Literature summary extracted from

Wang, C.H.; Zhang, C.; Xing, X.H.
Xanthine dehydrogenase an old enzyme with new knowledge and prospects (2016), Bioengineered, 7, 395-405 .

Application

EC Number	Application	Comment	Organism
1.17.1.4	biotechnology	the enzyme can be useful in biotechnlogical applications requiring special conditions, e.g. extreme pH values	Acinetobacter baumannii
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Gallus gallus
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Drosophila melanogaster
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Homo sapiens
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Rattus norvegicus
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Bos taurus
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Ovis aries
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Enterobacter cloacae
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Pseudomonas putida
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Rhodobacter capsulatus
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Clostridium cylindrosporum
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Micrococcus sp.
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Acinetobacter baumannii
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Streptomyces cyanogenus
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Arabidopsis thaliana
1.17.1.4	environmental protection	XDHs can find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin	Arthrobacter luteolus

Cloned(Commentary)

EC Number	Cloned (Comment)	Organism
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Gallus gallus
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Drosophila melanogaster
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Homo sapiens
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Bos taurus
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Ovis aries
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Enterobacter cloacae
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Pseudomonas putida
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Clostridium cylindrosporum
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Micrococcus sp.
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Streptomyces cyanogenus
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis	Arthrobacter luteolus
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis, recombinant expression in Escherichia coli	Rhodobacter capsulatus
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis, recombinant expression in Escherichia coli	Acinetobacter baumannii
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis, recombinant expression in Escherichia coli	Escherichia coli
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis, recombinant expression in Pichia pastoris	Arabidopsis thaliana
1.17.1.4	gene xdh, sequence comparisons and phylogenetic analysis, recombinant expression of liver XDH in insect cell system	Rattus norvegicus

Crystallization (Commentary)

EC Number	Crystallization (Comment)	Organism
1.17.1.4	crystal structure determination	Homo sapiens
1.17.1.4	crystal structure determination	Rattus norvegicus
1.17.1.4	crystal structure determination	Bos taurus
1.17.1.4	crystal structure determination	Rhodobacter capsulatus

Localization

EC Number	Localization	Comment	Organism	GeneOntology No.	Textmining
1.17.1.4	extracellular	-	Bos taurus	-	-

Metals/Ions

EC Number	Metals/Ions	Comment	Organism
1.17.1.4	Fe2+	in the [2Fe-2S] center	Gallus gallus
1.17.1.4	Fe2+	in the [2Fe-2S] center	Drosophila melanogaster
1.17.1.4	Fe2+	in the [2Fe-2S] center	Homo sapiens
1.17.1.4	Fe2+	in the [2Fe-2S] center	Rattus norvegicus
1.17.1.4	Fe2+	in the [2Fe-2S] center	Bos taurus
1.17.1.4	Fe2+	in the [2Fe-2S] center	Ovis aries
1.17.1.4	Fe2+	in the [2Fe-2S] center	Enterobacter cloacae
1.17.1.4	Fe2+	in the [2Fe-2S] center	Pseudomonas putida
1.17.1.4	Fe2+	in the [2Fe-2S] center	Rhodobacter capsulatus
1.17.1.4	Fe2+	in the [2Fe-2S] center	Clostridium cylindrosporum
1.17.1.4	Fe2+	in the [2Fe-2S] center	Micrococcus sp.
1.17.1.4	Fe2+	in the [2Fe-2S] center	Acinetobacter baumannii
1.17.1.4	Fe2+	in the [2Fe-2S] center	Streptomyces cyanogenus
1.17.1.4	Fe2+	in the [2Fe-2S] center	Arabidopsis thaliana
1.17.1.4	Fe2+	in the [2Fe-2S] center	Escherichia coli
1.17.1.4	Fe2+	in the [2Fe-2S] center	Acinetobacter phage Ab105-3phi
1.17.1.4	Fe2+	in the [2Fe-2S] center	Arthrobacter luteolus
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Gallus gallus
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Drosophila melanogaster
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Homo sapiens
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Rattus norvegicus
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Bos taurus
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Ovis aries
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Enterobacter cloacae
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Pseudomonas putida
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Rhodobacter capsulatus
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Clostridium cylindrosporum
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Micrococcus sp.
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Acinetobacter baumannii
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Streptomyces cyanogenus
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Escherichia coli
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Acinetobacter phage Ab105-3phi
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein	Arthrobacter luteolus
1.17.1.4	Molybdenum	a molybdenum-containing flavoprotein, biosynthesis of sulfurated molybdenum cofactor, overview	Arabidopsis thaliana

