Literature summary for 3.3.2.10 extracted from

Newman, J.W.; Morisseau, C.; Hammock, B.D.
Epoxide hydrolases: their roles and interactions with lipid metabolism (2005), Prog. Lipid Res., 44, 1-51.

Activating Compound

Activating Compound	Comment	Organism
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Vicia sativa
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Triticum aestivum
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Spinacia oleracea
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Brassica napus
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Ricinus communis
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Apium graveolens
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Oryza sativa
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Ananas comosus
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Euphorbia lagascae
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth	Malus pumila
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth, ethylene induces the enzyme in germinating seeds	Glycine max
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth, pathogenic fungus infection induces the enzyme in leaves	Citrus jambhiri
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, exogenous exposure to hormones, growth, viral infection of the aerial body and the plant induces the enzyme	Nicotiana tabacum
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, growth, the enzyme is not affected by cytokinin, abscisic acid, 6-benzylaminopurine, or gibberellin, but highly by methyl jasmonate, auxin, and ethylene, wounding induces the enzyme in leaves	Solanum tuberosum
additional information	inducible isozymes can be induced by e.g. fruit ripening, germination, host-defense, growth, the enzyme is not affected by cytokinin, abscisic acid, 6-benzylaminopurine, or gibberellin, while auxin, 2,4-dichlorophenoxy acetic acid, and naphthalene acetic acid induce the enzyme in stem and leaves, drought stress slightly induces the enzmye in stem and leaves	Arabidopsis thaliana
additional information	the enzyme is induced by clofibrate	Cavia porcellus
additional information	the enzyme is induced by clofibrate	Homo sapiens
additional information	the enzyme is induced by clofibrate	Rattus norvegicus
additional information	the enzyme is induced by clofibrate	Sus scrofa
additional information	the enzyme is induced by clofibrate	Oryctolagus cuniculus
additional information	the enzyme is induced by clofibrate	Mesocricetus auratus
additional information	the enzyme is induced by clofibrate	Equus caballus
additional information	the enzyme is induced by clofibrate	Macaca mulatta
additional information	the enzyme is induced by clofibrate	Papio sp.
additional information	the enzyme is induced by clofibrate	Mus musculus

Protein Variants

Protein Variants	Comment	Organism
additional information	enzyme polymorphisms, overview	Homo sapiens
R287E	naturally occuring mutation of gene EPXH2 leads to elevated plasma cholesterol and triglycerides	Homo sapiens
R287Q	naturally occuring mutation of gene EPXH2 leads to elevated risk of coronary artery calcification found in African Americans	Homo sapiens

Localization

Localization	Comment	Organism	GeneOntology No.	Textmining
cytosol	-	Vicia sativa	5829	-
cytosol	-	Cavia porcellus	5829	-
cytosol	-	Homo sapiens	5829	-
cytosol	-	Rattus norvegicus	5829	-
cytosol	-	Sus scrofa	5829	-
cytosol	-	Triticum aestivum	5829	-
cytosol	-	Oryctolagus cuniculus	5829	-
cytosol	-	Spinacia oleracea	5829	-
cytosol	-	Zea mays	5829	-
cytosol	-	Solanum tuberosum	5829	-
cytosol	-	Nicotiana tabacum	5829	-
cytosol	-	Glycine max	5829	-
cytosol	-	Arabidopsis thaliana	5829	-
cytosol	-	Brassica napus	5829	-
cytosol	-	Ricinus communis	5829	-
cytosol	-	Mesocricetus auratus	5829	-
cytosol	-	Equus caballus	5829	-
cytosol	-	Apium graveolens	5829	-
cytosol	-	Macaca mulatta	5829	-
cytosol	-	Oryza sativa	5829	-
cytosol	-	Oncorhynchus mykiss	5829	-
cytosol	-	Ananas comosus	5829	-
cytosol	-	Oryzias latipes	5829	-
cytosol	-	Papio sp.	5829	-
cytosol	-	Euphorbia lagascae	5829	-
cytosol	-	Mus musculus	5829	-
cytosol	-	Citrus jambhiri	5829	-
cytosol	-	Malus pumila	5829	-
cytosol	-	Pimephales promelas	5829	-
cytosol	-	Stenotomus chrysops	5829	-
glyoxysome	-	Ricinus communis	9514	-
peroxisome	in the light mitochondrial fraction	Mus musculus	5777	-
peroxisome	the enzyme contains an impaired peroxisomal targeting sequence leading to dual localization	Rattus norvegicus	5777	-

