nucleotides degradation II
-
-
adenosine ribonucleotides de novo biosynthesis
-
-
adlupulone and adhumulone biosynthesis
-
-
aerobic respiration (NDH-1 to cytochrome c oxidase via plastocyanin)
-
-
aerobic respiration I (cytochrome c)
-
-
aerobic respiration II (cytochrome c) (yeast)
-
-
aerobic respiration III (alternative oxidase pathway)
-
-
aerobic respiration in cyanobacteria (NDH-2 to cytochrome c oxidase via plastocyanin)
-
-
Aflatoxin biosynthesis
-
-
aflatoxins B2 and G2 biosynthesis
-
-
ajmaline and sarpagine biosynthesis
-
-
alanine metabolism
-
-
Alanine, aspartate and glutamate metabolism
-
-
alginate degradation
-
-
alkylnitronates degradation
-
-
all-trans-farnesol biosynthesis
-
-
alliin metabolism
-
-
alpha-Linolenic acid metabolism
-
-
alpha-tomatine degradation
-
-
Amaryllidacea alkaloids biosynthesis
-
-
Amino sugar and nucleotide sugar metabolism
-
-
Aminoacyl-tRNA biosynthesis
-
-
Aminobenzoate degradation
-
-
ammonia assimilation cycle I
-
-
ammonia assimilation cycle II
-
-
ammonia oxidation II (anaerobic)
-
-
amygdalin and prunasin degradation
-
-
anaerobic energy metabolism (invertebrates, cytosol)
-
-
anaerobic energy metabolism (invertebrates, mitochondrial)
-
-
anandamide biosynthesis I
-
-
anandamide biosynthesis II
-
-
anapleurotic synthesis of oxalacetate
-
-
androsrtendione degradation II (anaerobic)
-
-
androstenedione degradation I (aerobic)
-
-
anhydromuropeptides recycling I
-
-
anhydromuropeptides recycling II
-
-
anteiso-branched-chain fatty acid biosynthesis
-
-
arachidonate biosynthesis
-
-
Arachidonic acid metabolism
-
-
arachidonic acid metabolism
-
-
Arg/N-end rule pathway (eukaryotic)
-
-
Arginine and proline metabolism
-
-
Arginine biosynthesis
-
-
arginine dependent acid resistance
-
-
arginine metabolism
-
-
aromatic polyketides biosynthesis
-
-
arsenate detoxification I (mammalian)
-
-
Ascorbate and aldarate metabolism
-
-
ascorbate metabolism
-
-
aspartate and asparagine metabolism
-
-
aspirin triggered resolvin D biosynthesis
-
-
aspirin triggered resolvin E biosynthesis
-
-
assimilatory sulfate reduction II
-
-
assimilatory sulfate reduction III
-
-
assimilatory sulfate reduction IV
-
-
ATP biosynthesis
-
-
Atrazine degradation
-
-
atromentin biosynthesis
-
-
avenanthramide biosynthesis
-
-
bacterial bioluminescence
-
-
baicalein degradation (hydrogen peroxide detoxification)
-
-
benzoate biosynthesis II (CoA-independent, non-beta-oxidative)
-
-
Benzoate degradation
-
-
berberine biosynthesis
-
-
beta-(1,4)-mannan degradation
-
-
beta-alanine biosynthesis I
-
-
beta-Alanine metabolism
-
-
beta-D-glucuronide and D-glucuronate degradation
-
-
Betalain biosynthesis
-
-
betanidin degradation
-
-
betaxanthin biosynthesis
-
-
betaxanthin biosynthesis (via dopamine)
-
-
Bifidobacterium shunt
-
-
bile acid biosynthesis, neutral pathway
Biosynthesis of 12-, 14- and 16-membered macrolides
-
-
Biosynthesis of ansamycins
-
-
Biosynthesis of enediyne antibiotics
-
-
biosynthesis of Lewis epitopes (H. pylori)
-
-
Biosynthesis of secondary metabolites
-
-
Biosynthesis of siderophore group nonribosomal peptides
-
-
Biosynthesis of unsaturated fatty acids
-
-
Biosynthesis of various secondary metabolites - part 1
-
-
biotin biosynthesis
-
-
Biotin metabolism
-
-
bisabolene biosynthesis (engineered)
-
-
brassicicene C biosynthesis
-
-
bryostatin biosynthesis
-
-
bupropion degradation
-
-
Butanoate metabolism
-
-
butanol and isobutanol biosynthesis (engineered)
-
-
C20 prostanoid biosynthesis
-
-
C4 and CAM-carbon fixation
-
-
C4 photosynthetic carbon assimilation cycle, NAD-ME type
-
-
C4 photosynthetic carbon assimilation cycle, NADP-ME type
-
-
C4 photosynthetic carbon assimilation cycle, PEPCK type
-
-
C5-Branched dibasic acid metabolism
-
-
Caffeine metabolism
-
-
Calvin-Benson-Bassham cycle
-
-
camalexin biosynthesis
-
-
Caprolactam degradation
-
-
capsaicin biosynthesis
-
-
Carbon fixation in photosynthetic organisms
-
-
Carbon fixation pathways in prokaryotes
-
-
