Journal:JBSD:6
From Proteopedia
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<b>Molecular Tour</b><br> | <b>Molecular Tour</b><br> | ||
| - | Ureases are enzymes that break down urea to carbon dioxide and ammonia, and they are one of the very few enzymes that have nickel in their active sites. Genetic and biochemical studies have shown that most of these enzymes require accessory proteins for the correct assembly of the nickel in their metallocenters. <scene name='Journal:JBSD:6/Cv/4'>UreA</scene> (<span style="color:lime;background-color:black;font-weight:bold;">green</span>), <scene name='Journal:JBSD:6/Cv/5'>UreB</scene> (<font color='red'><b>red</b></font>), and <scene name='Journal:JBSD:6/Cv/6'>UreC</scene> (<font color='darkmagenta'><b>darkmagenta</b></font>) form the <scene name='Journal:JBSD:6/Cv/7'>(UreABC)3 apoprotein</scene>. Studies of ''Klebsiella aerogenes'' urease activation pathway revealed that three accessory proteins – UreD, UreF, UreG – are essential for the production of a functional urease. In this work we submitted structural models of such proteins to macromolecular docking calculations with ''K. aerogenes'' urease, which lead to a putative structure for the urease activation complex. | + | Ureases are enzymes that break down urea to carbon dioxide and ammonia, and they are one of the very few enzymes that have nickel in their active sites. Genetic and biochemical studies have shown that most of these enzymes require accessory proteins for the correct assembly of the nickel in their metallocenters. <scene name='Journal:JBSD:6/Cv/4'>UreA</scene> (<span style="color:lime;background-color:black;font-weight:bold;">green</span>), <scene name='Journal:JBSD:6/Cv/5'>UreB</scene> (<font color='red'><b>red</b></font>), and <scene name='Journal:JBSD:6/Cv/6'>UreC</scene> (<font color='darkmagenta'><b>darkmagenta</b></font>) form the <scene name='Journal:JBSD:6/Cv/7'>(UreABC)3 apoprotein</scene>. The trimeric representation |
| + | considers UreABC as a functional unit. Studies of ''Klebsiella aerogenes'' urease activation pathway revealed that three accessory proteins – UreD, UreF, UreG – are essential for the production of a functional urease. These proteins sequentially bind to form the <scene name='Journal:JBSD:6/Cv/8'>(UreABC-UreD)3</scene>, (UreABC-UreDF)3, and (UreABC-UreDFG)3 activation complexes. In this work we submitted structural models of such proteins to macromolecular docking calculations with ''K. aerogenes'' urease, which lead to a putative structure for the urease activation complex. | ||
The presented model for this complex is the first to include UreG and to use the current data on the activation pathway to guide the docking calculations. Despite the urease activation process being far more complex, our results are likely to expand the current knowledge on this essential step for proper ureolytic activity, aiding further high resolution studies of this macromolecular assembly by providing a 3D scaffold to work upon. | The presented model for this complex is the first to include UreG and to use the current data on the activation pathway to guide the docking calculations. Despite the urease activation process being far more complex, our results are likely to expand the current knowledge on this essential step for proper ureolytic activity, aiding further high resolution studies of this macromolecular assembly by providing a 3D scaffold to work upon. | ||
</StructureSection> | </StructureSection> | ||
Revision as of 07:48, 17 July 2012
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- ↑ REF
This page complements a publication in scientific journals and is one of the Proteopedia's Interactive 3D Complement pages. For aditional details please see I3DC.
