Fumarase 2

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Fumarase

Overview

Fumarase, also known as fumarate hydratase, is an enzyme in the citric acid cycle. In the seventh step of the reaction pathway, fumarase catalyzes the reversible hydration reaction that converts fumarate to malate and vice versa. Fumarase is classified as an which belongs to the L-aspartase/fumarase family. It forms a tetramer of identical subunits that . Each subunit is comprised of .

Structure: will the real active site please stand?

Crystal structures of fumarase C revealed that the enzyme has two dicarboxylate binding sites; one was called the A site, and the second, the B site. This raises the question: which of the two sites is the active site of the enzyme? The A site shows relatively little change upon substrate binding, while the B site shifts substantially. ^[1]. But these changes could account for regulation...so which site is the true active site?

In order to answer this question, an experiment that tested each of the sites independently was conducted. Both sites contain histidine residues: in the A-site and in the B-site. These sites were mutated to asparagine in separate experiments, and the effect on kinetics was measured. The results of the experiment showed that the H129N mutation had little effect on the enzymatic activity of the enzyme, as the specific activity of the enzyme was comparable to the wild-type enzyme. In contrast, the mutation dramatically reduced the specific activity of the catalytic reaction. These data strongly suggested that the H188 residue had a direct role in the catalytic mechanism of the enzyme and, therefore, that the H188 residue was located in the active site of the enzyme. This lead to the conclusion that that the A-site was in fact the active site of the enzyme^[2].

Active Site Characteristics

The active site (A-site) of the fumarase enzyme is formed by residues from three of the enzyme’s four subunits (shown in ) and is located in a relatively deep pit that is removed from bulk solvent ^[3]. The residues that form the include N141b, T100b, S98b, E331c, K324c, N326c, His 188c, (the letter indicates the chain) and a water molecule. It is speculated that the is the most important active site residue, activating the water through a , which increases the basicity of the water molecule. This electron-withdrawing hydrogen bond allows the water molecule to remove the C3 proton of malate, though this model has in the active site. Complex hydrogen bonding patterns in the active site also help stabilize the aci-carboxylate intermediate^[2]. By increasing the stabilization if the intermediate, the fumarase enzyme can effectively catalyze the hydration/dehydration reaction between L-malate and fumarate.

References

↑ Weaver,T. Structure of free fumarase C from Escherichia coli. Acta Crystallographica (2005), D61, 1395-1401. [http://dx.doi.org/10.1107/S0907444905024194 doi:10.1107/S0907444905024194]
↑ ^2.0 ^2.1 Weaver T, Lees M, Banaszak L. Mutations of fumarase that distinguish between the active site and a nearby dicarboxylic acid binding site. Protein Sci. 1997 Apr;6(4):834-42. PMID:9098893
↑ Weaver TM, Levitt DG, Donnelly MI, Stevens PP, Banaszak LJ. The multisubunit active site of fumarase C from Escherichia coli. Nat Struct Biol. 1995 Aug;2(8):654-62. PMID:7552727

Proteopedia Page Contributors and Editors (what is this?)

Ann Taylor, Michal Harel, Karsten Theis, Jaime Prilusky

Retrieved from "http://52.214.119.220/wiki/index.php/Fumarase_2"

