Literature summary extracted from

Delgado-Carmona, J.D.; Ramirez-Quijas, M.D.; Vega-Gonzalez, A.; Lopez-Romero, E.; Cuellar-Cruz, M.
Changes in GDPase/UDPase enzymatic activity in response to oxidative stress in four Candida species (2015), Folia Microbiol. (Praha), 60, 343-350 .

Inhibitors

EC Number	Inhibitors	Comment	Organism
3.6.1.6	H2O2	in the presence of H2O2, UDPase activity is lower than that of GDPase. GDPase activity significantly decreases at high concentrations. Inverse relationship between the decline in UDPase activity and the increase in the concentration of H2O2	Candida albicans
3.6.1.6	H2O2	in the presence of H2O2, UDPase activity is lower than that of GDPase. GDPase activity significantly decreases at high concentrations. Inverse relationship between the decline in UDPase activity and the increase in the concentration of H2O2	[Candida] glabrata
3.6.1.6	H2O2	in the presence of H2O2, UDPase activity is lower than that of GDPase. GDPase activity significantly decreases at high concentrations. Inverse relationship between the decline in UDPase activity and the increase in the concentration of H2O2	Candida parapsilosis
3.6.1.6	H2O2	in the presence of H2O2, UDPase activity is lower than that of GDPase. GDPase activity significantly decreases at high concentrations. Inverse relationship between the decline in UDPase activity and the increase in the concentration of H2O2	Pichia kudriavzevii
3.6.1.6	menadione	-	Candida albicans
3.6.1.6	menadione	UDPase activity increases at lower concentrations of the oxidant and decreases at higher concentrations	[Candida] glabrata
3.6.1.6	menadione	UDPase activity increases at lower concentrations of the oxidant and decreases at higher concentrations	Candida parapsilosis
3.6.1.6	menadione	-	Pichia kudriavzevii
3.6.1.6	additional information	GDPase and UDPase activities are generally affected by H2O2 and the superoxide ion generated by menadione	Candida albicans
3.6.1.6	additional information	GDPase and UDPase activities are generally affected by H2O2 and the superoxide ion generated by menadione	[Candida] glabrata
3.6.1.6	additional information	GDPase and UDPase activities are generally affected by H2O2 and the superoxide ion generated by menadione	Candida parapsilosis
3.6.1.6	additional information	GDPase and UDPase activities are generally affected by H2O2 and the superoxide ion generated by menadione	Pichia kudriavzevii
3.6.1.6	superoxide	GDPase activity significantly decreases at high concentrations	Candida albicans
3.6.1.6	superoxide	GDPase activity significantly decreases at high concentrations	[Candida] glabrata
3.6.1.6	superoxide	GDPase activity significantly decreases at high concentrations	Candida parapsilosis
3.6.1.6	superoxide	GDPase activity significantly decreases at high concentrations	Pichia kudriavzevii

Localization

EC Number	Localization	Comment	Organism	GeneOntology No.	Textmining
3.6.1.6	microsome	-	Pichia kudriavzevii	-	-
3.6.1.6	microsome	-	Candida albicans	-	-
3.6.1.6	microsome	-	Candida parapsilosis	-	-
3.6.1.6	microsome	-	[Candida] glabrata	-	-

Metals/Ions

EC Number	Metals/Ions	Comment	Organism
3.6.1.6	Ca2+	required	Pichia kudriavzevii
3.6.1.6	Ca2+	required	Candida albicans
3.6.1.6	Ca2+	required	Candida parapsilosis
3.6.1.6	Ca2+	required	[Candida] glabrata

Natural Substrates/ Products (Substrates)

EC Number	Natural Substrates	Organism	Comment (Nat. Sub.)	Natural Products	Comment (Nat. Pro.)	Rev.
3.6.1.6	GDP + H2O	Pichia kudriavzevii	-	GMP + phosphate	-	?
3.6.1.6	GDP + H2O	Candida albicans	-	GMP + phosphate	-	?
3.6.1.6	GDP + H2O	Candida parapsilosis	-	GMP + phosphate	-	?
3.6.1.6	GDP + H2O	[Candida] glabrata	-	GMP + phosphate	-	?
3.6.1.6	UDP + H2O	Pichia kudriavzevii	-	UMP + phosphate	-	?
3.6.1.6	UDP + H2O	Candida albicans	-	UMP + phosphate	-	?
3.6.1.6	UDP + H2O	Candida parapsilosis	-	UMP + phosphate	-	?
3.6.1.6	UDP + H2O	[Candida] glabrata	-	UMP + phosphate	-	?
3.6.1.42	GDP + H2O	Pichia kudriavzevii	-	GMP + phosphate	-	?
3.6.1.42	GDP + H2O	Candida albicans	-	GMP + phosphate	-	?
3.6.1.42	GDP + H2O	Candida parapsilosis	-	GMP + phosphate	-	?
3.6.1.42	GDP + H2O	[Candida] glabrata	-	GMP + phosphate	-	?

