1.14.13.111: methanesulfonate monooxygenase (NADH)
This is an abbreviated version!
For detailed information about methanesulfonate monooxygenase (NADH), go to the full flat file.
Word Map on EC 1.14.13.111
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1.14.13.111
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methylovora
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sulfur
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methanol
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ferredoxins
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hydroxylase
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metagenome
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methylobacterium
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biogeochemical
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rieske-type
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hyphomicrobium
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methylotrophy
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sulfite
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ocean
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multicomponent
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afipia
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portuguese
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atlantic
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antarctica
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estuary
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signy
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felis
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dimethylsulfide
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rieske
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portugal
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nadh-specific
- 1.14.13.111
- methylovora
- sulfur
- methanol
- ferredoxins
- hydroxylase
- metagenome
- methylobacterium
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biogeochemical
-
rieske-type
- hyphomicrobium
-
methylotrophy
- sulfite
-
ocean
-
multicomponent
- afipia
-
portuguese
-
atlantic
-
antarctica
-
estuary
-
signy
- felis
- dimethylsulfide
-
rieske
-
portugal
-
nadh-specific
Reaction
Synonyms
EC 1.14.14.6, methanesulfonate monooxygenase, methanesulfonic acid monooxygenase, MSA monooxygenase, MSAMO, Msm, MsmA
ECTree
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General Information
General Information on EC 1.14.13.111 - methanesulfonate monooxygenase (NADH)
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evolution
physiological function
the two msm operons in Filomicrobium sp. strains Y and W are divergently transcribed, like in Methylosulfonomonas methylovora str. M2
evolution
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the two msm operons in Filomicrobium sp. strains Y and W are divergently transcribed, like in Methylosulfonomonas methylovora str. M2
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evolution
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the two msm operons in Filomicrobium sp. strains Y and W are divergently transcribed, like in Methylosulfonomonas methylovora str. M2
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all strains isolated grow with methanesulfonate as sole carbon substrate
physiological function
the enzyme is responsible for splitting the C-S bond, catalyzing the first oxidative step of MSA to the central methylotrophic intermediate formaldehyde with the release of sulfite, which is subsequently oxidized to sulfate. Formaldehyde is assimilated through the serine cycle or fully oxidized to CO2 and H2O, in order to yield reducing power and energy
physiological function
the enzyme is responsible for splitting the C-S bond, catalyzing the first oxidative step of MSA to the central methylotrophic intermediate formaldehyde with the release of sulfite, which is subsequently oxidized to sulfate. Formaldehyde is assimilated through the serine cycle or fully oxidized to CO2 and H2O, in order to yield reducing power and energy
physiological function
the enzyme is responsible for splitting the C-S bond, catalyzing the first oxidative step of MSA to the central methylotrophic intermediate formaldehyde with the release of sulfite, which is subsequently oxidized to sulfate. Formaldehyde is assimilated through the serine cycle or fully oxidized to CO2 and H2O, in order to yield reducing power and energy
physiological function
the enzyme is responsible for splitting the C-S bond, catalyzing the first oxidative step of MSA to the central methylotrophic intermediate formaldehyde with the release of sulfite, which is subsequently oxidized to sulfate. Formaldehyde is assimilated through the serine cycle or fully oxidized to CO2 and H2O, in order to yield reducing power and energy
physiological function
the enzyme is responsible for splitting the C-S bond, catalyzing the first oxidative step of MSA to the central methylotrophic intermediate formaldehyde with the release of sulfite, which is subsequently oxidized to sulfate. Formaldehyde is assimilated through the serine cycle or fully oxidized to CO2 and H2O, in order to yield reducing power and energy
physiological function
-
the enzyme is responsible for splitting the C-S bond, catalyzing the first oxidative step of MSA to the central methylotrophic intermediate formaldehyde with the release of sulfite, which is subsequently oxidized to sulfate. Formaldehyde is assimilated through the serine cycle or fully oxidized to CO2 and H2O, in order to yield reducing power and energy
-
physiological function
-
the enzyme is responsible for splitting the C-S bond, catalyzing the first oxidative step of MSA to the central methylotrophic intermediate formaldehyde with the release of sulfite, which is subsequently oxidized to sulfate. Formaldehyde is assimilated through the serine cycle or fully oxidized to CO2 and H2O, in order to yield reducing power and energy
-
physiological function
-
the enzyme is responsible for splitting the C-S bond, catalyzing the first oxidative step of MSA to the central methylotrophic intermediate formaldehyde with the release of sulfite, which is subsequently oxidized to sulfate. Formaldehyde is assimilated through the serine cycle or fully oxidized to CO2 and H2O, in order to yield reducing power and energy
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