Fumarase

This enzyme belongs to the family of lyases, specifically the hydro-lyases, which cleave carbon-oxygen bonds. The systematic name of this enzyme class is (S)-malate hydro-lyase (fumarate-forming). Other names in common use include:

• fumarase
• L-malate hydro-lyase
• (S)-malate hydro-lyase

File: 1fuo2.jpg

In humans, the FH gene is localized to the chromosomal position 1q42.3-q43. The FH gene contains 10 exons.

Crystal structures of fumarase C from Escherichia coli have been observed to have two dicarboxylate binding sites close to one another. These are known as the active site and the B site. These sites are connected by a series of hydrogen bonds and the access to either site is only through an opening near the enzyme surface near the B site. Active site is made up of three domains. Even when no ligand is bound to the active site, the binding pocket created by surrounding residues is sufficient to bind water in its place. Crystallographic research on the B site of the enzyme has observed that there is a shift on His129 between free and occupied states. It also suggests that the use of an imidazole-imidazolium conversion controls access to the allosteric B site.{{cite journal | vauthors = Weaver T | title = Structure of free fumarase C from Escherichia coli | journal = Acta Crystallographica. Section D, Biological Crystallography | volume = 61 | issue = Pt 10 | pages = 1395–1401 | date = October 2005 | pmid = 16204892 | doi = 10.1107/S0907444905024194 }}

There are two classes of fumarases, class I and class II.{{cite web | url = http://atlasgeneticsoncology.org/Genes/FHID40573ch1q42.html | title = FH (fumarate hydratase). |vauthors=Lynch AM, Morton CC | date = 2006-07-01 | publisher = Atlas of Genetics and Cytogenetics in Oncology and Haematology }} Classification depends on the arrangement of their relative subunits, their metal ion requirement, and their thermal stability. Class I fumarases are change state or become inactive when subjected to heat or radiation, are sensitive to superoxide anion, are iron (Fe²⁺) dependent, and are dimeric proteins with each subunit consisting of around 120 kD. Class II fumarases, found in prokaryotes as well as in eukaryotes, are tetrameric enzymes with subunits of 200 kD that contain three distinct segments of significantly homologous amino acids. They are also iron-independent and thermally stable. Prokaryotes are known to have three different forms of fumarase: Fumarase A, Fumarase B, and Fumarase C. Fumarase A and Fumarase B from Escherichia coli are classified as class I, whereas Fumarase C is a part of the class II fumarases.

Image:FumaraseMechanismE1CB.png

Figure 1 depicts the fumarase reaction mechanism. Two residues catalyze proton transfer and the ionization state of these residues is in part defined by two forms of the enzyme, E₁ and E₂. In E₁, the groups exist in an internally neutralized AH/B: state, while in E₂, they occur in a zwitterionic A⁻/BH⁺ state. E₁ binds fumarate and facilitates its transformation into malate, and E₂ binds malate and facilitates its transformation into fumarate. The two forms must undergo isomerization with each catalytic turnover.{{cite book | vauthors = Hegemony AD, Frey PA | title = Enzymatic reaction mechanisms | publisher = Oxford University Press | location = Oxford [Oxfordshire] | year = 2007 | isbn = 978-0-19-512258-9 }}

Image:Reaction1.png

Despite its biological significance, the reaction mechanism of fumarase is not completely understood. The reaction itself can be monitored in either direction; however, it is the formation of fumarate from S-malate in particular that is less understood due to the high pK_a value of the H^R atom (Fig. 2) that is removed without the aid of any cofactors or coenzymes. The reaction from fumarate to S-malate is better understood, and involves a stereospecific hydration of fumarate to produce S-malate by trans-addition of a hydroxyl group and a hydrogen atom. Early research into this reaction suggested that the formation of fumarate from S-malate involved dehydration of malate to a carbocationic intermediate, which then loses the alpha proton to form fumarate. This led to the conclusion that the formation of S-malate proceeds as E1 elimination - protonation of fumarate to create a carbocation was followed by the addition of a hydroxyl group from H₂O. However, more recent trials have provided evidence that the mechanism actually takes place through an acid-base catalyzed elimination by means of a carbanionic intermediate, meaning it proceeds as E1cB elimination (Figure 1).{{cite book | vauthors = Begley TP, McMurry J | title = The organic chemistry of biological pathways | publisher = Roberts and Co. Publishers | year = 2005 | isbn = 978-0-9747077-1-6 }}{{cite book | vauthors = Walsh C | title = Enzymatic reaction mechanisms | publisher = W. H. Freeman | location = San Francisco | year = 1979 | isbn = 978-0-7167-0070-8 }}