Organism

EC Number	Organism	UniProt	Comment	Textmining
3.6.1.6	Candida albicans	-	clinical isolate from Mexico	-
3.6.1.6	Candida parapsilosis	-	clinical isolate from Mexico	-
3.6.1.6	Pichia kudriavzevii	-	clinical isolate from Mexico	-
3.6.1.6	[Candida] glabrata	-	clinical isolate from Mexico	-
3.6.1.42	Candida albicans	-	-	-
3.6.1.42	Candida parapsilosis	-	-	-
3.6.1.42	Pichia kudriavzevii	-	-	-
3.6.1.42	[Candida] glabrata	-	-	-

Substrates and Products (Substrate)

EC Number	Substrates	Comment Substrates	Organism	Products	Comment (Products)	Rev.
3.6.1.6	GDP + H2O	-	Pichia kudriavzevii	GMP + phosphate	-	?
3.6.1.6	GDP + H2O	-	Candida albicans	GMP + phosphate	-	?
3.6.1.6	GDP + H2O	-	Candida parapsilosis	GMP + phosphate	-	?
3.6.1.6	GDP + H2O	-	[Candida] glabrata	GMP + phosphate	-	?
3.6.1.6	UDP + H2O	-	Pichia kudriavzevii	UMP + phosphate	-	?
3.6.1.6	UDP + H2O	-	Candida albicans	UMP + phosphate	-	?
3.6.1.6	UDP + H2O	-	Candida parapsilosis	UMP + phosphate	-	?
3.6.1.6	UDP + H2O	-	[Candida] glabrata	UMP + phosphate	-	?
3.6.1.42	GDP + H2O	-	Pichia kudriavzevii	GMP + phosphate	-	?
3.6.1.42	GDP + H2O	-	Candida albicans	GMP + phosphate	-	?
3.6.1.42	GDP + H2O	-	Candida parapsilosis	GMP + phosphate	-	?
3.6.1.42	GDP + H2O	-	[Candida] glabrata	GMP + phosphate	-	?

Synonyms

EC Number	Synonyms	Comment	Organism
3.6.1.6	GDPase	-	Pichia kudriavzevii
3.6.1.6	GDPase	-	Candida albicans
3.6.1.6	GDPase	-	Candida parapsilosis
3.6.1.6	GDPase	-	[Candida] glabrata
3.6.1.6	GDPase/UDPase	-	Pichia kudriavzevii
3.6.1.6	GDPase/UDPase	-	Candida albicans
3.6.1.6	GDPase/UDPase	-	Candida parapsilosis
3.6.1.6	GDPase/UDPase	-	[Candida] glabrata
3.6.1.6	NDPase	-	Pichia kudriavzevii
3.6.1.6	NDPase	-	Candida albicans
3.6.1.6	NDPase	-	Candida parapsilosis
3.6.1.6	NDPase	-	[Candida] glabrata
3.6.1.6	UDPase	-	Pichia kudriavzevii
3.6.1.6	UDPase	-	Candida albicans
3.6.1.6	UDPase	-	Candida parapsilosis
3.6.1.6	UDPase	-	[Candida] glabrata
3.6.1.42	GDPase	-	Pichia kudriavzevii
3.6.1.42	GDPase	-	Candida albicans
3.6.1.42	GDPase	-	Candida parapsilosis
3.6.1.42	GDPase	-	[Candida] glabrata

Temperature Optimum [°C]

EC Number	Temperature Optimum [°C]	Temperature Optimum Maximum [°C]	Comment	Organism
3.6.1.6	37	-	assay at	Pichia kudriavzevii
3.6.1.6	37	-	assay at	Candida albicans
3.6.1.6	37	-	assay at	Candida parapsilosis
3.6.1.6	37	-	assay at	[Candida] glabrata

pH Optimum

EC Number	pH Optimum Minimum	pH Optimum Maximum	Comment	Organism
3.6.1.6	7.5	-	assay at	Pichia kudriavzevii
3.6.1.6	7.5	-	assay at	Candida albicans
3.6.1.6	7.5	-	assay at	Candida parapsilosis
3.6.1.6	7.5	-	assay at	[Candida] glabrata