Molecular Weight [Da]

EC Number	Molecular Weight [Da]	Molecular Weight Maximum [Da]	Comment	Organism
1.17.1.4	128000	-	-	Enterobacter cloacae
1.17.1.4	160000	-	-	Escherichia coli
1.17.1.4	160000	-	-	Arthrobacter luteolus
1.17.1.4	270000	-	-	Rhodobacter capsulatus
1.17.1.4	290000	-	-	Bos taurus
1.17.1.4	290000	-	-	Acinetobacter baumannii

Natural Substrates/ Products (Substrates)

EC Number	Natural Substrates	Organism	Comment (Nat. Sub.)	Natural Products	Comment (Nat. Pro.)	Rev.
1.17.1.4	xanthine + NAD+ + H2O	Gallus gallus	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Drosophila melanogaster	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Homo sapiens	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Rattus norvegicus	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Bos taurus	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Ovis aries	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Enterobacter cloacae	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Pseudomonas putida	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Rhodobacter capsulatus	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Clostridium cylindrosporum	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Micrococcus sp.	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Acinetobacter baumannii	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Streptomyces cyanogenus	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Arabidopsis thaliana	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Escherichia coli	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Acinetobacter phage Ab105-3phi	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Arthrobacter luteolus	-	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	Rhodobacter capsulatus B10XDHB	-	urate + NADH + H+	-	?

Organism

EC Number	Organism	UniProt	Comment	Textmining
1.17.1.4	Acinetobacter baumannii	-	-	-
1.17.1.4	Acinetobacter phage Ab105-3phi	-	-	-
1.17.1.4	Arabidopsis thaliana	Q8GUQ8	-	-
1.17.1.4	Arthrobacter luteolus	-	-	-
1.17.1.4	Bos taurus	-	-	-
1.17.1.4	Clostridium cylindrosporum	-	-	-
1.17.1.4	Drosophila melanogaster	-	-	-
1.17.1.4	Enterobacter cloacae	-	-	-
1.17.1.4	Escherichia coli	Q46799 AND Q46800	subunits encoding genes xdhA and xdhB	-
1.17.1.4	Gallus gallus	-	-	-
1.17.1.4	Homo sapiens	-	-	-
1.17.1.4	Micrococcus sp.	-	-	-
1.17.1.4	Ovis aries	-	-	-
1.17.1.4	Pseudomonas putida	-	-	-
1.17.1.4	Rattus norvegicus	-	-	-
1.17.1.4	Rhodobacter capsulatus	-	-	-
1.17.1.4	Rhodobacter capsulatus B10XDHB	-	-	-
1.17.1.4	Streptomyces cyanogenus	-	-	-

Purification (Commentary)

EC Number	Purification (Comment)	Organism
1.17.1.4	native enzyme	Enterobacter cloacae
1.17.1.4	purification of native enzyme	Arthrobacter luteolus
1.17.1.4	purification of native XDH	Gallus gallus
1.17.1.4	purification of native XDH	Drosophila melanogaster
1.17.1.4	purification of native XDH	Homo sapiens
1.17.1.4	purification of native XDH	Rattus norvegicus
1.17.1.4	purification of native XDH	Ovis aries
1.17.1.4	purification of native XDH	Rhodobacter capsulatus
1.17.1.4	purification of native XDH	Clostridium cylindrosporum
1.17.1.4	purification of native XDH	Micrococcus sp.
1.17.1.4	purification of native XDH	Streptomyces cyanogenus

