Sandbox Reserved 1559
From Proteopedia
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{{Sandbox_Reserved_BHall_Chem351_F19}}<!-- PLEASE ADD YOUR CONTENT BELOW HERE --> | {{Sandbox_Reserved_BHall_Chem351_F19}}<!-- PLEASE ADD YOUR CONTENT BELOW HERE --> | ||
| - | == | + | ==Overview== |
| - | <StructureSection load='6ojt' size=' | + | <StructureSection load='6ojt' size='440' side='right' frame='true' caption='Caption for this structure' scene=''> |
This is a default text for your page ''''''. Click above on '''edit this page''' to modify. Be careful with the < and > signs. | This is a default text for your page ''''''. Click above on '''edit this page''' to modify. Be careful with the < and > signs. | ||
You may include any references to papers as in: the use of JSmol in Proteopedia <ref>DOI 10.1002/ijch.201300024</ref> or to the article describing Jmol <ref>PMID:21638687</ref> to the rescue. | You may include any references to papers as in: the use of JSmol in Proteopedia <ref>DOI 10.1002/ijch.201300024</ref> or to the article describing Jmol <ref>PMID:21638687</ref> to the rescue. | ||
== Function(s) and Biological Relevance == | == Function(s) and Biological Relevance == | ||
| + | <scene name='82/823083/6ojt/1'>Lignostilbene-α,β-dioxygenase A (LsdA) from the bacterium ''Sphingomonas paucimobilis'' TMY1009</scene> is a nonheme iron oxygenase that catalyzes the cleavage of lignostilbene, a compound arising in lignin transformation, to two vanillin molecules. LsdA has greatest substrate specificity for lignostilbene. The substrate's 4-hydryoxy moiety is required for catalysis. Phenylazophenol inhibits the cleavage of lignostilbene by LsdA. The breaking down of lignin is essential to the sustainable biorefining of lignocellulose. It is of great relevance to transforming lignocellulose to biofuels.<ref> PMID:31292192 </ref> | ||
| - | == Broader Implications == | ||
| + | == Broader Implications == | ||
| + | Lignin represents 30% of the lignocellulose biomass. It consists of different aromatic building blocks, phenylpropanoids, which are extremely useful. Normally aromatic compounds are extracted from petroleum and are used to manufacture drugs, paint, plastics, etc. Therefore the potential of lignin is very high. Lignin is the most abundant polymer in nature other than cellulose and chitin, and it is the only one that contains such a large number of aromatic compounds. | ||
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== Structural highlights and structure-function relationships == | == Structural highlights and structure-function relationships == | ||
| + | This protein has a <scene name='82/823083/6ojttriad/1'>Catalytic Triad</scene> which consists of the amino acids Phe-59, Tyr101, and Lys-134. These amino acids play an important role in catalysis for the protein. Lys-134 proved to be the most important amino acid. The basic spacefill view of the entire protein allows for visualization of the different elements in different colors. The elements shown are carbon (Grey), nitrogen (Blue), and oxygen (Red). The <scene name='82/823083/Spacefill/1'>spacefill view</scene> also allows for visualization of different allosteric binding sites. This protein has a <scene name='82/823083/Nsl_ligand/1'>ligand</scene>, called NSL. The structural fold of LsdA is that of a <scene name='83/830391/Rainbow_7blade_beta_propeller/2'>seven-bladed β-propeller</scene>. <ref> PMID: 30115012 </ref> <scene name='82/823083/Hydrophobic/1'>Hydrophobic interactions</scene> are highlighted in grey, and polar regions are purple, while the ligand is yellow. This protein has a catalytic triad for binding that consists of tyrosine (hydrophilic), phenylalanine (hydrophobic), and lysine (has a positive charge). | ||
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| + | The <scene name='82/823083/Secondary_structure/1'>secondary structure</scene> of this protein is mostly composed of β-sheets with minimal areas of alpha-helices. Beta sheets provide a flat surface for interactions to occur. | ||
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| + | The tertiary structure creates a<scene name='82/823083/Aminobindingpocket/1'> binding pocket of amino acids</scene> that are important to the active site. His282 provides pi-stacking, Phe305 provides Hydrophobic contacts, and Tyr101 provides Hydrogen bonding. The tertiary structure also allows the NSL ligand to interact using its 4-hydroxy with the catalytic triad. LsdA can only cleave 4-hydroxystilbenes. | ||
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| + | The tertiary structure also creates a <scene name='82/823083/Metal_binding_site/1'>metal-binding site</scene> of Histidines to keep the iron molecule in place. This site is located in the active site where the single Fe2+ ion resides at the center of the β-propeller. This metal ion is coordinated in a tetragonal pyramidal fashion by four histidines (His-167, His-218, His-282, and His-472). There have been two mechanisms proposed for Lsd's. In one mechanism, the hydroxystillbenoid is activated via the enzyme-catalyzed deprotonation of the 4-hydroxy group, which then allows electron delocalization toward an Fe3+. In the other mechanism, π electron density from the double bond is redistributed to the iron-oxy complex to form an Fe2+ cation intermediate. Deprotonation of the hydroxyl is demanding for both mechanisms and is assisted by Lys134 and Tyr101. | ||
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== Energy Transformation == | == Energy Transformation == | ||
| + | Phenylazophenol inhibits the LsdA-catalyzed cleavage of lignostilbene in a reversible, mixed fashion. | ||
| - | This is a sample scene created with SAT to <scene name="/12/3456/Sample/1">color</scene> by Group, and another to make <scene name="/12/3456/Sample/2">a transparent representation</scene> of the protein. You can make your own scenes on SAT starting from scratch or loading and editing one of these sample scenes. | ||
</StructureSection> | </StructureSection> | ||
== References == | == References == | ||
<references/> | <references/> | ||
Current revision
| This Sandbox is Reserved from Aug 26 through Dec 12, 2019 for use in the course CHEM 351 Biochemistry taught by Bonnie_Hall at the Grand View University, Des Moines, USA. This reservation includes Sandbox Reserved 1556 through Sandbox Reserved 1575. |
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Overview
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References
- ↑ Hanson, R. M., Prilusky, J., Renjian, Z., Nakane, T. and Sussman, J. L. (2013), JSmol and the Next-Generation Web-Based Representation of 3D Molecular Structure as Applied to Proteopedia. Isr. J. Chem., 53:207-216. doi:http://dx.doi.org/10.1002/ijch.201300024
- ↑ Herraez A. Biomolecules in the computer: Jmol to the rescue. Biochem Mol Biol Educ. 2006 Jul;34(4):255-61. doi: 10.1002/bmb.2006.494034042644. PMID:21638687 doi:10.1002/bmb.2006.494034042644
- ↑ Kuatsjah E, Verstraete MM, Kobylarz MJ, Liu AKN, Murphy MEP, Eltis LD. Identification of functionally important residues and structural features in a bacterial lignostilbene dioxygenase. J Biol Chem. 2019 Jul 10. pii: RA119.009428. doi: 10.1074/jbc.RA119.009428. PMID:31292192 doi:http://dx.doi.org/10.1074/jbc.RA119.009428
- ↑ Loewen PC, Switala J, Wells JP, Huang F, Zara AT, Allingham JS, Loewen MC. Structure and function of a lignostilbene-alpha,beta-dioxygenase orthologue from Pseudomonas brassicacearum. BMC Biochem. 2018 Aug 16;19(1):8. doi: 10.1186/s12858-018-0098-4. PMID:30115012 doi:http://dx.doi.org/10.1186/s12858-018-0098-4
