3.5.1.3: omega-amidase
This is an abbreviated version!
For detailed information about omega-amidase, go to the full flat file.
Word Map on EC 3.5.1.3
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3.5.1.3
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alpha-ketoglutaramate
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asparagine
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transamination
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ammonia
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oxaloacetate
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succinamate
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glutaminase
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transamidase
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analysis
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medicine
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biotechnology
- 3.5.1.3
- alpha-ketoglutaramate
- asparagine
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transamination
- ammonia
- oxaloacetate
- succinamate
- glutaminase
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transamidase
- analysis
- medicine
- biotechnology
Reaction
Synonyms
alpha-keto acid omega-amidase, alpha-keto acid-omega-amidase, amidase, omega, dicarboxylate omega-amidase, NIT2, Nit2/omega-amidase, nitrilase-like protein 2, omega-amidase, omega-amidase/Nit2, omega-amido dicarboxylate amidohydrolase, omega-amidodicarboxylate amidohydrolase
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General Information
General Information on EC 3.5.1.3 - omega-amidase
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metabolism
physiological function
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the omega-amidase is involved in the nicotine catabolism, and encoded in organized clusters of homologous genes for nicotine catabolism. The omega-amidase, together with glutamate dehydrogenase, may form a physiologically relevant enzyme couple, leading to transformation of metabolically inert alpha-oxoglutaramate derived from trihydroxypyridine into glutamate, a central compound of nitrogen metabolism
metabolism
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the omega-amidase is involved in the nicotine catabolism, and encoded in organized clusters of homologous genes for nicotine catabolism. The omega-amidase, together with glutamate dehydrogenase, may form a physiologically relevant enzyme couple, leading to transformation of metabolically inert alpha-oxoglutaramate derived from trihydroxypyridine into glutamate, a central compound of nitrogen metabolism
metabolism
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the omega-amidase is involved in the nicotine catabolism, and encoded in organized clusters of homologous genes for nicotine catabolism. The omega-amidase, together with glutamate dehydrogenase, may form a physiologically relevant enzyme couple, leading to transformation of metabolically inert alpha-oxoglutaramate derived from trihydroxypyridine into glutamate, a central compound of nitrogen metabolism
metabolism
omega-amidase is involved in the metabolism of asparagine, and probably is also closely coupled with glutamine transamination in the methionine salvage cycle
metabolism
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glutamine transaminase and omega-amidase potentially act in tandem to close the methionine salvage cycle in bacteria and plants
metabolism
glutamine transaminase and omega-amidase potentially act in tandem to close the methionine salvage cycle in bacteria and plants
metabolism
the enzyme may be regarded as a repair enzyme for salvaging L-2-hydroxysuccinamate (as L-malate), and, working in conjunction with L-2-hydroxyglutarate dehydrogenase, for salvaging L-2-hydroxyglutaramate (as 2-oxoglutarate)
metabolism
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omega-amidase is involved in the metabolism of asparagine, and probably is also closely coupled with glutamine transamination in the methionine salvage cycle
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metabolism
Nocardioides sp. JS614 / ATCC BAA-499
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the omega-amidase is involved in the nicotine catabolism, and encoded in organized clusters of homologous genes for nicotine catabolism. The omega-amidase, together with glutamate dehydrogenase, may form a physiologically relevant enzyme couple, leading to transformation of metabolically inert alpha-oxoglutaramate derived from trihydroxypyridine into glutamate, a central compound of nitrogen metabolism
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omega-amidase plays an important role in removing potentially toxic intermediates by converting 2-oxoglutaramate and 2-oxosuccinamate to biologically useful 2-oxoglutarate and oxaloacetate, respectively. It is also important in nitrogen and sulfur metabolism
physiological function
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the omega-amidase, together with glutamate dehydrogenase, may form a physiologically relevant enzyme couple, leading to transformation of metabolically inert alpha-oxoglutaramate derived from trihydroxypyridine into glutamate, a central compound of nitrogen metabolism
physiological function
-
the omega-amidase, together with glutamate dehydrogenase, may form a physiologically relevant enzyme couple, leading to transformation of metabolically inert alpha-oxoglutaramate derived from trihydroxypyridine into glutamate, a central compound of nitrogen metabolism
physiological function
-
the omega-amidase, together with glutamate dehydrogenase, may form a physiologically relevant enzyme couple, leading to transformation of metabolically inert alpha-oxoglutaramate derived from trihydroxypyridine into glutamate, a central compound of nitrogen metabolism
physiological function
Nocardioides sp. JS614 / ATCC BAA-499
-
the omega-amidase, together with glutamate dehydrogenase, may form a physiologically relevant enzyme couple, leading to transformation of metabolically inert alpha-oxoglutaramate derived from trihydroxypyridine into glutamate, a central compound of nitrogen metabolism
-