cardenolide glucosides biosynthesis
-
-
carnitine metabolism
-
-
catechol degradation to 2-hydroxypentadienoate I
-
-
catechol degradation to 2-hydroxypentadienoate II
-
-
catecholamine biosynthesis
CDP-6-deoxy-D-gulose biosynthesis
-
-
CDP-diacylglycerol biosynthesis
-
-
CDP-diacylglycerol biosynthesis I
-
-
CDP-diacylglycerol biosynthesis II
-
-
CDP-diacylglycerol biosynthesis III
-
-
cellulose and hemicellulose degradation (cellulolosome)
-
-
cellulose degradation
-
-
cellulose degradation II (fungi)
-
-
ceramide and sphingolipid recycling and degradation (yeast)
-
-
ceramide degradation (generic)
-
-
ceramide degradation by alpha-oxidation
-
-
chanoclavine I aldehyde biosynthesis
-
-
chelerythrine biosynthesis
-
-
chitin biosynthesis
-
-
chitin deacetylation
-
-
chitin degradation I (archaea)
-
-
chitin degradation II (Vibrio)
-
-
chitin degradation III (Serratia)
-
-
Chloroalkane and chloroalkene degradation
-
-
Chlorocyclohexane and chlorobenzene degradation
-
-
chlorogenic acid biosynthesis I
-
-
chlorogenic acid degradation
-
-
cholesterol biosynthesis
-
-
cholesterol degradation to androstenedione I (cholesterol oxidase)
-
-
cholesterol degradation to androstenedione II (cholesterol dehydrogenase)
-
-
cholesterol degradation to androstenedione III (anaerobic)
-
-
chorismate biosynthesis from 3-dehydroquinate
-
-
chorismate metabolism
-
-
cichoriin interconversion
-
-
cinnamoyl-CoA biosynthesis
-
-
cis-geranyl-CoA degradation
-
-
cis-vaccenate biosynthesis
cis-zeatin biosynthesis
-
-
Citrate cycle (TCA cycle)
-
-
citric acid cycle
-
-
CO2 fixation in Crenarchaeota
-
-
CO2 fixation into oxaloacetate (anaplerotic)
-
-
coenzyme M biosynthesis
-
-
coenzyme M biosynthesis II
-
-
colanic acid building blocks biosynthesis
-
-
colupulone and cohumulone biosynthesis
-
-
complex N-linked glycan biosynthesis (plants)
-
-
complex N-linked glycan biosynthesis (vertebrates)
-
-
coptisine biosynthesis
-
-
coumarin biosynthesis (via 2-coumarate)
-
-
coumarins biosynthesis (engineered)
-
-
creatine-phosphate biosynthesis
-
-
crepenynate biosynthesis
-
-
crotonate fermentation (to acetate and cyclohexane carboxylate)
-
-
curcuminoid biosynthesis
-
-
cuticular wax biosynthesis
-
-
cutin biosynthesis
-
-
Cutin, suberine and wax biosynthesis
-
-
cyanate degradation
cyanide detoxification II
-
-
Cyanoamino acid metabolism
-
-
Cysteine and methionine metabolism
-
-
cysteine metabolism
-
-
cytosolic NADPH production (yeast)
-
-
D-Alanine metabolism
-
-
D-arabitol degradation
-
-
D-Arginine and D-ornithine metabolism
-
-
D-galactarate degradation I
-
-
D-galactose degradation I (Leloir pathway)
-
-
D-galactose detoxification
-
-
D-glucarate degradation I
-
-
D-glucuronate degradation I
-
-
D-Glutamine and D-glutamate metabolism
-
-
d-mannose degradation
-
-
D-myo-inositol (1,4,5)-trisphosphate biosynthesis
-
-
D-myo-inositol-5-phosphate metabolism
-
-
D-phenylglycine degradation
-
-
D-sorbitol degradation I
-
-
d-xylose degradation
-
-
D-xylose degradation I
-
-
D-xylose degradation II
-
-
daphnin interconversion
-
-
degradation of aromatic, nitrogen containing compounds
-
-
degradation of hexoses
-
-
degradation of pentoses
-
-
degradation of sugar acids
-
-
degradation of sugar alcohols
-
-
dehydroscoulerine biosynthesis
-
-
denitrification
-
-
diacylglycerol and triacylglycerol biosynthesis
-
-
diethylphosphate degradation
-
-
dimethyl sulfide biosynthesis from methionine
-
-
dissimilatory sulfate reduction I (to hydrogen sufide))
-
-
Diterpenoid biosynthesis
-
-
divinyl ether biosynthesis II
-
-
docosahexaenoate biosynthesis III (6-desaturase, mammals)
-
-
dopamine degradation
-
-
Drug metabolism - cytochrome P450
-
-
Drug metabolism - other enzymes
-
-
echinatin biosynthesis
-
-
enterobactin biosynthesis
-
-
Entner Doudoroff pathway
-
-
Entner-Doudoroff pathway I
-
-
Entner-Doudoroff pathway II (non-phosphorylative)
-
-
Entner-Doudoroff pathway III (semi-phosphorylative)
-
-
ephedrine biosynthesis
-
-
