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PW685875

Pw685875 View Pathway
metabolic

Uracil Degradation III

Bacteroides eggerthii 1_2_48FAA
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: January 31, 2025 at 13:32

Last Updated: January 31, 2025 at 13:32

PW685980

Pw685980 View Pathway
metabolic

Uracil Degradation III

Morganella morganii subsp. morganii KT
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: February 01, 2025 at 05:47

Last Updated: February 01, 2025 at 05:47

PW490105

Pw490105 View Pathway
metabolic

Uracil Degradation III

Salmonella paratyphi B (strain ATCC BAA-1250 / SPB7)
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: January 31, 2025 at 09:01

Last Updated: January 31, 2025 at 09:01

PW685868

Pw685868 View Pathway
metabolic

Uracil Degradation III

Achromobacter xylosoxidans A8
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: January 31, 2025 at 01:05

Last Updated: January 31, 2025 at 01:05

PW685874

Pw685874 View Pathway
metabolic

Uracil Degradation III

Acinetobacter calcoaceticus PHEA-2
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: January 31, 2025 at 09:24

Last Updated: January 31, 2025 at 09:24

PW491341

Pw491341 View Pathway
metabolic

Uracil Degradation III

Prevotella pallens ATCC 700821
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: January 31, 2025 at 19:15

Last Updated: January 31, 2025 at 19:15

PW686002

Pw686002 View Pathway
metabolic

Uracil Degradation III

Yersinia bercovieri ATCC 43970
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: February 01, 2025 at 07:02

Last Updated: February 01, 2025 at 07:02

PW685879

Pw685879 View Pathway
metabolic

Uracil Degradation III

Bacteroides fluxus YIT 12057
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: January 31, 2025 at 13:57

Last Updated: January 31, 2025 at 13:57

PW685933

Pw685933 View Pathway
metabolic

Uracil Degradation III

Lautropia mirabilis ATCC 51599
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: February 01, 2025 at 00:12

Last Updated: February 01, 2025 at 00:12

PW492303

Pw492303 View Pathway
metabolic

Uracil Degradation III

Enterobacter cancerogenus ATCC 35316
Uracil is a pyrimidine nucleobase found in RNA, and can be used as a source of nitrogen for E. coli. There are at least three pathways through which uracil is degraded. This one begins with uracil, which originates from purine degradation. The putative monooxygenase enzyme rutA catalyzes the breakdown of uracil into peroxyaminoacrylate, using FMNH2 as a cofactor. Peroxyaminoacrylate is then broken down into both carbamic acid and 3-aminoacrylate following the addition of a water molecule by the putative isochorismatase family protein rutB. Carbamic acid can then spontaneously, with the addition of a hydrogen ion, split into an ammonium ion and a molecule of carbon dioxide. 3-aminoacrylate, on the other hand, is catalyzed by the UPF0076 protein rutC to form 2-aminoacrylic acid. This compound enters into a reaction catalyzed by protein rutD, which adds a water molecule and hydrogen ion and forms malonic semialdehyde with ammonium being a byproduct. Finally, the putative NADH dehydrogenase/NAD(P)H nitroreductase rutE complex converts malonic semialdehyde into hydroxypropionic acid, which is then used to form other necessary chemicals. The ammonium ions produced will be the important source of nitrogen for the bacteria.
BioPAX SVG SBGN SBML PWML All files (.zip)

Creator: Julia Wakoli

Created On: February 01, 2025 at 04:18

Last Updated: February 01, 2025 at 04:18