Source Tissue

EC Number	Source Tissue	Comment	Organism	Textmining
1.17.1.4	liver	-	Rattus norvegicus	-
1.17.1.4	milk	-	Bos taurus	-

Specific Activity [micromol/min/mg]

EC Number	Specific Activity Minimum [µmol/min/mg]	Specific Activity Maximum [µmol/min/mg]	Comment	Organism
1.17.1.4	1.8	-	purified native enzyme, pH and temperature not specified in the publication	Bos taurus
1.17.1.4	7	-	purified recombinant enzyme, pH and temperature not specified in the publication	Escherichia coli
1.17.1.4	7.5	-	purified native enzyme, pH and temperature not specified in the publication	Enterobacter cloacae
1.17.1.4	10	-	purified native enzyme, pH and temperature not specified in the publication	Arthrobacter luteolus
1.17.1.4	17.5	-	purified enzyme, pH and temperature not specified in the publication	Rhodobacter capsulatus
1.17.1.4	29.1	-	purified recombinant enzyme, pH and temperature not specified in the publication	Acinetobacter baumannii

Substrates and Products (Substrate)

EC Number	Substrates	Comment Substrates	Organism	Products	Comment (Products)	Rev.
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Gallus gallus	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Drosophila melanogaster	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Homo sapiens	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Rattus norvegicus	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Bos taurus	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Ovis aries	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Enterobacter cloacae	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Pseudomonas putida	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Rhodobacter capsulatus	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Clostridium cylindrosporum	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Micrococcus sp.	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Acinetobacter baumannii	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Streptomyces cyanogenus	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Arabidopsis thaliana	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Escherichia coli	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Acinetobacter phage Ab105-3phi	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Arthrobacter luteolus	?	-	?
1.17.1.4	additional information	The enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD+ or NADP+ as electron acceptor, and in some species can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor	Rhodobacter capsulatus B10XDHB	?	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Gallus gallus	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Drosophila melanogaster	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Homo sapiens	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Rattus norvegicus	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Bos taurus	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Ovis aries	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Enterobacter cloacae	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Pseudomonas putida	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Rhodobacter capsulatus	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Clostridium cylindrosporum	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Micrococcus sp.	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Acinetobacter baumannii	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Streptomyces cyanogenus	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Arabidopsis thaliana	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Escherichia coli	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Acinetobacter phage Ab105-3phi	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Arthrobacter luteolus	urate + NADH + H+	-	?
1.17.1.4	xanthine + NAD+ + H2O	-	Rhodobacter capsulatus B10XDHB	urate + NADH + H+	-	?

Subunits

EC Number	Subunits	Comment	Organism
1.17.1.4	homodimer	2 * 69000	Enterobacter cloacae
1.17.1.4	homodimer	2 * 145000, the enzyme exists as (alpha)2 form	Bos taurus
1.17.1.4	homodimer	2 * 80000, (alpha)2	Arthrobacter luteolus
1.17.1.4	homodimer	the enzyme exists as (alpha)2 form	Gallus gallus
1.17.1.4	homodimer	the enzyme exists as (alpha)2 form	Rattus norvegicus
1.17.1.4	homodimer	the enzyme exists as (alpha)2 form	Arabidopsis thaliana
1.17.1.4	More	bacterial XDHs, including Rhodobacter capsulatus, Pseudomonas putida and Streptomyces cyanogenus, are found in the alpha2, alpha4, (alphabeta)2, (alphabeta)4 and alphabetagamma forms	Rhodobacter capsulatus
1.17.1.4	More	bacterial XDHs, including Rhodobacter capsulatus, Pseudomonas putida and Streptomyces cyanogenus, are found in the alpha2, alpha4, (alphabeta)2, (alphabeta)4, and alphabetagamma forms	Pseudomonas putida
1.17.1.4	More	bacterial XDHs, including Rhodobacter capsulatus, Pseudomonas putida and Streptomyces cyanogenus, are found in the alpha2, alpha4, (alphabeta)2, (alphabeta)4, and alphabetagamma forms	Streptomyces cyanogenus
1.17.1.4	tetramer	2 * 50000, alpha-subunit, + 2 * 80000, beta-subunit, alpha2beta2	Rhodobacter capsulatus
1.17.1.4	tetramer	2 * 87000, alpha-subunit, + 2 * 56000, beta-subunit, alpha2beta2	Acinetobacter baumannii

