| PathWhiz ID | Pathway | Meta Data |
|---|---|---|
PW500925
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Allantoin Degradation (Anaerobic)Campylobacter showae CSUNSWCD
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 05, 2025 at 08:43 Last Updated: February 05, 2025 at 08:43 |
PW686205
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Allantoin Degradation (Anaerobic)Providencia rustigianii DSM 4541
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 05, 2025 at 13:59 Last Updated: February 05, 2025 at 13:59 |
PW686204
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Allantoin Degradation (Anaerobic)Providencia alcalifaciens DSM 30120
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 05, 2025 at 13:29 Last Updated: February 05, 2025 at 13:29 |
PW686055
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Allantoin Degradation (Anaerobic)Escherichia coli (strain UTI89 / UPEC)
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 03, 2025 at 13:05 Last Updated: February 03, 2025 at 13:05 |
PW499146
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Allantoin Degradation (Anaerobic)Bacteroides sp. 1_1_14
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 04, 2025 at 17:40 Last Updated: February 04, 2025 at 17:40 |
PW500777
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Allantoin Degradation (Anaerobic)Neisseria subflava NJ9703
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 05, 2025 at 07:14 Last Updated: February 05, 2025 at 07:14 |
PW500133
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Allantoin Degradation (Anaerobic)Parabacteroides sp. 20_3
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 05, 2025 at 00:32 Last Updated: February 05, 2025 at 00:32 |
PW501321
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Allantoin Degradation (Anaerobic)Tatumella ptyseos ATCC 33301
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 05, 2025 at 12:54 Last Updated: February 05, 2025 at 12:54 |
PW499057
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Allantoin Degradation (Anaerobic)Bacteroides xylanisolvens SD CC 1b
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 04, 2025 at 17:09 Last Updated: February 04, 2025 at 17:09 |
PW499052
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Allantoin Degradation (Anaerobic)Bacteroides xylanisolvens SD CC 2a
Allantoin can be degraded in anaerobic conditions. The first step involves allantoin being degraded by an allantoinase resulting in an allantoate. This compound in turn is metabolized by reacting with water and 2 hydrogen ions through an allantoate amidohydrolase resulting in the release of a carbon dioxide, ammonium and an S-ureidoglycine. The latter compund is further degrades through a S-ureidoglycine aminohydrolase resulting in the release of an ammonium and an S-ureidoglycolate.
S-ureidoglycolate can be metabolized into oxalurate by two different reactions. The first reactions involves a NAD driven ureidoglycolate dehydrogenase resulting in the release of a hydrogen ion , an NADH and a oxalurate. On the other hand S-ureidoglycolate can react with NADP resulting in the release of an NADPH, a hydroge ion and an oxalurate.
It is hypothesized that oxalurate can interact with a phosphate and release a a carbamoyl phosphate and an oxamate.
The carbamoyl phosphate can be further degraded by reacting with an ADP, and a hydrogen ion through a carbamate kinase resulting in the release of an ammonium , ATP and carbon dioxide
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Creator: Julia Wakoli Created On: February 04, 2025 at 17:07 Last Updated: February 04, 2025 at 17:07 |