Molecular Weight [Da]

Molecular Weight [Da]	Molecular Weight Maximum [Da]	Comment	Organism
35000	-	n * 35000, about	Solanum tuberosum
35000	-	n * 35000, about	Glycine max
35000	-	n * 35000, about	Arabidopsis thaliana
35000	-	n * 35000, about	Ricinus communis
35000	-	x * 35000, about	Vicia sativa
35000	-	x * 35000, about	Triticum aestivum
35000	-	x * 35000, about	Spinacia oleracea
35000	-	x * 35000, about	Nicotiana tabacum
35000	-	x * 35000, about	Brassica napus
35000	-	x * 35000, about	Apium graveolens
35000	-	x * 35000, about	Oryza sativa
35000	-	x * 35000, about	Ananas comosus
35000	-	x * 35000, about	Euphorbia lagascae
35000	-	x * 35000, about	Citrus jambhiri
35000	-	x * 35000, about	Malus pumila
62000	-	2 * 62000, about	Cavia porcellus
62000	-	2 * 62000, about	Homo sapiens
62000	-	2 * 62000, about	Rattus norvegicus
62000	-	2 * 62000, about	Sus scrofa
62000	-	2 * 62000, about	Oryctolagus cuniculus
62000	-	2 * 62000, about	Mesocricetus auratus
62000	-	2 * 62000, about	Equus caballus
62000	-	2 * 62000, about	Macaca mulatta
62000	-	2 * 62000, about	Papio sp.
62000	-	2 * 62000, about	Mus musculus

Natural Substrates/ Products (Substrates)

Natural Substrates	Organism	Comment (Nat. Sub.)	Natural Products	Comment (Nat. Pro.)	Rev.
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	Solanum tuberosum	-	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	Citrus jambhiri	-	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	Malus pumila	step in cutin biosynthesis	?	-	?
additional information	Homo sapiens	enzyme regulation, overview	?	-	?
additional information	Oncorhynchus mykiss	enzyme regulation, overview	?	-	?
additional information	Oryzias latipes	enzyme regulation, overview	?	-	?
additional information	Pimephales promelas	enzyme regulation, overview	?	-	?
additional information	Stenotomus chrysops	enzyme regulation, overview	?	-	?
additional information	Vicia sativa	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Triticum aestivum	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Spinacia oleracea	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Zea mays	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Nicotiana tabacum	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Glycine max	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Arabidopsis thaliana	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Brassica napus	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Ricinus communis	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Apium graveolens	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Oryza sativa	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Ananas comosus	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Euphorbia lagascae	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Malus pumila	synthesis of anti-fungal substances in fruits, the enzyme is involved in host-defense and cutin biosynthesis, preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Citrus jambhiri	the enzyme is involved in host-defense and cutin biosynthesis, preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Solanum tuberosum	the enzyme is involved in host-defense and cutin biosynthesis, synthesis of (9S,10S,11R)-trihydroxy-12(Z)-octadecenoic and (9S,12S,13S)-trihydroxy-10(E)-octadecenoic acids with potent anti-fungal properties, preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	?	-	?
additional information	Cavia porcellus	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	?	-	?
additional information	Rattus norvegicus	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	?	-	?
additional information	Sus scrofa	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	?	-	?
additional information	Oryctolagus cuniculus	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	?	-	?
additional information	Mesocricetus auratus	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	?	-	?
additional information	Equus caballus	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	?	-	?
additional information	Macaca mulatta	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	?	-	?
additional information	Papio sp.	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lipid/carbohydrate metabolism, enzyme regulation, overview	?	-	?
additional information	Mus musculus	the enzyme is involved in synthesis of tetrahydrofuran diol and trihydroxy furanyl lipids, enzyme regulation, overview	?	-	?

