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Team:Alberta/Project/Bioinformatics
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| + | <style type="text/css"> | ||
| + | .b1f, .b2f, .b3f, .b4f{font-size:1px; overflow:hidden; display:block;} | ||
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| + | </style> | ||
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| + | <!-- adjust table width, main background and padding between cells and edge of background --> | ||
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| + | <div class="Outreach"> | ||
| + | <div style="height: 400; background:#FFFFFF; colorou line-height:100% padding: 3px 0px;"> | ||
| + | <h1>Why build a minimal genome?</h1> | ||
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| + | <P>Genomes are complex! Determining how simplified a genome can become enriches our understanding the function and interactions of cellular components. Simplified cells can be used as a well characterized chasses for synthetic biology. Moreover, a simplified cell can be used to study cellular processes in a controlled, characterized genetic background. Finally, developing a minimal genome requires us to develop and optimize molecular methods of genome assembly. These methods can be then applied to other high through put biology. </P> | ||
Revision as of 02:42, 11 September 2009
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Why build a minimal genome?Genomes are complex! Determining how simplified a genome can become enriches our understanding the function and interactions of cellular components. Simplified cells can be used as a well characterized chasses for synthetic biology. Moreover, a simplified cell can be used to study cellular processes in a controlled, characterized genetic background. Finally, developing a minimal genome requires us to develop and optimize molecular methods of genome assembly. These methods can be then applied to other high through put biology. |