epiberberine biosynthesis
-
-
ergosterol biosynthesis II
-
-
ergothioneine biosynthesis II (fungi)
-
-
erythromycin D biosynthesis
-
-
ethanol degradation I
-
-
ethanol degradation II
-
-
ethanol degradation III
-
-
ethanol degradation IV
-
-
ethanol fermentation
-
-
ethanolamine utilization
-
-
ethene biosynthesis I (plants)
-
-
ethene biosynthesis III (microbes)
-
-
ethene biosynthesis IV (engineered)
-
-
ethene biosynthesis V (engineered)
-
-
Ether lipid metabolism
-
-
Ethylbenzene degradation
-
-
ethylmalonyl-CoA pathway
-
-
even iso-branched-chain fatty acid biosynthesis
-
-
farnesene biosynthesis
-
-
fatty acid beta-oxidation I (generic)
-
-
fatty acid beta-oxidation II (plant peroxisome)
-
-
fatty acid beta-oxidation VI (mammalian peroxisome)
-
-
fatty acid beta-oxidation VII (yeast peroxisome)
-
-
Fatty acid biosynthesis
-
-
fatty acid biosynthesis initiation (mitochondria)
-
-
fatty acid biosynthesis initiation (plant mitochondria)
-
-
fatty acid biosynthesis initiation (type I)
-
-
fatty acid biosynthesis initiation (type II)
-
-
Fatty acid degradation
-
-
Fatty acid elongation
-
-
fatty acid elongation -- saturated
-
-
fatty acid salvage
-
-
Fe(II) oxidation
-
-
firefly bioluminescence
-
-
flavin biosynthesis
-
-
Flavone and flavonol biosynthesis
-
-
flavonoid biosynthesis
-
-
Flavonoid biosynthesis
-
-
flavonoid biosynthesis (in equisetum)
-
-
flavonoid di-C-glucosylation
-
-
fluoroacetate and fluorothreonine biosynthesis
-
-
Folate biosynthesis
-
-
folate transformations I
-
-
folate transformations II (plants)
-
-
folate transformations III (E. coli)
-
-
formaldehyde assimilation I (serine pathway)
-
-
formaldehyde assimilation II (assimilatory RuMP Cycle)
-
-
formaldehyde assimilation III (dihydroxyacetone cycle)
-
-
formaldehyde oxidation
-
-
formaldehyde oxidation I
-
-
formaldehyde oxidation II (glutathione-dependent)
-
-
formate oxidation to CO2
-
-
fructan biosynthesis
-
-
fructan degradation
-
-
Fructose and mannose metabolism
-
-
fusicoccin A biosynthesis
-
-
GABA shunt
-
-
Galactose metabolism
-
-
gallate biosynthesis
-
-
gamma-glutamyl cycle
-
-
gamma-linolenate biosynthesis II (animals)
-
-
GDP-alpha-D-glucose biosynthesis
-
-
geosmin biosynthesis
-
-
Geraniol degradation
-
-
geranyl diphosphate biosynthesis
-
-
geranylgeranyl diphosphate biosynthesis
-
-
ginsenoside degradation I
-
-
ginsenoside degradation III
-
-
ginsenoside metabolism
-
-
ginsenosides biosynthesis
-
-
gliotoxin biosynthesis
-
-
gluconeogenesis
-
-
gluconeogenesis I
-
-
gluconeogenesis II (Methanobacterium thermoautotrophicum)
-
-
gluconeogenesis III
-
-
glucose and glucose-1-phosphate degradation
-
-
glucose degradation (oxidative)
-
-
glucosylglycerol biosynthesis
-
-
glutamate and glutamine metabolism
-
-
glutaminyl-tRNAgln biosynthesis via transamidation
-
-
glutaryl-CoA degradation
-
-
Glutathione metabolism
-
-
glutathione metabolism
-
-
glutathione-mediated detoxification I
-
-
glutathione-mediated detoxification II
-
-
glutathione-peroxide redox reactions
-
-
glycerol degradation I
-
-
glycerol degradation II
-
-
glycerol degradation to butanol
-
-
glycerol degradation V
-
-
glycerol-3-phosphate shuttle
-
-
glycerol-3-phosphate to cytochrome bo oxidase electron transfer
-
-
glycerol-3-phosphate to fumarate electron transfer
-
-
glycerol-3-phosphate to hydrogen peroxide electron transport
-
-
Glycerolipid metabolism
-
-
glycerophosphodiester degradation
-
-
Glycerophospholipid metabolism
-
-
glycine biosynthesis IV
-
-
glycine metabolism
-
-
Glycine, serine and threonine metabolism
-
-
glycogen biosynthesis
-
-
glycogen biosynthesis I (from ADP-D-Glucose)
-
-
glycogen biosynthesis II (from UDP-D-Glucose)
-
-
glycogen biosynthesis III (from alpha-maltose 1-phosphate)
-
-
glycogen degradation I
-
-
glycogen degradation II
-
-
glycogen metabolism
-
-
glycolysis
-
-
Glycolysis / Gluconeogenesis
-
-
glycolysis I (from glucose 6-phosphate)
-
-
glycolysis II (from fructose 6-phosphate)
-
-
glycolysis III (from glucose)
-
