Sandbox Reserved 1464
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{{Sandbox_Reserved_BHall_1}}<!-- PLEASE ADD YOUR CONTENT BELOW HERE --> | {{Sandbox_Reserved_BHall_1}}<!-- PLEASE ADD YOUR CONTENT BELOW HERE --> | ||
| - | == | + | ==Structure of Glycerol-bound Obc1== |
| - | <StructureSection load=' | + | <StructureSection load='5IKZ' size='340' side='right' caption='Glycerol bound Obc1' scene=''> |
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== Function == | == Function == | ||
| - | ''Burkholderia'' species produce oxalate which helps maintain environmental pH. Two enzymes are required to produce oxalate, ObcA and ObcB. ObcA catalyzes first, resulting in a tetrahedral C6-CoA adduct from acetyl-CoA and oxaloacetate. ObcB then produces three products from the C6-CoA adduct which include oxalate, acetoacetate, and CoA. In ''Burkholderia thailandensis'' and ''Burkholderia pseudomallei'' Obc1 carries out both steps of this reaction as it is a single bi-functional enzyme. | + | ''Burkholderia'' species produce oxalate which helps maintain environmental pH.<ref>PMID: 27226606</ref> Two enzymes are required to produce oxalate, ObcA and ObcB. ObcA catalyzes first, resulting in a tetrahedral C6-CoA adduct from acetyl-CoA and oxaloacetate. ObcB then produces three products from the C6-CoA adduct which include oxalate, acetoacetate, and CoA. In ''Burkholderia thailandensis'' and ''Burkholderia pseudomallei'' <scene name='79/799592/Cartoon_view/2'>Obc1</scene> carries out both steps of this reaction as it is a single bi-functional enzyme. |
== Disease == | == Disease == | ||
| - | ''Burkholderia'' species have many pathogenic consequences for plants and humans. ''B. cepacia'' effects immunocompromised individuals that may have cystic fibrosis or chronic granulomatous disease. ''B. pseudomallei'' causes a lethal infection called melioidosis that results in formation of abscesses. In plants, ''B. glumae'' causes bacterial panicle blight in rice. | + | ''Burkholderia'' species have many pathogenic consequences for plants and humans. ''B. cepacia'' effects immunocompromised individuals that may have cystic fibrosis or chronic granulomatous disease. ''B. pseudomallei'' causes a lethal infection called melioidosis that results in formation of abscesses. In plants, ''B. glumae'' causes bacterial panicle blight in rice. By studying Obc1 we may find the mechanism behind Burkholdria induced disease which can lead to treatments for the diseases. |
== Relevance == | == Relevance == | ||
| - | Understanding the reaction that is catalyzed by ObcA and ObcB in two steps and Obc1 in one step has clinical relevance. Currently, the molecular basis of the Obc enzymes is unknown. By studying these enzymes, a treatment may be developed for disease control | + | Understanding the reaction that is catalyzed by ObcA and ObcB in two steps and Obc1 in one step has clinical relevance. Currently, the molecular basis of the Obc enzymes is unknown. By studying these enzymes, a treatment may be developed for disease control against Burkholdria induced disease, specifically in patients suffering from cystic fibrosis.<ref>PMID: 20390415</ref> |
== Structural highlights == | == Structural highlights == | ||
| - | <scene name='79/799592/ | + | Secondary structures of Obc1 include alpha helices, beta sheets, random coil, and turns. The most abundant <scene name='79/799592/Cartoon_secondary_structure/2'>secondary structure</scene> is alpha helices which are shaded pink, followed by beta sheets (yellow) and random coil (gray), with turns being the least abundant (purple). Obc1's <scene name='79/799592/Tertiary_structure/2'>tertiary structure</scene> consists of two domains, an N-domain that is shaded red and C-domain that is shaded grey. The C-domain is composed of two regions: A cap region and an alpha/beta hydrolase fold. A space-filling view of a protein shows a 3D representation of how much space the atoms take up in the protein. The <scene