@@ Line 1: / Line 1: @@
-<StructureSection load='1fuo' size='350' side='right' caption='Fumarase with citrate bound to the active site (PDB profile: 1fuo)'>
+==Fumarase==
-=Fumarase=
+<StructureSection load='1fuo' size='340' side='right' caption='Fumarase with citrate bound to the active site (PDB profile: 1fuo)' scene = ''>
 ===Overview===
-Fumarase, also known as fumarate hydratase, is an enzyme in the citric acid cycle. In the seventh step of the reaction pathway, fumarase catalyzes the reversible hydration reaction that converts fumarate to malate and vice versa.
+'''Fumarase''', also known as fumarate hydratase, is an enzyme in the citric acid cycle. In the seventh step of the reaction pathway, fumarase catalyzes the reversible hydration reaction that converts fumarate to malate and vice versa.  Fumarase is classified as an <scene name='44/446278/Secondary_structure/2'>alpha helical protein</scene> which belongs to the L-aspartase/fumarase family. It forms a tetramer of identical subunits that <scene name='44/446278/Rainbow_subunits/1'>alternate in orientation</scene>. Each subunit is comprised of <scene name='44/446278/Domains/1'>three domains</scene>.
-===Stucture===
-Fumarase is classified as an all alpha protein which belongs to the L-aspartase/fumarase family. It forms a tetramer of identical subunits.  Crystal structures of fumarase C revealed that the enzyme has two dicarboxylate binding sites; one was called the A site, and the second, the B site.  This raises the question: which of the two sites is the active site of the enzyme?  The A site shows relatively little change upon substrate binding, while the B site shifts substantially. <ref name="Weaver, et al."> Weaver,T.  Structure of free fumarase C from ''Escherichia coli''. ''Acta Crystallographica'' (2005), '''D61''', 1395-1401. ['''http://dx.doi.org/10.1107/S0907444905024194''' doi:10.1107/S0907444905024194]</ref>. But these changes could account for regulation...so which site is the true active site?
-In order to answer this question, an experiment that tested each of the sites independently was conducted. Both sites contain histidine residues: <scene name='72/726367/His_188/1'>His 188</scene> in the A-site and <scene name='72/726367/His_129/1'>His 129</scene> in the B-site.  These sites were mutated to asparagine in separate experiments, and the effect on kinetics was measured. The results of the experiment showed that the H129N mutation had little effect on the enzymatic activity of the enzyme, as the specific activity of the enzyme was comparable to the wild-type enzyme. In contrast, the <scene name='72/726367/Ans_188_mutant/1'>H188N</scene> mutation dramatically reduced the specific activity of the catalytic reaction. These data strongly suggested that the H188 residue had a direct role in the catalytic mechanism of the enzyme and, therefore, that the H188 residue was located in the active site of the enzyme.  This lead to the conclusion that that the A-site was in fact the active site of the enzyme<ref name= "Weaver">PMID:9098893</ref>.
-== Structure and Function of the Fumurase Active Site ==
-The active site (A-site) of the fumarase enzyme is formed by residues from three of the enzyme’s four subunits and is located in a relatively deep pit that is removed from bulk solvent. The multi-subunit active site is comprised of atoms from residues 312-334 from subunit A, residues 182-200 from subunit C, and residues 129-145 from subunit D<ref>PMID: 7552727</ref>. The residues that form the active site are N141b, T100b, S98b, E331c, K324c, N326c, His 188C, and a water molecule, W-26. It is speculated that the H188 and W-26 are two of the most vital active site residues. Furthermore, H188 and W-26 form a short hydrogen bond, which increases the basicity of the water molecule. This electron-withdrawing hydrogen bond allows the water molecule to remove the C3 proton of <scene name='72/726367/L-malate/1'>L-malate</scene>. The cationic charge on W-26 plays an essential role in the stabilization of the double negative charge that is present on the aci-carboxylate at C4. Complex hydrogen bonding patterns in the active site involving T187, N141, H188, N362, and K324 also help stabilize the aci-carboxylate intermediate<ref name= "Weaver">PMID:9098893</ref>. By increasing the stabilization if the intermediate, the fumarase enzyme can effectively catalyze the hydration/dehydration reaction between L-malate and fumarate.
-===Regulation===
-Similar to most enzymes involved in biological processes, fumarase can be regulated in several different ways.  Allosteric effects commonly regulate fumarase activity via substrate and inhibitor binding with the active site.  Fumarase activity is both positively and negatively regulated by substrate concentration.  When the concentration of a substrate is five-fold of the Km value, it activates fumarase’s activity; however, substrate concentrations above 0.1 M result in inhibition of fumarase function <ref name="Beeckmans, et al."/>.  The concentration of substrate influences cooperativity of fumarase, depending on the availability of substrate to bind to domains.
