2.5.1.32: 15-cis-phytoene synthase
This is an abbreviated version!
For detailed information about 15-cis-phytoene synthase, go to the full flat file.
Word Map on EC 2.5.1.32
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2.5.1.32
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carotenoid
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desaturase
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carotenogenic
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ripening
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carotenogenesis
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orange
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zeaxanthin
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carotene
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astaxanthin
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lutein
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capsicum
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xanthophyl
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annuum
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xanthophyllomyces
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provitamin
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apocarotenoids
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dendrorhous
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violaxanthin
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zeta-carotene
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chromoplast
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nutrition
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alpha-carotene
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ananatis
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pantoea
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krabbe
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canthaxanthin
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analysis
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phaffia
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dunaliella
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9-cis-epoxycarotenoid
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ketolase
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uredovora
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pluvialis
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food industry
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ketocarotenoids
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norflurazon
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beta-cryptoxanthin
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beta-cyclase
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carra
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haematococcus
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biofortification
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biotechnology
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agriculture
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galcs
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rhodozyma
- 2.5.1.32
-
carotenoid
-
desaturase
-
carotenogenic
-
ripening
-
carotenogenesis
- orange
- zeaxanthin
- carotene
- astaxanthin
- lutein
- capsicum
-
xanthophyl
- annuum
- xanthophyllomyces
-
provitamin
-
apocarotenoids
- dendrorhous
- violaxanthin
- zeta-carotene
- chromoplast
- nutrition
- alpha-carotene
- ananatis
- pantoea
- krabbe
- canthaxanthin
- analysis
- phaffia
- dunaliella
-
9-cis-epoxycarotenoid
-
ketolase
- uredovora
- pluvialis
- food industry
-
ketocarotenoids
- norflurazon
- beta-cryptoxanthin
-
beta-cyclase
-
carra
- haematococcus
-
biofortification
- biotechnology
- agriculture
-
galcs
- rhodozyma
Reaction
2 geranylgeranyl diphosphate = + 2 diphosphate
Synonyms
AtPSY, CitPsy, CrtB, crtYB, EgcrtB, fruit-specific phytoene synthase, geranylgeranyl-diphosphate geranylgeranyltransferase, MaPsy1, MaPsy2, phytoene synthase, phytoene synthase 1, phytoene synthase 2, phytoene synthase/lycopene cyclase, phytoene synthetase, phytoene-synthetase, prephytoene-diphosphate synthase, Psase, PSY, PSY protein, PSY1, PSY1a, PSY1b, PSY1C, PSY2, PSY3, PSY5, synthetase, phytoene, sZmPSY1, TaPSY1, TaPSY2, TaPSY3, YELLOW-FRUITED TOMATO 2, yft2, Zmpsy1
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Synonyms
Synonyms on EC 2.5.1.32 - 15-cis-phytoene synthase
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CitPsy
CrtB
crtYB
EgcrtB
geranylgeranyl-diphosphate geranylgeranyltransferase
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phytoene synthase
phytoene synthase 2
phytoene synthase/lycopene cyclase
phytoene synthetase
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phytoene-synthetase
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-
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prephytoene-diphosphate synthase
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-
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Psase
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PSY
PSY protein
PSY1
PSY1a
PSY1b
PSY2
PSY3
synthetase, phytoene
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-
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phytoene synthase 2
Capsicum annuum MicroPep Yellow
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PSY
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An ancient gene duplication event leads to a class I PSY (I) and a class II PSY (II) in Haptophyta, Rhodophyta, Heterokontophyta as well as Pelagophyceae and Prasinophyceae. Both PSY classes share the essential characteristics of PSY including predicted substrate-Mg2+-binding sites (Aspartate-rich regions) and catalytic residues. Major differences between the two PSY classes appear to exist only in regions not essential to the enzymatic function.
PSY
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Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY
-
Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY
-
An ancient gene duplication event leads to a class I PSY (I) and a class II PSY (II) in Haptophyta, Rhodophyta, Heterokontophyta as well as Pelagophyceae and Prasinophyceae. Both PSY classes share the essential characteristics of PSY including predicted substrate-Mg2+-binding sites (Aspartate-rich regions) and catalytic residues. Major differences between the two PSY classes appear to exist only in regions not essential to the enzymatic function.