name='79/799592/Space-filling_view/2'>space-fill view</scene> of Obc1 shows that the atoms in this protein consume a considerable amount of space as there are no gaps in the protein. With very little room it is difficult for other molecules to move through Obc1. Obc1 is composed of equal, dispersed amounts of hydrophobic and hydrophilic patches as seen in the <scene name='79/799592/Hydrophobicity_view/2'>hydrophobicity view</scene>. The areas shaded in gray represent hydrophobic areas and areas shaded in purple represent hydrophilic areas. The <scene name='79/799592/Ligand/4'>ligand</scene> that interacts with Obc1 is glycerol. Important features of the ligand glycerol include that it is hydrophilic. This is demonstrated by the hydrogen bonds it creates in the active site. The <scene name='79/799592/Catalytic_triad/5'>catalytic triad</scene> helps the protein achieve its function by making Ser-935 act in a nucleophilic attack to generate a tetrahedral intermediate, which is the first step in producing oxalate. The catalytic triad consists of S935, D997, and H1069. Amino acids that make up the <scene name='79/799592/Active_site/3'>active site</scene> include S785, T786, P787, R856, H934, S936, F974, R999, D1061, D1067, S1070, and R1073. In Obc1, there are two subdomains that make up the <scene name='79/799592/Subdomains_in_c-domain/2'>C-domain</scene>. The first subdomain consists of Ser-740 to Gln 1106. The second subdomain consists of Arg-529 to Ala-739. The second subdomain forms a cap over a concave region formed by an alpha/beta hydrolase fold. In the image, the N-domain is shaded red, C-domain subdomain 1 is shaded teal, and the C-domain subdomain 2 is shaded green. In the active site, there are two <scene name='79/799592/Arginine_stabilization/2'>arginines</scene> that help stabilize the oxyanionic intermediate during the production of oxalate, Arg-856 and Arg-999. A <scene name='79/799592/Loop/2'>loop</scene> consisting of Ser-785-Thr-786-Pro-787 connects beta27 and aplha27 in the area of Ser-935. In this loop, Thr-786 protrudes from the loop and hydrogen bonds with a water molecule. |
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| + | == Kinetic Data == | ||
| + | Formation of CoA from the adduct is dependent on an enzyme. This was proven in an Obc1 activity assay that showed C6-CoA adduct that was produced by ObcA was stable could not be converted into CoA without being in the presense of Obc1. Also, when mutants R856K, R999K, and H934 were tested, the mutants showed decreased Kcat and Kcat/Km. Mutant R999K and the Obc wildtype had very similiar Kms, where H934A had a much higher Km and R856K and the lowest Km of the four. These results show that the positive charge on R999 and R856 play a critical role for catalysis. | ||
</StructureSection> | </StructureSection> | ||
== References == | == References == | ||
<references/> | <references/> | ||
Current revision
| This Sandbox is Reserved from October 22, 2018 through April 30, 2019 for use in the course Biochemistry taught by Bonnie Hall at the Grand View University, Des Moines, IA USA. This reservation includes Sandbox Reserved 1456 through Sandbox Reserved 1470. |
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Structure of Glycerol-bound Obc1
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References
- ↑ Oh J, Hwang I, Rhee S. Structural Insights into an Oxalate-producing Serine Hydrolase with an Unusual Oxyanion Hole and Additional Lyase Activity. J Biol Chem. 2016 Jul 15;291(29):15185-95. doi: 10.1074/jbc.M116.727180. Epub, 2016 May 24. PMID:27226606 doi:http://dx.doi.org/10.1074/jbc.M116.727180
- ↑ Leitao JH, Sousa SA, Ferreira AS, Ramos CG, Silva IN, Moreira LM. Pathogenicity, virulence factors, and strategies to fight against Burkholderia cepacia complex pathogens and related species. Appl Microbiol Biotechnol. 2010 Jun;87(1):31-40. doi: 10.1007/s00253-010-2528-0. PMID:20390415 doi:http://dx.doi.org/10.1007/s00253-010-2528-0