-
glycolysis IV
-
-
glycolysis V (Pyrococcus)
-
-
Glycosaminoglycan biosynthesis - keratan sulfate
-
-
Glycosaminoglycan degradation
-
-
Glycosphingolipid biosynthesis - ganglio series
-
-
Glycosphingolipid biosynthesis - globo and isoglobo series
-
-
Glycosphingolipid biosynthesis - lacto and neolacto series
-
-
Glyoxylate and dicarboxylate metabolism
-
-
glyoxylate assimilation
-
-
glyoxylate cycle
-
-
glyphosate degradation III
-
-
gossypol biosynthesis
-
-
guanine and guanosine salvage
-
-
guanine and guanosine salvage II
-
-
guanosine nucleotides degradation III
-
-
heme degradation I
-
-
heme metabolism
-
-
heparan sulfate degradation
-
-
heparin degradation
-
-
heterolactic fermentation
-
-
histamine degradation
-
-
Histidine metabolism
-
-
histidine metabolism
-
-
homocysteine and cysteine interconversion
-
-
hydrogen sulfide biosynthesis II (mammalian)
-
-
hypoglycin biosynthesis
-
-
IAA biosynthesis
-
-
icosapentaenoate biosynthesis II (6-desaturase, mammals)
-
-
incomplete reductive TCA cycle
-
-
Indole alkaloid biosynthesis
-
-
indole glucosinolate activation (herbivore attack)
-
-
indole glucosinolate activation (intact plant cell)
-
-
indole-3-acetate biosynthesis II
-
-
indole-3-acetate biosynthesis III (bacteria)
-
-
indole-3-acetate biosynthesis IV (bacteria)
-
-
indole-3-acetate biosynthesis V (bacteria and fungi)
-
-
indole-3-acetate degradation II
-
-
inosine 5'-phosphate degradation
-
-
Inositol phosphate metabolism
-
-
ipsdienol biosynthesis
-
-
Isoflavonoid biosynthesis
-
-
isoflavonoid biosynthesis I
-
-
isoflavonoid biosynthesis II
-
-
isoleucine metabolism
-
-
isoprene biosynthesis II (engineered)
-
-
isoprenoid biosynthesis
-
-
isopropanol biosynthesis (engineered)
-
-
Isoquinoline alkaloid biosynthesis
-
-
itaconate biosynthesis I
-
-
jadomycin biosynthesis
-
-
jasmonic acid biosynthesis
-
-
justicidin B biosynthesis
-
-
ketogenesis
-
-
ketolysis
-
-
L-alanine biosynthesis II
-
-
L-alanine degradation II (to D-lactate)
-
-
L-alanine degradation III
-
-
L-alanine degradation V (oxidative Stickland reaction)
-
-
L-alanine degradation VI (reductive Stickland reaction)
-
-
L-arabinose degradation II
-
-
L-arginine biosynthesis I (via L-ornithine)
-
-
L-arginine biosynthesis II (acetyl cycle)
-
-
L-arginine biosynthesis IV (archaebacteria)
-
-
L-arginine degradation III (arginine decarboxylase/agmatinase pathway)
-
-
L-arginine degradation IV (arginine decarboxylase/agmatine deiminase pathway)
-
-
L-arginine degradation X (arginine monooxygenase pathway)
-
-
L-arginine degradation XIII (reductive Stickland reaction)
-
-
L-arginine degradation XIV (oxidative Stickland reaction)
-
-
L-ascorbate biosynthesis IV (animals, D-glucuronate pathway)
-
-
L-ascorbate biosynthesis VI (plants, myo-inositol pathway)
-
-
L-ascorbate biosynthesis VIII (engineered pathway)
-
-
L-asparagine biosynthesis I
-
-
L-asparagine biosynthesis III (tRNA-dependent)
-
-
L-asparagine degradation I
-
-
L-asparagine degradation III (mammalian)
-
-
L-aspartate biosynthesis
-
-
L-aspartate degradation I
-
-
L-citrulline biosynthesis
-
-
L-citrulline degradation
-
-
L-cysteine biosynthesis III (from L-homocysteine)
-
-
L-cysteine biosynthesis VI (from L-methionine)
-
-
L-dopa and L-dopachrome biosynthesis
-
-
L-dopa degradation II (bacterial)
-
-
L-glutamate biosynthesis I
-
-
L-glutamate biosynthesis III
-
-
L-glutamate degradation I
-
-
L-glutamate degradation II
-
-
L-glutamate degradation IV
-
-
L-glutamate degradation IX (via 4-aminobutanoate)
-
-
L-glutamate degradation V (via hydroxyglutarate)
-
-
L-glutamate degradation VI (to pyruvate)
-
-
L-glutamate degradation XI (reductive Stickland reaction)
-
-
L-glutamine biosynthesis I
-
-
L-glutamine biosynthesis III
-
-
L-glutamine degradation I
-
-
L-histidine degradation V
-
-
L-isoleucine biosynthesis V
-
-
L-isoleucine degradation I
-
-
L-isoleucine degradation II
-
-
L-lactaldehyde degradation
-
-
L-leucine degradation I
-
-
L-leucine degradation III
-
-
