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(3R)-linalool biosynthesis
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PWY-7709
(3S)-linalool biosynthesis
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PWY-7141
2'-deoxymugineic acid phytosiderophore biosynthesis
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PWY-5912
3-dehydroquinate biosynthesis I
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PWY-6164
5'-deoxyadenosine degradation II
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PWY-8131
all-trans-farnesol biosynthesis
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PWY-6859
alpha-Linolenic acid metabolism
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Aminobenzoate degradation
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anaerobic aromatic compound degradation (Thauera aromatica)
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BENZCOA-PWY
autoinducer AI-2 biosynthesis I
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PWY-6153
autoinducer AI-2 biosynthesis II (Vibrio)
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PWY-6154
avenanthramide biosynthesis
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PWY-8157
baicalein degradation (hydrogen peroxide detoxification)
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PWY-7214
benzoate biosynthesis I (CoA-dependent, beta-oxidative)
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PWY-6443
benzoate degradation II (aerobic and anaerobic)
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PWY-283
betanidin degradation
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PWY-5461
Biosynthesis of secondary metabolites
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Biosynthesis of type II polyketide products
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bisabolene biosynthesis (engineered)
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PWY-7102
capsaicin biosynthesis
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PWY-5710
chlorogenic acid biosynthesis I
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PWY-6039
chorismate metabolism
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cis-zeatin biosynthesis
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PWY-2781
coumarins biosynthesis (engineered)
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PWY-7398
curcuminoid biosynthesis
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PWY-6432
Cysteine and methionine metabolism
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daunorubicin biosynthesis
Entner-Doudoroff pathway I
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PWY-8004
epoxypseudoisoeugenol-2-methylbutanoate biosynthesis
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PWY-5882
ethene biosynthesis I (plants)
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ETHYL-PWY
eugenol and isoeugenol biosynthesis
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PWY-5859
ferulate and sinapate biosynthesis
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PWY-5168
Flavonoid biosynthesis
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formaldehyde oxidation I
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RUMP-PWY
free phenylpropanoid acid biosynthesis
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PWY-2181
geranyl acetate biosynthesis
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PWY-5835
geranyl diphosphate biosynthesis
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PWY-5122
glucosylglycerol biosynthesis
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PWY-7902
Glycerolipid metabolism
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heterolactic fermentation
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P122-PWY
ipsdienol biosynthesis
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PWY-7410
isoprene biosynthesis II (engineered)
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PWY-7391
isoprenoid biosynthesis
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justicidin B biosynthesis
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PWY-6824
L-cysteine biosynthesis VI (reverse transsulfuration)
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PWY-I9
L-methionine degradation I (to L-homocysteine)
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METHIONINE-DEG1-PWY
linalool biosynthesis I
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PWY-7182
luteolin triglucuronide degradation
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PWY-7445
matairesinol biosynthesis
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PWY-5466
methionine metabolism
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methyl indole-3-acetate interconversion
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PWY-6303
methylerythritol phosphate pathway I
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NONMEVIPP-PWY
methylerythritol phosphate pathway II
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PWY-7560
methylsalicylate biosynthesis
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PWY18C3-22
mevalonate metabolism
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mevalonate pathway I (eukaryotes and bacteria)
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PWY-922
mevalonate pathway II (haloarchaea)
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PWY-6174
mevalonate pathway III (Thermoplasma)
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PWY-7524
mevalonate pathway IV (archaea)
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PWY-8125
Microbial metabolism in diverse environments
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mono-trans, poly-cis decaprenyl phosphate biosynthesis
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PWY-6383
Monoterpenoid biosynthesis
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Pentose phosphate pathway
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pentose phosphate pathway
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pentose phosphate pathway (oxidative branch) I
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OXIDATIVEPENT-PWY
Phenylalanine, tyrosine and tryptophan biosynthesis
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phenylethyl acetate biosynthesis