Synonyms

EC Number	Synonyms	Comment	Organism
1.17.1.4	XDH	-	Gallus gallus
1.17.1.4	XDH	-	Drosophila melanogaster
1.17.1.4	XDH	-	Homo sapiens
1.17.1.4	XDH	-	Rattus norvegicus
1.17.1.4	XDH	-	Bos taurus
1.17.1.4	XDH	-	Ovis aries
1.17.1.4	XDH	-	Enterobacter cloacae
1.17.1.4	XDH	-	Pseudomonas putida
1.17.1.4	XDH	-	Rhodobacter capsulatus
1.17.1.4	XDH	-	Clostridium cylindrosporum
1.17.1.4	XDH	-	Micrococcus sp.
1.17.1.4	XDH	-	Acinetobacter baumannii
1.17.1.4	XDH	-	Streptomyces cyanogenus
1.17.1.4	XDH	-	Arabidopsis thaliana
1.17.1.4	XDH	-	Escherichia coli
1.17.1.4	XDH	-	Acinetobacter phage Ab105-3phi
1.17.1.4	XDH	-	Arthrobacter luteolus
1.17.1.4	XDH1	-	Arabidopsis thaliana

Temperature Optimum [°C]

EC Number	Temperature Optimum [°C]	Temperature Optimum Maximum [°C]	Comment	Organism
1.17.1.4	25	35	-	Bos taurus
1.17.1.4	35	40	-	Rhodobacter capsulatus
1.17.1.4	35	45	-	Enterobacter cloacae
1.17.1.4	55	60	-	Arthrobacter luteolus
1.17.1.4	65	-	-	Escherichia coli

Turnover Number [1/s]

EC Number	Turnover Number Minimum [1/s]	Turnover Number Maximum [1/s]	Substrate	Comment	Organism	Structure
1.17.1.4	25	-	xanthine	pH and temperature not specified in the publication	Acinetobacter baumannii

pH Optimum

EC Number	pH Optimum Minimum	pH Optimum Maximum	Comment	Organism
1.17.1.4	6.5	7.5	-	Enterobacter cloacae
1.17.1.4	7.5	8.5	-	Rhodobacter capsulatus
1.17.1.4	7.5	8	-	Escherichia coli
1.17.1.4	7.5	8	-	Arthrobacter luteolus
1.17.1.4	8.5	-	-	Bos taurus
1.17.1.4	8.5	9	-	Acinetobacter baumannii

pH Range

EC Number	pH Minimum	pH Maximum	Comment	Organism
1.17.1.4	additional information	-	Acinetobacter baumannii XDH extends the pH tolerance to pH 11.0	Acinetobacter baumannii