Organism

Organism	UniProt	Comment	Textmining
Ananas comosus	-	multiple isozymes, constitutive and inducible	-
Apium graveolens	-	multiple isozymes, constitutive and inducible	-
Arabidopsis thaliana	-	multiple isozymes, constitutive and inducible	-
Brassica napus	-	multiple isozymes, constitutive and inducible	-
Cavia porcellus	-	-	-
Citrus jambhiri	-	multiple isozymes, constitutive and inducible	-
Equus caballus	-	-	-
Euphorbia lagascae	-	multiple isozymes, constitutive and inducible	-
Glycine max	-	multiple isozymes, constitutive and inducible	-
Homo sapiens	-	-	-
Macaca mulatta	-	-	-
Malus pumila	-	multiple isozymes, constitutive and inducible	-
Mesocricetus auratus	-	-	-
Mus musculus	P34914	isozyme EPXH2B	-
Nicotiana tabacum	-	multiple isozymes, constitutive and infection-induced	-
Oncorhynchus mykiss	-	-	-
Oryctolagus cuniculus	-	-	-
Oryza sativa	-	multiple isozymes, constitutive and inducible	-
Oryzias latipes	-	-	-
Papio sp.	-	baboon	-
Pimephales promelas	-	-	-
Rattus norvegicus	-	-	-
Ricinus communis	-	multiple isozymes, constitutive and inducible	-
Solanum tuberosum	-	multiple isozymes, constitutive and inducible	-
Spinacia oleracea	-	multiple isozymes, constitutive and inducible	-
Stenotomus chrysops	-	-	-
Sus scrofa	-	-	-
Triticum aestivum	-	multiple isozymes, constitutive and inducible	-
Vicia sativa	-	multiple isozymes, constitutive and inducible	-
Zea mays	-	multiple isozymes	-

Purification (Commentary)

Purification (Comment)	Organism
from liver	Cavia porcellus
from liver	Mus musculus

Source Tissue

Source Tissue	Comment	Organism	Textmining
adrenal gland	-	Homo sapiens	-
aerial part	-	Nicotiana tabacum	-
brain	-	Rattus norvegicus	-
endosperm	-	Ricinus communis	-
endothelium	vascular	Homo sapiens	-
epididymis	-	Homo sapiens	-
fruit	-	Malus pumila	-
gonad	-	Homo sapiens	-
heart	-	Rattus norvegicus	-
intestine	-	Homo sapiens	-
kidney	cortex	Homo sapiens	-
kidney	cortex	Rattus norvegicus	-
kidney	cortex	Mus musculus	-
leaf	-	Nicotiana tabacum	-
leaf	-	Arabidopsis thaliana	-
leaf	-	Citrus jambhiri	-
leaf	meristem shows increased enzyme level compared to expanding and mature leaves	Solanum tuberosum	-
leukocyte	-	Rattus norvegicus	-
liver	-	Cavia porcellus	-
liver	-	Homo sapiens	-
liver	-	Rattus norvegicus	-
liver	-	Mus musculus	-
lung	-	Rattus norvegicus	-
lymph node	-	Homo sapiens	-
mammary gland	-	Mus musculus	-
additional information	tissue distribution	Vicia sativa	-
additional information	tissue distribution	Cavia porcellus	-
additional information	tissue distribution	Homo sapiens	-
additional information	tissue distribution	Rattus norvegicus	-
additional information	tissue distribution	Sus scrofa	-
additional information	tissue distribution	Triticum aestivum	-
additional information	tissue distribution	Oryctolagus cuniculus	-
additional information	tissue distribution	Spinacia oleracea	-
additional information	tissue distribution	Zea mays	-
additional information	tissue distribution	Solanum tuberosum	-
additional information	tissue distribution	Nicotiana tabacum	-
additional information	tissue distribution	Glycine max	-
additional information	tissue distribution	Arabidopsis thaliana	-
additional information	tissue distribution	Brassica napus	-
additional information	tissue distribution	Ricinus communis	-
additional information	tissue distribution	Mesocricetus auratus	-
additional information	tissue distribution	Equus caballus	-
additional information	tissue distribution	Apium graveolens	-
additional information	tissue distribution	Macaca mulatta	-
additional information	tissue distribution	Oryza sativa	-
additional information	tissue distribution	Oncorhynchus mykiss	-
additional information	tissue distribution	Ananas comosus	-
additional information	tissue distribution	Oryzias latipes	-
additional information	tissue distribution	Papio sp.	-
additional information	tissue distribution	Euphorbia lagascae	-
additional information	tissue distribution	Mus musculus	-
additional information	tissue distribution	Citrus jambhiri	-
additional information	tissue distribution	Malus pumila	-
additional information	tissue distribution	Pimephales promelas	-
additional information	tissue distribution	Stenotomus chrysops	-
muscle	striated	Mus musculus	-
ovary	-	Homo sapiens	-
ovary	-	Mus musculus	-
pancreas	-	Homo sapiens	-
placenta	-	Homo sapiens	-
prostate	-	Homo sapiens	-
seed	germinating	Glycine max	-
seed	germination-specific isozyme	Euphorbia lagascae	-
skin	-	Rattus norvegicus	-
smooth muscle	-	Homo sapiens	-
spleen	-	Rattus norvegicus	-
stem	-	Arabidopsis thaliana	-
stomach	-	Homo sapiens	-
testis	-	Rattus norvegicus	-
tonsil	-	Homo sapiens	-
urinary bladder	-	Homo sapiens	-
uterus	-	Homo sapiens	-