L-leucine degradation IV (reductive Stickland reaction)
-
-
L-lysine degradation V
-
-
L-lysine fermentation to acetate and butanoate
-
-
L-methionine degradation III
-
-
L-methionine salvage cycle II (plants)
-
-
L-nicotianamine biosynthesis
-
-
L-phenylalanine biosynthesis I
-
-
L-phenylalanine degradation II (anaerobic)
-
-
L-phenylalanine degradation III
-
-
L-phenylalanine degradation IV (mammalian, via side chain)
-
-
L-phenylalanine degradation VI (reductive Stickland reaction)
-
-
L-serine biosynthesis II
-
-
L-threonine degradation IV
-
-
L-tryptophan degradation I (via anthranilate)
-
-
L-tryptophan degradation to 2-amino-3-carboxymuconate semialdehyde
-
-
L-tryptophan degradation V (side chain pathway)
-
-
L-tryptophan degradation XI (mammalian, via kynurenine)
-
-
L-tyrosine biosynthesis I
-
-
L-tyrosine degradation I
-
-
L-tyrosine degradation II
-
-
L-tyrosine degradation III
-
-
L-tyrosine degradation IV (to 4-methylphenol)
-
-
L-tyrosine degradation V (reductive Stickland reaction)
-
-
L-valine degradation II
-
-
lacinilene C biosynthesis
-
-
lactate fermentation
-
-
lacto-series glycosphingolipids biosynthesis
-
-
lactose degradation II
-
-
lactose degradation III
-
-
leucine metabolism
-
-
leukotriene biosynthesis
-
-
linalool biosynthesis I
-
-
linamarin degradation
-
-
Linoleic acid metabolism
-
-
linustatin bioactivation
-
-
lipid metabolism
-
-
long chain fatty acid ester synthesis (engineered)
-
-
lotaustralin degradation
-
-
lupulone and humulone biosynthesis
-
-
luteolin triglucuronide degradation
-
-
Lysine degradation
-
-
lysine metabolism
-
-
malate/L-aspartate shuttle pathway
-
-
mandelate degradation I
-
-
manganese oxidation I
-
-
mannitol biosynthesis
-
-
mannitol cycle
-
-
matairesinol biosynthesis
-
-
melatonin degradation I
-
-
melibiose degradation
-
-
Metabolic pathways
-
-
metabolism of disaccharids
-
-
Metabolism of xenobiotics by cytochrome P450
-
-
Methane metabolism
-
-
methane metabolism
-
-
Methanobacterium thermoautotrophicum biosynthetic metabolism
-
-
methanol oxidation to formaldehyde IV
-
-
methiin metabolism
-
-
methionine metabolism
-
-
methyl indole-3-acetate interconversion
-
-
methyl phomopsenoate biosynthesis
-
-
methyl tert-butyl ether degradation
-
-
methylaspartate cycle
methylsalicylate degradation
-
-
mevalonate metabolism
-
-
mevalonate pathway I (eukaryotes and bacteria)
-
-
mevalonate pathway II (haloarchaea)
-
-
mevalonate pathway III (Thermoplasma)
-
-
mevalonate pathway IV (archaea)
-
-
Microbial metabolism in diverse environments
-
-
mitochondrial L-carnitine shuttle
-
-
mixed acid fermentation
-
-
mono-trans, poly-cis decaprenyl phosphate biosynthesis
-
-
monoacylglycerol metabolism (yeast)
-
-
Monobactam biosynthesis
-
-
mupirocin biosynthesis
-
-
mycobacterial sulfolipid biosynthesis
-
-
mycolyl-arabinogalactan-peptidoglycan complex biosynthesis
-
-
myo-inositol biosynthesis
-
-
myristate biosynthesis (mitochondria)
-
-
N-Glycan biosynthesis
-
-
N-methyl-Delta1-pyrrolinium cation biosynthesis
-
-
NAD metabolism
-
-
NAD salvage pathway II (PNC IV cycle)
-
-
NAD salvage pathway V (PNC V cycle)
-
-
NAD(P)/NADPH interconversion
-
-
NADH to cytochrome bd oxidase electron transfer I
-
-
NADH to cytochrome bo oxidase electron transfer I
-
-
Naphthalene degradation
-
-
naringenin biosynthesis (engineered)
-
-
neolinustatin bioactivation
-
-
Neomycin, kanamycin and gentamicin biosynthesis
-
-
Nicotinate and nicotinamide metabolism
-
-
nicotine degradation IV
-
-
nicotine degradation V
-
-
nitrate assimilation
-
-
nitrate reduction I (denitrification)
-
-
nitrate reduction II (assimilatory)
-
-
nitrate reduction IX (dissimilatory)
-
-
nitrate reduction V (assimilatory)
-
-
nitrate reduction VI (assimilatory)
-
-
nitrate reduction VII (denitrification)
-
-
nitrate reduction X (dissimilatory, periplasmic)
-
-
nitric oxide biosynthesis II (mammals)
-
-
nitrifier denitrification
-
-
nitrite-dependent anaerobic methane oxidation
-
-
nitrogen fixation I (ferredoxin)