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PWY-7075
phenylpropanoid biosynthesis
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PWY-361
Phenylpropanoid biosynthesis
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phenylpropanoid biosynthesis
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phenylpropanoids methylation (ice plant)
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PWY-7498
retinol biosynthesis
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PWY-6857
S-adenosyl-L-methionine biosynthesis
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SAM-PWY
S-adenosyl-L-methionine salvage I
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PWY-6151
S-adenosyl-L-methionine salvage II
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PWY-5041
S-methyl-5'-thioadenosine degradation I
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PWY-6754
S-methyl-5'-thioadenosine degradation IV
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PWY0-1391
salicortin biosynthesis
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PWY-6763
scopoletin biosynthesis
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PWY-6792
sesamin biosynthesis
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PWY-5469
Starch and sucrose metabolism
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stellatic acid biosynthesis
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PWY-7736
Stilbenoid, diarylheptanoid and gingerol biosynthesis
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suberin monomers biosynthesis
superpathway of glycolysis and the Entner-Doudoroff pathway
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GLYCOLYSIS-E-D
superpathway of scopolin and esculin biosynthesis
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PWY-7186
Terpenoid backbone biosynthesis
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tetrahydroxyxanthone biosynthesis (from benzoate)
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PWY-5001
trans, trans-farnesyl diphosphate biosynthesis
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PWY-5123
triacylglycerol degradation
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LIPAS-PWY
viridicatumtoxin biosynthesis
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PWY-7659
volatile benzenoid biosynthesis I (ester formation)
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PWY-4203
volatile cinnamoic ester biosynthesis
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PWY-4201
volatile esters biosynthesis (during fruit ripening)
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PWY-6801
xanthommatin biosynthesis
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PWY-8249
daunorubicin biosynthesis
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PWY-7352
daunorubicin biosynthesis
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suberin monomers biosynthesis
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PWY-1121
suberin monomers biosynthesis
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reduced BAMT activity
brenda
expression in days 1-3 of open flowers
brenda
expression mainly in epidermis
brenda
no expression in the leaves under normal conditions. BEBT expression is induced in damaged leaves, reaching a maximum 6 h after damage occurres
brenda
expression in flower buds, not in open flowers
brenda
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reduced BAMT activity
brenda
-
brenda
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monoterpenes are produced in unopened buds and in open flowers with a peak at 2-3 days of anthesis
brenda
the BEBT gene is expressed in different parts of the flowers with maximal RNA transcript levels in the stigma
brenda
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the highest specific activity levels of eugenol synthase are found in the stamens, followed closely by the pistil and petals
brenda
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brenda
30% of the activity in stigma
brenda
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high enzyme activity, linalool is emitted
brenda
highest expression level of LIS2
brenda
highest SAMT activity compared to the levels of activity in all other floral parts or the vegetative tissue
brenda
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in upper and lower lobes, major activity of BAMT
brenda
of flower buds and open flowers, expression mainly in epidermis
brenda
petal contain the majority of BEAT transcripts
brenda
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brenda
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high enzyme activity, linalool is mostly converted to linalool oxide
brenda
30% of the activity in stigma
brenda
very low expression level of LIS1
brenda
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brenda
30% of the activity in stigma
brenda
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high enzyme activity, linalool is mostly converted to linalool oxide
brenda
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brenda
highest expression level of LIS1
brenda
of open flowers, high expression level in the secretory zone, between the papillate epidermis and parenchyma cells, converging into the style as a central region of transmitting tissue
brenda
the BEBT gene is expressed in different parts of the flowers with maximal RNA transcript levels in the stigma
brenda
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brenda
high expression level, in the transmitting tissue but not in the vascular system or the stylar epidermis
brenda
additional information
floral tissue-specific expression levels of LIS1 and LIS2, overview, no expression in vegetative tissues
brenda
additional information
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no BAMT activity in pistil, stamen, sepal, ovary and leaf tissue
brenda
additional information
no BEAT mRNA is detected in leaves
brenda
additional information
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the monoterpene is emitted soon after its synthesis
brenda
additional information
tissue specific expression dependent on developmental stage of flowers, no activity in leaves, no expression in sepals
brenda
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