Substrates and Products (Substrate)

Substrates	Comment Substrates	Organism	Products	Comment (Products)	Rev.
11,12-leukotriene A4 + H2O	-	Cavia porcellus	?	-	?
11R,12S-epoxyeicosatrienoic acid + H2O	-	Mus musculus	11R,12S-dihydroxyeicosatrienoic acid	-	?
11S,12R-epoxyeicosatrienoic acid + H2O	-	Mus musculus	11S,12R-hydroxyeicosatrienoic acid	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Vicia sativa	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Triticum aestivum	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Spinacia oleracea	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Zea mays	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Solanum tuberosum	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Nicotiana tabacum	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Glycine max	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Arabidopsis thaliana	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Brassica napus	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Ricinus communis	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Apium graveolens	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Oryza sativa	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Ananas comosus	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Euphorbia lagascae	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Citrus jambhiri	?	-	?
12,13-epoxy octadeca-(9Z)-eneoic acid + H2O	-	Malus pumila	?	-	?
14,15-leukotriene A4 + H2O	-	Cavia porcellus	?	-	?
14R,15S-epoxyeicosatrienoic acid + H2O	-	Mus musculus	14R,15S-dihydroxyeicosatrienoic acid	-	?
14S,15R-epoxyeicosatrienoic acid + H2O	-	Mus musculus	14S,15R-dihydroxyeicosatrienoic acid	-	?
14S,15S-trans-epoxy-(5Z,8Z,10E,12E)-eicosatetraenoic acid + H2O	-	Mus musculus	14S,15R-dihydroxy-(5Z,8Z,10E,12E)-eicosatetraenoic acid	-	?
5,6-leukotriene A4 + H2O	-	Cavia porcellus	?	-	?
8R,9S-epoxyeicosatrienoic acid + H2O	-	Mus musculus	8R,9S-dihydroxyeicosatrienoic acid	-	?
8S,9R-epoxyeicosatrienoic acid + H2O	-	Mus musculus	8S,9R-dihydroxyeicosatrienoic acid	-	?
9(10),12(13)-diepoxyoctadecanoic acid + H2O	-	Mus musculus	9,10,12,13-tetrahydroxyoctadecanoic acid	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Vicia sativa	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Spinacia oleracea	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Arabidopsis thaliana	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Brassica napus	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Ricinus communis	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Ananas comosus	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Euphorbia lagascae	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Citrus jambhiri	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Malus pumila	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	no enantioselectivity	Triticum aestivum	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	no enantioselectivity	Zea mays	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	no enantioselectivity	Oryza sativa	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	no enantioselectivity of infection-induced isozymes, conversion of the (S)-carbon to the corresponding threo-(R,R)-diol in over 85%	Nicotiana tabacum	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	the enzyme prefers the (9R,10S)-enantiomer	Apium graveolens	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	the enzyme prefers the (9R,10S)-enantiomer, conversion of the (S)-carbon to the corresponding threo-(R,R)-diol in over 85%	Solanum tuberosum	?	-	?
9,10-epoxy octadeca-(12Z)-eneoic acid + H2O	the enzyme strongly prefers the (9R,10S)-enantiomer, conversion of the (S)-carbon to the corresponding threo-(R,R)-diol in over 85%	Glycine max	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Vicia sativa	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Triticum aestivum	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Spinacia oleracea	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Zea mays	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Solanum tuberosum	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Nicotiana tabacum	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Glycine max	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Arabidopsis thaliana	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Brassica napus	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Ricinus communis	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Apium graveolens	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Oryza sativa	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Ananas comosus	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Euphorbia lagascae	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Citrus jambhiri	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	-	Malus pumila	?	-	?
9,10-epoxy-18-hydroxy octadeca-(12Z)-eneoic acid + H2O	step in cutin biosynthesis	Malus pumila	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Vicia sativa	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Triticum aestivum	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Spinacia oleracea	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Zea mays	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Solanum tuberosum	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Nicotiana tabacum	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Glycine max	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Arabidopsis thaliana	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Brassica napus	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Ricinus communis	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Apium graveolens	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Oryza sativa	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Ananas comosus	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Euphorbia lagascae	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Citrus jambhiri	?	-	?