-
-
Nitrogen metabolism
-
-
nocardicin A biosynthesis
-
-
non-pathway related
-
-
noradrenaline and adrenaline degradation
-
-
noscapine biosynthesis
-
-
Novobiocin biosynthesis
-
-
nucleoside and nucleotide degradation (archaea)
-
-
o-diquinones biosynthesis
-
-
octane oxidation
octanoyl-[acyl-carrier protein] biosynthesis (mitochondria, yeast)
-
-
odd iso-branched-chain fatty acid biosynthesis
-
-
oleandomycin activation/inactivation
-
-
oleate beta-oxidation
-
-
oleate biosynthesis I (plants)
-
-
oleate biosynthesis II (animals and fungi)
-
-
One carbon pool by folate
-
-
ophiobolin F biosynthesis
-
-
Other glycan degradation
-
-
Other types of O-glycan biosynthesis
-
-
oxalate degradation III
-
-
oxalate degradation VI
-
-
Oxidative phosphorylation
-
-
oxidative phosphorylation
-
-
palmatine biosynthesis
-
-
palmitate biosynthesis
-
-
palmitate biosynthesis (type I fatty acid synthase)
-
-
palmitate biosynthesis (type II fatty acid synthase)
-
-
palmitoleate biosynthesis I (from (5Z)-dodec-5-enoate)
-
-
palmitoleate biosynthesis II (plants and bacteria)
-
-
Pantothenate and CoA biosynthesis
-
-
pantothenate biosynthesis
-
-
partial TCA cycle (obligate autotrophs)
-
-
paspaline biosynthesis
-
-
patulin biosynthesis
-
-
pectin degradation I
-
-
pectin degradation II
-
-
pederin biosynthesis
-
-
Penicillin and cephalosporin biosynthesis
-
-
pentachlorophenol degradation
-
-
Pentose and glucuronate interconversions
-
-
Pentose phosphate pathway
-
-
pentose phosphate pathway
-
-
pentose phosphate pathway (non-oxidative branch) I
-
-
pentose phosphate pathway (non-oxidative branch) II
-
-
pentose phosphate pathway (oxidative branch) I
-
-
pentose phosphate pathway (partial)
-
-
Peptidoglycan biosynthesis
-
-
peptidoglycan biosynthesis
-
-
peptidoglycan biosynthesis II (staphylococci)
-
-
peptidoglycan biosynthesis IV (Enterococcus faecium)
-
-
peptidoglycan maturation (meso-diaminopimelate containing)
-
-
petroselinate biosynthesis
-
-
phenol degradation
-
-
phenolphthiocerol biosynthesis
-
-
Phenylalanine metabolism
-
-
phenylalanine metabolism
-
-
Phenylalanine, tyrosine and tryptophan biosynthesis
-
-
phenylethanol biosynthesis
-
-
phenylpropanoid biosynthesis
-
-
Phenylpropanoid biosynthesis
-
-
phenylpropanoid biosynthesis
-
-
phenylpropanoid biosynthesis, initial reactions
-
-
phenylpropanoids methylation (ice plant)
-
-
pheomelanin biosynthesis
-
-
phloridzin biosynthesis
-
-
phosphate acquisition
-
-
phosphatidate metabolism, as a signaling molecule
-
-
phosphatidylcholine acyl editing
-
-
phospholipases
-
-
phospholipid remodeling (phosphatidate, yeast)
-
-
phospholipid remodeling (phosphatidylcholine, yeast)
-
-
phospholipid remodeling (phosphatidylethanolamine, yeast)
-
-
phosphopantothenate biosynthesis I
-
-
Photosynthesis
-
-
photosynthesis
-
-
photosynthesis light reactions
-
-
photosynthetic 3-hydroxybutanoate biosynthesis (engineered)
-
-
phytate degradation I
-
-
phytol degradation
-
-
pinobanksin biosynthesis
-
-
plasmalogen biosynthesis
-
-
plasmalogen degradation
-
-
platensimycin biosynthesis
-
-
plaunotol biosynthesis
-
-
polyamine pathway
-
-
Polycyclic aromatic hydrocarbon degradation
-
-
polyethylene terephthalate degradation
-
-
polyhydroxybutanoate biosynthesis
-
-
Porphyrin and chlorophyll metabolism
-
-
Primary bile acid biosynthesis
-
-
propanethial S-oxide biosynthesis
-
-
propanoate fermentation to 2-methylbutanoate
-
-
Propanoate metabolism
-
-
propanol degradation
-
-
propionate fermentation
-
-
protein N-glycosylation processing phase (plants and animals)
-
-
protein N-glycosylation processing phase (yeast)
-
-
protein O-[N-acetyl]-glucosylation
-
-
protein ubiquitination
-
-
purine deoxyribonucleosides degradation I
-
-
purine deoxyribonucleosides degradation II
-
-
Purine metabolism
-
-
purine metabolism
-
-
purine nucleobases degradation I (anaerobic)
-
-
purine nucleobases degradation II (anaerobic)
-
-
purine ribonucleosides degradation
-
-