PSY
Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY
Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY
Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY
-
An ancient gene duplication event leads to a class I PSY (I) and a class II PSY (II) in Haptophyta, Rhodophyta, Heterokontophyta as well as Pelagophyceae and Prasinophyceae. Both PSY classes share the essential characteristics of PSY including predicted substrate-Mg2+-binding sites (Aspartate-rich regions) and catalytic residues. Major differences between the two PSY classes appear to exist only in regions not essential to the enzymatic function.
PSY
Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY
-
An ancient gene duplication event leads to a class I PSY (I) and a class II PSY (II) in Haptophyta, Rhodophyta, Heterokontophyta as well as Pelagophyceae and Prasinophyceae. Both PSY classes share the essential characteristics of PSY including predicted substrate-Mg2+-binding sites (Aspartate-rich regions) and catalytic residues. Major differences between the two PSY classes appear to exist only in regions not essential to the enzymatic function.
PSY
-
An ancient gene duplication event leads to a class I PSY (I) and a class II PSY (II) in Haptophyta, Rhodophyta, Heterokontophyta as well as Pelagophyceae and Prasinophyceae. Both PSY classes share the essential characteristics of PSY including predicted substrate-Mg2+-binding sites (Aspartate-rich regions) and catalytic residues. Major differences between the two PSY classes appear to exist only in regions not essential to the enzymatic function.
PSY
-
Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY
-
An ancient gene duplication event leads to a class I PSY (I) and a class II PSY (II) in Haptophyta, Rhodophyta, Heterokontophyta as well as Pelagophyceae and Prasinophyceae. Both PSY classes share the essential characteristics of PSY including predicted substrate-Mg2+-binding sites (Aspartate-rich regions) and catalytic residues. Major differences between the two PSY classes appear to exist only in regions not essential to the enzymatic function.
PSY
-
An ancient gene duplication event leads to a class I PSY (I) and a class II PSY (II) in Haptophyta, Rhodophyta, Heterokontophyta as well as Pelagophyceae and Prasinophyceae. Both PSY classes share the essential characteristics of PSY including predicted substrate-Mg2+-binding sites (Aspartate-rich regions) and catalytic residues. Major differences between the two PSY classes appear to exist only in regions not essential to the enzymatic function.
PSY
-
An ancient gene duplication event leads to a class I PSY (I) and a class II PSY (II) in Haptophyta, Rhodophyta, Heterokontophyta as well as Pelagophyceae and Prasinophyceae. Both PSY classes share the essential characteristics of PSY including predicted substrate-Mg2+-binding sites (Aspartate-rich regions) and catalytic residues. Major differences between the two PSY classes appear to exist only in regions not essential to the enzymatic function.
PSY
-
An ancient gene duplication event leads to a class I PSY (I) and a class II PSY (II) in Haptophyta, Rhodophyta, Heterokontophyta as well as Pelagophyceae and Prasinophyceae. Both PSY classes share the essential characteristics of PSY including predicted substrate-Mg2+-binding sites (Aspartate-rich regions) and catalytic residues. Major differences between the two PSY classes appear to exist only in regions not essential to the enzymatic function.
PSY
Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY
Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY
-
Chlorophyceae, Streptophyta and Cyanophyta expresses class I PSY (I)
PSY1
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in poaceae there are three genes encoding PSY, which are expressed in different pattern providing fine control of carotenogenesis that serves numerous physiological purposes
PSY1
Sorghum sp.
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in poaceae there are three genes encoding PSY, which are expressed in different pattern providing fine control of carotenogenesis that serves numerous physiological purposes
PSY1
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in poaceae there are three genes encoding PSY, which are expressed in different pattern providing fine control of carotenogenesis that serves numerous physiological purposes
PSY2
Capsicum annuum MicroPep Yellow
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-
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PSY2
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in poaceae there are three genes encoding PSY, which are expressed in different pattern providing fine control of carotenogenesis that serves numerous physiological purposes
PSY2
Sorghum sp.
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in poaceae there are three genes encoding PSY, which are expressed in different pattern providing fine control of carotenogenesis that serves numerous physiological purposes
PSY2
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in poaceae there are three genes encoding PSY, which are expressed in different pattern providing fine control of carotenogenesis that serves numerous physiological purposes
-
in poaceae there are three genes encoding PSY, which are expressed in different pattern providing fine control of carotenogenesis that serves numerous physiological purposes
PSY3
Sorghum sp.
-
in poaceae there are three genes encoding PSY, which are expressed in different pattern providing fine control of carotenogenesis that serves numerous physiological purposes
PSY3
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in poaceae there are three genes encoding PSY, which are expressed in different pattern providing fine control of carotenogenesis that serves numerous physiological purposes