9-hydroxy-10,11-epoxy octadeca-(12Z)-eneoic acid + H2O	-	Malus pumila	?	-	?
additional information	enzyme regulation, overview	Homo sapiens	?	-	?
additional information	enzyme regulation, overview	Oncorhynchus mykiss	?	-	?
additional information	enzyme regulation, overview	Oryzias latipes	?	-	?
additional information	enzyme regulation, overview	Pimephales promelas	?	-	?
additional information	enzyme regulation, overview	Stenotomus chrysops	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Vicia sativa	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Triticum aestivum	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Spinacia oleracea	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Zea mays	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Nicotiana tabacum	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Glycine max	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Arabidopsis thaliana	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Brassica napus	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Ricinus communis	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Apium graveolens	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Oryza sativa	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Ananas comosus	?	-	?
additional information	preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Euphorbia lagascae	?	-	?
additional information	synthesis of anti-fungal substances in fruits, the enzyme is involved in host-defense and cutin biosynthesis, preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Malus pumila	?	-	?
additional information	the enzyme is involved in host-defense and cutin biosynthesis, preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Citrus jambhiri	?	-	?
additional information	the enzyme is involved in host-defense and cutin biosynthesis, synthesis of (9S,10S,11R)-trihydroxy-12(Z)-octadecenoic and (9S,12S,13S)-trihydroxy-10(E)-octadecenoic acids with potent anti-fungal properties, preferred endogenous substrates are epoxides containing fatty acids, e.g. epoxides of stearic and linoleic acids, and hepoxilins	Solanum tuberosum	?	-	?
additional information	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	Cavia porcellus	?	-	?
additional information	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	Rattus norvegicus	?	-	?
additional information	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	Sus scrofa	?	-	?
additional information	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	Oryctolagus cuniculus	?	-	?
additional information	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	Mesocricetus auratus	?	-	?
additional information	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	Equus caballus	?	-	?
additional information	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lidpi/carbohydrate metabolism, enzyme regulation, overview	Macaca mulatta	?	-	?
additional information	the enzyme is involved in metabolism of epoxide lipids in blood pressure, inflammation, reproduction and in lipid/carbohydrate metabolism, enzyme regulation, overview	Papio sp.	?	-	?
additional information	the enzyme is involved in synthesis of tetrahydrofuran diol and trihydroxy furanyl lipids, enzyme regulation, overview	Mus musculus	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Vicia sativa	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Triticum aestivum	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Spinacia oleracea	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Zea mays	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Solanum tuberosum	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Nicotiana tabacum	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Glycine max	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Arabidopsis thaliana	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Brassica napus	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Ricinus communis	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Apium graveolens	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Oryza sativa	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Ananas comosus	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Euphorbia lagascae	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Citrus jambhiri	?	-	?
additional information	plant enzymes prefer trans- over cis-epoxides of sterically hindered substrates like stilbene oxides	Malus pumila	?	-	?
additional information	substrate specificity, the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates, except for the isozyme EPXH2B, overview	Mus musculus	?	-	?
additional information	the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Cavia porcellus	?	-	?
additional information	the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Sus scrofa	?	-	?
additional information	the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Oryctolagus cuniculus	?	-	?
additional information	the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Mesocricetus auratus	?	-	?
additional information	the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Equus caballus	?	-	?
additional information	the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Macaca mulatta	?	-	?
additional information	the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Papio sp.	?	-	?
additional information	the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates, overview	Homo sapiens	?	-	?
additional information	the enzyme prefers trans- over cis-epoxides of sterically hindered substrates like stilbene oxides, the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates, overview	Rattus norvegicus	?	-	?
squalene diepoxide + H2O	-	Mus musculus	?	-	?
squalene-2,3-epoxide + H2O	-	Mus musculus	?	-	?