Cofactor

EC Number	Cofactor	Comment	Organism
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Gallus gallus
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Drosophila melanogaster
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Homo sapiens
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Rattus norvegicus
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Bos taurus
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Ovis aries
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Enterobacter cloacae
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Pseudomonas putida
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Rhodobacter capsulatus
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Clostridium cylindrosporum
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Micrococcus sp.
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Acinetobacter baumannii
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Streptomyces cyanogenus
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Arabidopsis thaliana
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Escherichia coli
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Acinetobacter phage Ab105-3phi
1.17.1.4	FAD	a molybdenum-containing flavoprotein	Arthrobacter luteolus
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Gallus gallus
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Drosophila melanogaster
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Homo sapiens
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Rattus norvegicus
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Bos taurus
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Ovis aries
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Enterobacter cloacae
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Pseudomonas putida
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Rhodobacter capsulatus
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Clostridium cylindrosporum
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Micrococcus sp.
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Acinetobacter baumannii
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Streptomyces cyanogenus
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Arabidopsis thaliana
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Acinetobacter phage Ab105-3phi
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein	Arthrobacter luteolus
1.17.1.4	molybdenum cofactor	a molybdenum-containing flavoprotein, biosynthesis of sulfurated molybdenum cofactor, overview	Escherichia coli
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview	Acinetobacter phage Ab105-3phi
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview	Arthrobacter luteolus
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Enterobacter cloacae
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Gallus gallus
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Drosophila melanogaster
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Homo sapiens
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Rattus norvegicus
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Bos taurus
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Ovis aries
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Pseudomonas putida
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Clostridium cylindrosporum
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Micrococcus sp.
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Acinetobacter baumannii
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Streptomyces cyanogenus
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Arabidopsis thaliana
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species	Escherichia coli
1.17.1.4	additional information	cofactor domain amino acid sequence comparisons, overview. XDH consists of 3 redox center domains, XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S]), another that includes a flavin adenine dinucleotide (FAD), and a third that incorporates a sulfurated molybdenum cofactor (Moco). The [2Fe-2S] domain is more conserved than the Moco domain, and the FAD domain is the least conserved one between different species. Rhodobacter capsulatus alpha2beta2 XDH arranges the FAD and [2Fe-2S] domains and the Moco domain into 2 separate subunits	Rhodobacter capsulatus
1.17.1.4	NAD+	-	Gallus gallus
1.17.1.4	NAD+	-	Drosophila melanogaster
1.17.1.4	NAD+	-	Homo sapiens
1.17.1.4	NAD+	-	Rattus norvegicus
1.17.1.4	NAD+	-	Bos taurus
1.17.1.4	NAD+	-	Ovis aries
1.17.1.4	NAD+	-	Enterobacter cloacae
1.17.1.4	NAD+	-	Pseudomonas putida
1.17.1.4	NAD+	-	Rhodobacter capsulatus
1.17.1.4	NAD+	-	Clostridium cylindrosporum
1.17.1.4	NAD+	-	Micrococcus sp.
1.17.1.4	NAD+	-	Acinetobacter baumannii
1.17.1.4	NAD+	-	Streptomyces cyanogenus
1.17.1.4	NAD+	-	Arabidopsis thaliana
1.17.1.4	NAD+	-	Escherichia coli
1.17.1.4	NAD+	-	Acinetobacter phage Ab105-3phi
1.17.1.4	NAD+	-	Arthrobacter luteolus
1.17.1.4	[2Fe-2S]-center	-	Acinetobacter phage Ab105-3phi
1.17.1.4	[2Fe-2S]-center	-	Arthrobacter luteolus
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Gallus gallus
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Drosophila melanogaster
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Homo sapiens
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Rattus norvegicus
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Bos taurus
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Ovis aries
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Enterobacter cloacae
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Pseudomonas putida
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Rhodobacter capsulatus
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Clostridium cylindrosporum
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Micrococcus sp.
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Acinetobacter baumannii
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Streptomyces cyanogenus
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Arabidopsis thaliana
1.17.1.4	[2Fe-2S]-center	XDH consists of 3 redox center domains, one of which contains 2 distinct iron-sulfur clusters ([2Fe-2S])	Escherichia coli

