Fumarase: Difference between revisions
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===Fumarase=== | ===Fumarase=== | ||
[[3qbp]] – FUM – Mycobacterium marinum<br /> | [[3qbp]] – FUM – ''Mycobacterium marinum''<br /> | ||
[[3no9]] – FUM II – Mycobacterium tuberculosis<br /> | [[3no9]] – FUM II – ''Mycobacterium tuberculosis''<br /> | ||
[[3gtd]] – FUM II – Rickettsia prowazekii<br /> | [[3gtd]] – FUM II – ''Rickettsia prowazekii''<br /> | ||
[[3e04]] – FUM residues 44-510 – human<br /> | [[3e04]] – FUM residues 44-510 – human<br /> | ||
[[2isb]] – FUM I – Archaeoglobus fulgidus<br /> | [[2isb]] – FUM I – ''Archaeoglobus fulgidus''<br /> | ||
[[2yfe]], [[1yfm]] – EcFUM II – Escherichia coli<br /> | [[2yfe]], [[1yfm]] – EcFUM II – ''Escherichia coli''<br /> | ||
[[1vdk]], [[1kq7]] - EcFUM II (mutant) | [[1vdk]], [[1kq7]] - EcFUM II (mutant) | ||
Revision as of 12:00, 17 August 2011
Fumarase is used in the citric acid cycle to conduct a transition step in the production of energy to make NADH. It metabolizes Fumarate in the cytosol, which becomes a byproduct of the urea cycle and amino acid catabolism. It catalyzes the addition of water to make S-Malate. This is a reversible reaction.
Other interesting informationOther interesting information
Fumarase is dominant in fetal and adult tissues and largely expressed in the skin, parathyroid, lymph, and colon There are two classes of Fumarases, which depend on the arrangement of their relative subunit, their metal requirement, and their thermal stability. Class I Fumarases can change their state or become inactive when exposed to heat or radiation. They are sensitive to superoxide anions and Fe2+ dependent. Class II Fumarases are found in eukaryotes and prokaryotes. They are iron-independent and thermal-stable. Fumarase deficiency is an autosomal recessive metabolic disorder distinguished by a deficiency of the enzyme Fumarate hydratase and indicated by an excess of Fumaric acid in the urine. It is common of infants with neurologic abnormalities and its potential causes include cytosolic and mitochondrial forms of Fumarase.
Fumarase ScenesFumarase Scenes
3D structures of fumarase3D structures of fumarase
FumaraseFumarase
3qbp – FUM – Mycobacterium marinum
3no9 – FUM II – Mycobacterium tuberculosis
3gtd – FUM II – Rickettsia prowazekii
3e04 – FUM residues 44-510 – human
2isb – FUM I – Archaeoglobus fulgidus
2yfe, 1yfm – EcFUM II – Escherichia coli
1vdk, 1kq7 - EcFUM II (mutant)
Fumarase binary complexesFumarase binary complexes
1fur - EcFUM II (mutant) + malate
2fus - EcFUM II (mutant) + citrate
Fumarase ternary complexesFumarase ternary complexes
1fup - EcFUM II + pyromellitic acid + malate
1fuq - EcFUM II + pyromellitic acid + citrate
1fuo - EcFUM II + citrate + malate
ReferencesReferences
Wikipedia. <http://en.wikipedia.org/wiki/Fumarase>, Wikipedia. <http://en.wikipedia.org/wiki/Enolase>, University of Wisconsin- Eau Claire. <http://www.chem.uwec.edu/Webpapers_F99/Pages/Webpapers_F99/golnercm/Pages/descrip.html>, Virtual Chembook. Elmhurst College. <http://www.elmhurst.edu/~chm/vchembook/601glycolysisrx.html>
AuthorAuthor
Originally Completed by Sydney Park