putrescine biosynthesis I
-
-
putrescine biosynthesis II
-
-
pyrimidine deoxyribonucleotides biosynthesis from CTP
-
-
Pyrimidine metabolism
-
-
pyrimidine metabolism
-
-
pyrrolnitrin biosynthesis
-
-
pyruvate fermentation to (S)-lactate
-
-
pyruvate fermentation to acetate VIII
-
-
pyruvate fermentation to acetoin III
-
-
pyruvate fermentation to acetone
-
-
pyruvate fermentation to butanoate
-
-
pyruvate fermentation to butanol I
-
-
pyruvate fermentation to butanol II (engineered)
-
-
pyruvate fermentation to ethanol I
-
-
pyruvate fermentation to ethanol II
-
-
pyruvate fermentation to ethanol III
-
-
pyruvate fermentation to hexanol (engineered)
-
-
pyruvate fermentation to isobutanol (engineered)
-
-
pyruvate fermentation to propanoate I
-
-
Pyruvate metabolism
-
-
quinate degradation I
-
-
quinate degradation II
-
-
reactive oxygen species degradation
-
-
rebeccamycin biosynthesis
-
-
reductive acetyl coenzyme A pathway
-
-
reductive acetyl coenzyme A pathway I (homoacetogenic bacteria)
-
-
reductive TCA cycle I
-
-
reductive TCA cycle II
-
-
resolvin D biosynthesis
-
-
retinoate biosynthesis I
-
-
retinol biosynthesis
-
-
Retinol metabolism
-
-
rhamnogalacturonan type I degradation II (bacteria)
-
-
Riboflavin metabolism
-
-
rosmarinic acid biosynthesis I
-
-
Rubisco shunt
-
-
rutin degradation (plants)
-
-
S-methyl-5'-thioadenosine degradation II
-
-
salicylate biosynthesis I
-
-
salidroside biosynthesis
-
-
salinosporamide A biosynthesis
-
-
sanguinarine and macarpine biosynthesis
-
-
scopoletin biosynthesis
-
-
sedoheptulose bisphosphate bypass
-
-
selenate reduction
-
-
seleno-amino acid detoxification and volatilization I
-
-
seleno-amino acid detoxification and volatilization III
-
-
Selenocompound metabolism
-
-
selenocysteine biosynthesis
-
-
serine metabolism
-
-
serotonin and melatonin biosynthesis
-
-
serotonin degradation
-
-
sesamin biosynthesis
-
-
Sesquiterpenoid and triterpenoid biosynthesis
-
-
sitosterol degradation to androstenedione
-
-
solasodine glycosylation
-
-
sophorosyloxydocosanoate deacetylation
-
-
sorbitol biosynthesis II
-
-
sorgoleone biosynthesis
-
-
spermidine biosynthesis III
-
-
Sphingolipid metabolism
-
-
sphingosine and sphingosine-1-phosphate metabolism
-
-
sphingosine metabolism
-
-
sporopollenin precursors biosynthesis
-
-
stachyose degradation
-
-
Starch and sucrose metabolism
-
-
starch biosynthesis
-
-
starch degradation
-
-
starch degradation I
-
-
starch degradation II
-
-
starch degradation III
-
-
starch degradation IV
-
-
starch degradation V
-
-
Staurosporine biosynthesis
-
-
stearate biosynthesis I (animals)
-
-
stearate biosynthesis II (bacteria and plants)
-
-
stearate biosynthesis III (fungi)
-
-
stellatic acid biosynthesis
-
-
stephacidin A biosynthesis
-
-
sterigmatocystin biosynthesis
-
-
Steroid biosynthesis
-
-
Steroid hormone biosynthesis
-
-
sterol:steryl ester interconversion (yeast)
-
-
Stilbenoid, diarylheptanoid and gingerol biosynthesis
-
-
streptomycin biosynthesis
-
-
Streptomycin biosynthesis
-
-
Styrene degradation
-
-
suberin monomers biosynthesis
succinate to cytochrome bd oxidase electron transfer
-
-
succinate to cytochrome bo oxidase electron transfer
-
-
sucrose biosynthesis I (from photosynthesis)
-
-
sucrose biosynthesis II
-
-
sucrose biosynthesis III
-
-
sucrose degradation I (sucrose phosphotransferase)
-
-
sucrose degradation II (sucrose synthase)
-
-
sucrose degradation III (sucrose invertase)
-
-
sucrose degradation IV (sucrose phosphorylase)
-
-
sucrose degradation V (sucrose alpha-glucosidase)
-
-
sucrose degradation VII (sucrose 3-dehydrogenase)
-
-
sulfate activation for sulfonation
-
-
sulfate reduction
-
-
sulfite oxidation III
-
-
sulfolactate degradation III
-
-
sulfopterin metabolism
-
-
Sulfur metabolism
-
-
sulfur volatiles biosynthesis
-
-
superoxide radicals degradation
-
-
superpathway of fermentation (Chlamydomonas reinhardtii)
-
-
superpathway of glucose and xylose degradation
-
-