Expression

EC Number	Organism	Comment	Expression
3.6.1.42	Pichia kudriavzevii	the enzyme activity significantly decreases at high concentrations of menadione, H2O2 and O2-	down
3.6.1.42	Candida albicans	the enzyme activity significantly decreases at high concentrations of menadione, H2O2 and O2-	down
3.6.1.42	Candida parapsilosis	the enzyme activity significantly decreases at high concentrations of menadione, H2O2 and O2-	down
3.6.1.42	[Candida] glabrata	the enzyme activity significantly decreases at high concentrations of menadione, H2O2 and O2-	down

General Information

EC Number	General Information	Comment	Organism
3.6.1.6	metabolism	the organism shows a basic mechanism to cope with oxidative stress, suggesting that the pathogen might activate mechanisms for UDPase synthesis at lower concentrations of superoxide. Differential response to oxidative stress by different Candida species, overview	Pichia kudriavzevii
3.6.1.6	metabolism	the organism shows a basic mechanism to cope with oxidative stress, suggesting that the pathogen might activate mechanisms for UDPase synthesis at lower concentrations of superoxide. Differential response to oxidative stress by different Candida species, overview	Candida albicans
3.6.1.6	metabolism	the organism shows a basic mechanism to cope with oxidative stress, suggesting that the pathogen might activate mechanisms for UDPase synthesis at lower concentrations of superoxide. Differential response to oxidative stress by different Candida species, overview	Candida parapsilosis
3.6.1.6	metabolism	the organism shows a basic mechanism to cope with oxidative stress, suggesting that the pathogen might activate mechanisms for UDPase synthesis at lower concentrations of superoxide. Differential response to oxidative stress by different Candida species, overview	[Candida] glabrata
3.6.1.6	physiological function	the terminal processing of proteins and lipids occurs in the Golgi apparatus and involves the transport of sugar nucleotides into the Golgi lumen by specific carriers and the accumulation of nucleoside diphosphates (NDPs) as a result of oligosaccharide-protein glycosyltransferase activity. NDPs are converted into the corresponding nucleoside monophosphates (NMPs) by nucleoside diphosphatases (NDPases), thus relieving inhibition of sugar transferases. NMPs are then exchanged for equimolecular amounts of cytosolic sugar nucleotides by antiport transport systems. NDPases, commonly GDPase and UDPase, thus play a critical role in glycoprotein maturation and may influence fungal pathogenesis, morphogenesis, and cell wall properties	Pichia kudriavzevii
3.6.1.6	physiological function	the terminal processing of proteins and lipids occurs in the Golgi apparatus and involves the transport of sugar nucleotides into the Golgi lumen by specific carriers and the accumulation of nucleoside diphosphates (NDPs) as a result of oligosaccharide-protein glycosyltransferase activity. NDPs are converted into the corresponding nucleoside monophosphates (NMPs) by nucleoside diphosphatases (NDPases), thus relieving inhibition of sugar transferases. NMPs are then exchanged for equimolecular amounts of cytosolic sugar nucleotides by antiport transport systems. NDPases, commonly GDPase and UDPase, thus play a critical role in glycoprotein maturation and may influence fungal pathogenesis, morphogenesis, and cell wall properties	Candida albicans
3.6.1.6	physiological function	the terminal processing of proteins and lipids occurs in the Golgi apparatus and involves the transport of sugar nucleotides into the Golgi lumen by specific carriers and the accumulation of nucleoside diphosphates (NDPs) as a result of oligosaccharide-protein glycosyltransferase activity. NDPs are converted into the corresponding nucleoside monophosphates (NMPs) by nucleoside diphosphatases (NDPases), thus relieving inhibition of sugar transferases. NMPs are then exchanged for equimolecular amounts of cytosolic sugar nucleotides by antiport transport systems. NDPases, commonly GDPase and UDPase, thus play a critical role in glycoprotein maturation and may influence fungal pathogenesis, morphogenesis, and cell wall properties	Candida parapsilosis
3.6.1.6	physiological function	the terminal processing of proteins and lipids occurs in the Golgi apparatus and involves the transport of sugar nucleotides into the Golgi lumen by specific carriers and the accumulation of nucleoside diphosphates (NDPs) as a result of oligosaccharide-protein glycosyltransferase activity. NDPs are converted into the corresponding nucleoside monophosphates (NMPs) by nucleoside diphosphatases (NDPases), thus relieving inhibition of sugar transferases. NMPs are then exchanged for equimolecular amounts of cytosolic sugar nucleotides by antiport transport systems. NDPases, commonly GDPase and UDPase, thus play a critical role in glycoprotein maturation and may influence fungal pathogenesis, morphogenesis, and cell wall properties	[Candida] glabrata