-The regulation of fumarase via allosteric effects involves conformational changes that occur when a substrate binds to the active site.  Studies involving amino acid residue manipulation in the B site show that the B site helps regulate the binding affinity for the active site by allosteric effects <ref name="Beeckmans, et al."/>,<ref name="Rose & Weaver"/>.  According to Weaver (2004), the active site and B site are located 12 Å apart which suggests that the conformational changes resulting from <scene name='Vas_Sandbox_1/Malate_interaction/2'>malate interactions</scene> with the B site influence the active site affinity to bind with the substrate <ref name="Weaver, et al."/>.  Inhibitors also regulate the activity of an enzyme via binding to the active site.  Both citrate and succinate are known as competitive inhibitors of fumarase since they negatively influence the enzyme’s activity.  They are competitive inhibitors because they have structural similarity to the substrate; therefore, the inhibitors compete with substrates to bind with the active site.  The natural state of fumarase commonly involves <scene name='Vas_Sandbox_1/Citrate_interaction/2'>citrate interactions</scene> with the active site in which similar amino acid residues responsible for binding with a substrate result in binding with a citrate molecule.
+==Structure:  will the real active site please stand?==
+Crystal structures of fumarase C revealed that the enzyme has two dicarboxylate binding sites; one was called the A site, and the second, the B site.  This raises the question: which of the two sites is the active site of the enzyme?  The A site shows relatively little change upon substrate binding, while the B site shifts substantially. <ref name="Weaver, et al."> Weaver,T.  Structure of free fumarase C from ''Escherichia coli''. ''Acta Crystallographica'' (2005), '''D61''', 1395-1401. ['''http://dx.doi.org/10.1107/S0907444905024194''' doi:10.1107/S0907444905024194]</ref>. But these changes could account for regulation...so which site is the true active site?
+In order to answer this question, an experiment that tested each of the sites independently was conducted. Both sites contain histidine residues: <scene name='44/446278/His_188/1'>His 188</scene> in the A-site and <scene name='44/446278/His_129/1'>His 129</scene> in the B-site.  These sites were mutated to asparagine in separate experiments, and the effect on kinetics was measured. The results of the experiment showed that the H129N mutation had little effect on the enzymatic activity of the enzyme, as the specific activity of the enzyme was comparable to the wild-type enzyme. In contrast, the <scene name='72/726367/Ans_188_mutant/1'>H188N</scene> mutation dramatically reduced the specific activity of the catalytic reaction. These data strongly suggested that the H188 residue had a direct role in the catalytic mechanism of the enzyme and, therefore, that the H188 residue was located in the active site of the enzyme.  This lead to the conclusion that that the A-site was in fact the active site of the enzyme<ref name= "Weaver">PMID:9098893</ref>.
-</structure section>
+== Active Site Characteristics ==
+The active site (A-site) of the fumarase enzyme is formed by residues from three of the enzyme’s four subunits (shown in <scene name='44/446278/Active_site_chains/3'>different colors</scene>) and is located in a relatively deep pit that is removed from bulk solvent <ref>PMID: 7552727</ref>. The residues that form the <scene name='44/446278/Active_site_residues/6'>active site</scene> include N141b, T100b, S98b, E331c, K324c, N326c, His 188c, (the letter indicates the chain) and a water molecule. It is speculated that the <scene name='44/446278/His_188_active_site/2'>H188</scene> is the most important active site residue, activating the water through a <scene name='44/446278/Short_h_bond/2'>short hydrogen bond</scene>, which increases the basicity of the water molecule. This electron-withdrawing hydrogen bond allows the water molecule to remove the C3 proton of malate, though this model has <scene name='44/446278/Citrate/2'>citrate</scene> in the active site. Complex hydrogen bonding patterns in the active site also help stabilize the aci-carboxylate intermediate<ref name= "Weaver">PMID:9098893</ref>. By increasing the stabilization if the intermediate, the fumarase enzyme can effectively catalyze the hydration/dehydration reaction between L-malate and fumarate.
+</StructureSection>
 ===References===
 <references/>

Fumarase 2

From Proteopedia

Current revision

Fumarase

Overview

Structure: will the real active site please stand?

Active Site Characteristics

References

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