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Revision as of 02:49, 13 December 2022

Mevalonate 3,5-Bisphosphate Decarboxylase Structure

1 Function of your protein
2 Biological relevance and broader implications
3 Important amino acids
4 Structural highlights

Function of your protein

The protein of interest is the enzyme . The MBD enzyme was observed in Thermoplasma-type MVA pathway, specifically as a catalytic enzyme in the MBD reaction. The function of MBD is to catalyze the removal of the phosphate group from the 3rd carbon of mevalonate 3,5-bisphosphate (MVA3,5BP). The enzyme also accompanies the decarboxylation of the substrate. MBD acts upon MVA3,5BP to produce isopentnyl phosphate (IP), PO4, and CO2 in the MBD reaction.

Biological relevance and broader implications

Important amino acids

The in the MBD enzyme is called and is located within subunit A. OLA is hydrogen bonded to . In addition to the hydrogen bonding between OLA and Arg128, OLA is also hydrogen bonded to a water molecule which is hydrogen bonded to Arg128 as well. Amino acids residue aspartate is important for catalytic activity and the stability of the protein. When Asp281 is replaced the enzyme experiences lose in decarboxylase function. When Asp309 is replaced the enzyme experiences complete loss of MBD activity.

Structural highlights

The MBD protein is composed of alpha helix, parallel and anti-parrallel beta sheet, and random coils. The protein consists of two major subunits with a 60% alpha helixes and 40% beta sheets when viewing the tertiary . The alpha helixes and beta sheets within each individual subunit loop and fold to form a . The two subunits of the protein are homodimers, containing essentially identical alpha helixes and beta sheets between the two subunits, with intermolecular forces such as hydrogen bonds connecting them. The proteins contains both polar and non-polar amino acid, making the protein . The MBD enzymes is noted to have evolved from the ATP-depedent PMD enzyme where it lost its ability to bind to kinase and became ATP-indepedent. This belief is supported by the discovery that the MBD enzyme's ligand binding site overlaps with the ATP binding site observed in its homologous enzyme, DMD.

References

^[1]

↑ Azami Y, Hattori A, Nishimura H, Kawaide H, Yoshimura T, Hemmi H. (R)-mevalonate 3-phosphate is an intermediate of the mevalonate pathway in Thermoplasma acidophilum. J Biol Chem. 2014 Jun 6;289(23):15957-67. doi: 10.1074/jbc.M114.562686. Epub 2014, Apr 22. PMID:24755225 doi:http://dx.doi.org/10.1074/jbc.M114.562686

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 == Important amino acids==
-The <scene name='93/934003/Protein_view_2/1'>ligand of interest</scene> in the MBD enzyme is called <scene name='93/934003/Ola/1'>Oleic acid (OLA)</scene> and is located within subunit A. OLA is hydrogen bonded to <scene name='93/934003/Arg128_bonded_to_ola/1'>Arg128</scene>. Amino acids residue aspartate is important for catalytic activity and the stability of the protein. When Asp281 is replaced the enzyme experiences lose in decarboxylase function. When Asp309 is replaced the enzyme experiences complete loss of MBD activity.
+The <scene name='93/934003/Protein_view_2/1'>ligand of interest</scene> in the MBD enzyme is called <scene name='93/934003/Ola/1'>Oleic acid (OLA)</scene> and is located within subunit A. OLA is hydrogen bonded to <scene name='93/934003/Arg128_bonded_to_ola/1'>Arg128</scene>. In addition to the hydrogen bonding between OLA and Arg128, OLA is also hydrogen bonded to a water molecule which is hydrogen bonded to Arg128 as well. Amino acids residue aspartate is important for catalytic activity and the stability of the protein. When Asp281 is replaced the enzyme experiences lose in decarboxylase function. When Asp309 is replaced the enzyme experiences complete loss of MBD activity.
 == Structural highlights ==
 The MBD protein is composed of alpha helix, parallel and anti-parrallel beta sheet, and random coils. The protein consists of two major subunits with a 60% alpha helixes and 40% beta sheets when viewing the tertiary <scene name='93/934003/60_alpha_and_40_beta/1'>structure</scene>. The alpha helixes and beta sheets within each individual subunit loop and fold to form a <scene name='93/934003/Space_filling/1'>3D globular protein</scene>. The two subunits of the protein are homodimers, containing essentially identical alpha helixes and beta sheets between the two subunits, with intermolecular forces such as hydrogen bonds connecting them. The proteins contains both polar and non-polar amino acid, making the protein <scene name='93/934003/Amphipathic/1'>amphipathic</scene>. The MBD enzymes is noted to have evolved from the ATP-depedent PMD enzyme where it lost its ability to bind to kinase and became ATP-indepedent. This belief is supported by the discovery that the MBD enzyme's ligand binding site overlaps with the ATP binding site observed in its homologous enzyme, DMD.
-.In addition to the hydrogen bonding between OLA and Arg128, OLA is also hydrogen bonded to a water molecule which is hydrogen bonded to Arg128 as well
 </StructureSection>

Sandbox Reserved 1759

From Proteopedia

Revision as of 02:49, 13 December 2022

Mevalonate 3,5-Bisphosphate Decarboxylase Structure

Contents

Function of your protein

Biological relevance and broader implications

Important amino acids

Structural highlights

References

Views

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