General Information

EC Number	General Information	Comment	Organism
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Gallus gallus
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Drosophila melanogaster
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Homo sapiens
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Rattus norvegicus
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Bos taurus
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Ovis aries
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Enterobacter cloacae
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Pseudomonas putida
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Rhodobacter capsulatus
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Clostridium cylindrosporum
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Micrococcus sp.
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Streptomyces cyanogenus
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Arabidopsis thaliana
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Escherichia coli
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis	Arthrobacter luteolus
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis. The page XDH sequence shows 100% identity to the genomic XDH genes of Acinetobacter baumannii. It seems plausible that the similarity is a result of horizontal gene transfer	Acinetobacter phage Ab105-3phi
1.17.1.4	evolution	XDHs are widely distributed in all eukarya, bacteria and archaea domains, phylogenetic analysis. The unique industrially applicable Acinetobacter baumannii XDH shows only modest similarity to all the previous already-characterized XDHs	Acinetobacter baumannii
1.17.1.4	additional information	Glu802 binds the substrate and stabilizes the transition state, Glu1261 is the catalytic base, Arg880 and Thr1010 bind the substrate and decrease the reaction activation energy, Phe914 and Phe1009 orientate the substrate via pi-pi stacking, Val1011 is the key residue channeling the substrate, and Gln758 is responsible for releasing the product. There is an obvious variation of key residues channeling the substrate and binding pocket, which affect the substrate entry and product release, resulting in different catalytic activity and enzymatic properties. Surprisingly, the 2 pairs of cysteines, C535 and C992, and C1316 and C1324 numbering in bovine XDH, which are proposed to control the reversible post-translational conversion from XDH to XOD, EC 1.17.3.2, by forming 2 cysteine disulfide bonds, are totally absent in other XDHs. Bovine milk XDH can be converted reversibly into active XOD form by forming disulfide bond or irreversibly by limited proteolysis, overview	Bos taurus
1.17.1.4	additional information	rat liver XDH can be converted reversibly into active XOD form by forming disulfide bond or irreversibly by limited proteolysis, overview	Rattus norvegicus
1.17.1.4	additional information	the Arabidopsis thaliana XDH cannot be converted to oxidase form by neither proteolytic cleavage nor oxidation of specific cysteine residues	Arabidopsis thaliana
1.17.1.4	additional information	the chicken XDH cannot be converted to oxidase form by neither proteolytic cleavage nor oxidation of specific cysteine residues	Gallus gallus
1.17.1.4	additional information	the Rhodobacter capsulatus XDH cannot be converted to oxidase form by neither proteolytic cleavage nor oxidation of specific cysteine residues	Rhodobacter capsulatus
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Gallus gallus
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Drosophila melanogaster
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Homo sapiens
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Rattus norvegicus
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Bos taurus
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Ovis aries
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Acinetobacter baumannii
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Arabidopsis thaliana
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Acinetobacter phage Ab105-3phi
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts	Arthrobacter luteolus
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts. Physiological roles and applications of bacterial XDHs, overview	Enterobacter cloacae
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts. Physiological roles and applications of bacterial XDHs, overview	Pseudomonas putida
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts. Physiological roles and applications of bacterial XDHs, overview	Rhodobacter capsulatus
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts. Physiological roles and applications of bacterial XDHs, overview	Clostridium cylindrosporum
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts. Physiological roles and applications of bacterial XDHs, overview	Micrococcus sp.
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts. Physiological roles and applications of bacterial XDHs, overview	Streptomyces cyanogenus
1.17.1.4	physiological function	XDHs play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts. Physiological roles and applications of bacterial XDHs, overview	Escherichia coli

kcat/KM [mM/s]

EC Number	kcat/KM Value [1/mMs^-1]	kcat/KM Value Maximum [1/mMs^-1]	Substrate	Comment	Organism	Structure
1.17.1.4	2740	-	xanthine	pH and temperature not specified in the publication	Acinetobacter baumannii