Subunits

Subunits	Comment	Organism
dimer	2 * 62000, about	Cavia porcellus
dimer	2 * 62000, about	Homo sapiens
dimer	2 * 62000, about	Rattus norvegicus
dimer	2 * 62000, about	Sus scrofa
dimer	2 * 62000, about	Oryctolagus cuniculus
dimer	2 * 62000, about	Mesocricetus auratus
dimer	2 * 62000, about	Equus caballus
dimer	2 * 62000, about	Macaca mulatta
dimer	2 * 62000, about	Papio sp.
dimer	2 * 62000, about	Mus musculus
monomer or dimer	n * 35000, about	Solanum tuberosum
monomer or dimer	n * 35000, about	Glycine max
monomer or dimer	n * 35000, about	Arabidopsis thaliana
monomer or dimer	n * 35000, about	Ricinus communis
monomer or dimer	x * 35000, about	Vicia sativa
monomer or dimer	x * 35000, about	Triticum aestivum
monomer or dimer	x * 35000, about	Spinacia oleracea
monomer or dimer	x * 35000, about	Nicotiana tabacum
monomer or dimer	x * 35000, about	Brassica napus
monomer or dimer	x * 35000, about	Apium graveolens
monomer or dimer	x * 35000, about	Oryza sativa
monomer or dimer	x * 35000, about	Ananas comosus
monomer or dimer	x * 35000, about	Euphorbia lagascae
monomer or dimer	x * 35000, about	Citrus jambhiri
monomer or dimer	x * 35000, about	Malus pumila
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Cavia porcellus
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Homo sapiens
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Rattus norvegicus
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Sus scrofa
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Oryctolagus cuniculus
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Mesocricetus auratus
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Equus caballus
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Macaca mulatta
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Papio sp.
More	the C-terminal domain catalyzes epoxy fatty acid hydrolysis, the N-terminal catalytic domain has also phosphatase activity with specificity for fatty acid diol phosphates	Mus musculus

Synonyms

Synonyms	Comment	Organism
EPXH2	-	Homo sapiens
EPXH2B	-	Mus musculus
SEH	-	Vicia sativa
SEH	-	Rattus norvegicus
SEH	-	Triticum aestivum
SEH	-	Spinacia oleracea
SEH	-	Zea mays
SEH	-	Solanum tuberosum
SEH	-	Nicotiana tabacum
SEH	-	Glycine max
SEH	-	Arabidopsis thaliana
SEH	-	Brassica napus
SEH	-	Ricinus communis
SEH	-	Apium graveolens
SEH	-	Oryza sativa
SEH	-	Ananas comosus
SEH	-	Papio sp.
SEH	-	Euphorbia lagascae
SEH	-	Citrus jambhiri
SEH	-	Malus pumila

pI Value

Organism	Comment	pI Value Maximum	pI Value
Cavia porcellus	-	6	5
Rattus norvegicus	-	6	5
Sus scrofa	-	6	5
Oryctolagus cuniculus	-	6	5
Mesocricetus auratus	-	6	5
Equus caballus	-	6	5
Macaca mulatta	-	6	5