Team:UCSF/Project
From 2012.igem.org
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#mission {width: 500px; float:left; background-color: #F5F5F5; margin-left:8px; padding: 10px; margin-top:8px;} | #mission {width: 500px; float:left; background-color: #F5F5F5; margin-left:8px; padding: 10px; margin-top:8px;} | ||
#opensource {width:306px; float:left; background-color: #F5F5F5; margin-left:8px; padding: 10px; margin-top:8px;} | #opensource {width:306px; float:left; background-color: #F5F5F5; margin-left:8px; padding: 10px; margin-top:8px;} | ||
- | #rightcontent {width:925px; background-color: # | + | #rightcontent {width:925px; background-color: #FFFFFF; margin-left: 8px; margin-top:10px;} |
#photos {width:155px; float:left; background-color: #F5F5F5; margin-left: 8px; margin-top:10px;} | #photos {width:155px; float:left; background-color: #F5F5F5; margin-left: 8px; margin-top:10px;} | ||
#description{width:450px; height:110px;float:left; background-color: #F5F5F5; margin-left: 8px; margin-top:10px;} | #description{width:450px; height:110px;float:left; background-color: #F5F5F5; margin-left: 8px; margin-top:10px;} | ||
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- | <b | + | <b>We propose that instead of using one organism or strain to accomplish a task, it would be more efficient to get several strains to work together. The ability to "tune" the population ratios of the various symbiotic strains in order to maximize efficiency would also be extremely useful - especially in industrial situations. </b> <br> |
- | <img align="center" style="margin-bottom: | + | <img align="center" style="margin-bottom:40px; width: 300px; margin-top:20px; padding:2; margin-left:155px;" src="https://dl.dropbox.com/u/24404809/iGEM%202012/igem%202012%20website%20photos/Background/SplitPathway2.jpg"> |
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- | <regulartext>We are taking three different synthetic approaches to study tunable symbiosis. In the first, we use a model pathway (violacein production) to see if cells can work together to more efficiently produce a product. In the second two approaches we look at ways in which cells can be tuned to achieve ideal population ratios.</regulartext> <p> | + | <regulartext><center><h4>Summary: We are taking three different synthetic approaches to study tunable symbiosis. In the first, we use a model pathway (violacein production) to see if cells can work together to more efficiently produce a product. In the second two approaches we look at ways in which cells can be tuned to achieve ideal population ratios.</center></regulartext> <p> |
<img align="center" style="margin-bottom:20px; width: 500px; margin-top:20px; padding:2; margin-left:205px;" src="https://dl.dropbox.com/u/24404809/iGEM%202012/igem%202012%20website%20photos/Background/All%20Projects%20Slide.jpg"> | <img align="center" style="margin-bottom:20px; width: 500px; margin-top:20px; padding:2; margin-left:205px;" src="https://dl.dropbox.com/u/24404809/iGEM%202012/igem%202012%20website%20photos/Background/All%20Projects%20Slide.jpg"> | ||
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Latest revision as of 23:51, 3 October 2012
Summary: We are taking three different synthetic approaches to study tunable symbiosis. In the first, we use a model pathway (violacein production) to see if cells can work together to more efficiently produce a product. In the second two approaches we look at ways in which cells can be tuned to achieve ideal population ratios.