The function of fumarase in the citric acid cycle is to facilitate a transition step in the production of energy in the form of NADH.{{cite journal | vauthors = Yogev O, Naamati A, Pines O | title = Fumarase: a paradigm of dual targeting and dual localized functions | journal = The FEBS Journal | volume = 278 | issue = 22 | pages = 4230–4242 | date = November 2011 | pmid = 21929734 | doi = 10.1111/j.1742-4658.2011.08359.x | doi-access = free }} In the cytosol, the enzyme functions to metabolize fumarate, which is a byproduct of the urea cycle as well as amino acid catabolism. Studies have revealed that the active site is composed of amino acid residues from three of the four subunits within the tetrameric enzyme.{{cite journal | vauthors = Estévez M, Skarda J, Spencer J, Banaszak L, Weaver TM | title = X-ray crystallographic and kinetic correlation of a clinically observed human fumarase mutation | journal = Protein Science | volume = 11 | issue = 6 | pages = 1552–1557 | date = June 2002 | pmid = 12021453 | pmc = 2373640 | doi = 10.1110/ps.0201502 }}

The main substrates for fumarase are malate and fumarate. However, the enzyme can also catalyze the dehydration of D-tartrate which results in enol-oxaloacetate. Enol-oxaloacetate can then izomerize into keto-oxaloacetate. Both Fumarase A and Fumarase B have essentially the same kinetics for the reversible malate to fumarase conversion, but Fumarase B has a much higher catalytic efficiency for the conversion of D-tartrate to oxaloacetate compared to Fumarase A.{{cite journal | vauthors = van Vugt-Lussenburg BM, van der Weel L, Hagen WR, Hagedoorn PL | title = Biochemical similarities and differences between the catalytic [4Fe-4S] cluster containing fumarases FumA and FumB from Escherichia coli | journal = PLOS ONE | volume = 8 | issue = 2 | pages = e55549 | date = February 26, 2021 | pmid = 23405168 | pmc = 3565967 | doi = 10.1371/journal.pone.0055549 | doi-access = free }} This allows bacteria such as E. coli use D-tartrate for their growth; the growth of mutants with a disruptive gene fumB encoding Fumarase B on D-tartrate was severely impaired.

Fumarase deficiency is characterized by polyhydramnios and fetal brain abnormalities. In the newborn period, findings include severe neurologic abnormalities, poor feeding, failure to thrive, and hypotonia. Fumarase deficiency is suspected in infants with multiple severe neurologic abnormalities in the absence of an acute metabolic crisis. Inactivity of both cytosolic and mitochondrial forms of fumarase are potential causes. Isolated, increased concentration of fumaric acid on urine organic acid analysis is highly suggestive of fumarase deficiency. Molecular genetic testing for fumarase deficiency is currently available.

Fumarase is prevalent in both fetal and adult tissues. A large percentage of the enzyme is expressed in the skin, parathyroid, lymph, and colon. Mutations in the production and development of fumarase have led to the discovery of several fumarase-related diseases in humans. These include benign mesenchymal tumors of the uterus, leiomyomatosis and renal cell carcinoma, and fumarase deficiency. Germinal mutations in fumarase are associated with two distinct conditions. If the enzyme has missense mutation and in-frame deletions from the 3’ end, fumarase deficiency results. If it contains heterozygous 5’ missense mutation and deletions (ranging from one base pair to the whole gene), then leiomyomatosis and renal cell carcinoma/Reed’s syndrome (multiple cutaneous and uterine leiomyomatosis) could result.

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• Fumarase deficiency

{{reflist|33em}}

• {{MeshName|Fumarase}}
• [https://web.archive.org/web/20061011220752/http://www.biocheminfo.org/klotho/html/fumarate.html Structure of Fumarate]
• [https://web.archive.org/web/20061011234603/http://www.biocheminfo.org/klotho/html/L-malate.html Structure of S-Malate]
• [http://www.biology.pomona.edu/hoopes/bio147/Fumarate%20Hydratase%20(final).doc Link to Breakdown of Citric Acid Cycle]
• [http://www.johnkyrk.com/krebs.html Video of Fumarate → (S)L-Malate] {{Webarchive|url=https://web.archive.org/web/20050625074113/http://www.johnkyrk.com/krebs.html |date=2005-06-25 }}

{{Citric acid cycle enzymes}}

{{Mitochondrial enzymes}}

{{Carbon-oxygen lyases}}

{{Enzymes}}

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Category:EC 4.2.1