superpathway of glycolysis and the Entner-Doudoroff pathway
-
-
superpathway of glyoxylate cycle and fatty acid degradation
-
-
superpathway of L-aspartate and L-asparagine biosynthesis
-
-
superpathway of methylsalicylate metabolism
-
-
superpathway of photosynthetic hydrogen production
-
-
superpathway of UDP-glucose-derived O-antigen building blocks biosynthesis
-
-
Taurine and hypotaurine metabolism
-
-
TCA cycle I (prokaryotic)
-
-
TCA cycle II (plants and fungi)
-
-
TCA cycle III (animals)
-
-
TCA cycle IV (2-oxoglutarate decarboxylase)
-
-
TCA cycle V (2-oxoglutarate synthase)
-
-
TCA cycle VI (Helicobacter)
-
-
TCA cycle VII (acetate-producers)
-
-
tea aroma glycosidic precursor bioactivation
-
-
Terpenoid backbone biosynthesis
-
-
tetrahydrofolate metabolism
-
-
tetrapyrrole biosynthesis II (from glycine)
-
-
thiamine diphosphate biosynthesis III (Staphylococcus)
-
-
thiamine diphosphate biosynthesis IV (eukaryotes)
-
-
thiamine diphosphate salvage III
-
-
thiamine diphosphate salvage IV (yeast)
-
-
Thiamine metabolism
-
-
thyroid hormone metabolism II (via conjugation and/or degradation)
-
-
toluene degradation to 2-hydroxypentadienoate (via 4-methylcatechol)
-
-
toluene degradation to 2-hydroxypentadienoate (via toluene-cis-diol)
-
-
toluene degradation to 2-hydroxypentadienoate I (via o-cresol)
-
-
trans, trans-farnesyl diphosphate biosynthesis
-
-
traumatin and (Z)-3-hexen-1-yl acetate biosynthesis
-
-
trehalose biosynthesis V
-
-
trehalose degradation I (low osmolarity)
-
-
trehalose degradation II (cytosolic)
-
-
trehalose degradation IV
-
-
trehalose degradation V
-
-
trehalose degradation VI (periplasmic)
-
-
triacylglycerol degradation
-
-
tRNA charging
-
-
tRNA processing
-
-
Tropane, piperidine and pyridine alkaloid biosynthesis
-
-
Tryptophan metabolism
-
-
tryptophan metabolism
-
-
Tyrosine metabolism
-
-
tyrosine metabolism
-
-
Ubiquinone and other terpenoid-quinone biosynthesis
-
-
UDP-alpha-D-galactose biosynthesis
-
-
UDP-alpha-D-glucose biosynthesis
-
-
UDP-N-acetyl-D-galactosamine biosynthesis II
-
-
UDP-N-acetyl-D-glucosamine biosynthesis II
-
-
UMP biosynthesis I
-
-
UMP biosynthesis II
-
-
UMP biosynthesis III
-
-
urea cycle
urea degradation II
-
-
UTP and CTP dephosphorylation I
-
-
valine metabolism
-
-
Valine, leucine and isoleucine degradation
-
-
valproate beta-oxidation
-
-
vancomycin resistance I
-
-
vanillin biosynthesis I
-
-
Various types of N-glycan biosynthesis
-
-
viridicatumtoxin biosynthesis
-
-
vitamin B1 metabolism
-
-
Vitamin B6 metabolism
-
-
vitamin K metabolism
-
-
vitamin K-epoxide cycle
-
-
wax esters biosynthesis I
-
-
wax esters biosynthesis II
-
-
xanthine and xanthosine salvage
-
-
xanthohumol biosynthesis
-
-
Xylene degradation
-
-
xylitol degradation
-
-
xyloglucan degradation II (exoglucanase)
-
-
Zeatin biosynthesis
-
-
ORGANISM
COMMENTARY hide
LITERATURE
UNIPROT
SEQUENCE DB
SOURCE
SOURCE TISSUE
ORGANISM
UNIPROT
COMMENTARY hide
LITERATURE
SOURCE
enzyme synthesis during formation of germ tubes, the pH droops during germination from pH 5.5 to pH 3.5
Manually annotated by BRENDA team
-
solid culture on wheat bran
Manually annotated by BRENDA team
-
maximum induction of enzyme synthesis by culturing in media containing yeast mannan and a nitrogen source
Manually annotated by BRENDA team
additional information
LOCALIZATION
ORGANISM
UNIPROT
COMMENTARY hide
GeneOntology No.
LITERATURE
SOURCE
-
2 forms: extracellular and cytoplasmic, the cytoplasmic isozymes are immunologically related to extracellular isozyme A2
Manually annotated by BRENDA team
-
in contrast to the wild-type strain in which the inactivated RNase T1-GFP fusion protein is localized at the vacuole only under cold stress or nitrogen starvation, the inactivated RNase T1-GFP fusion protein expressed in the rns4 mutant is localized at the ER and vacuole, both under normal growth conditions and upon ambient stress conditions
Manually annotated by BRENDA team
LINKS TO OTHER DATABASES (specific for Aspergillus oryzae)