Team:PennState/Project
From 2008.igem.org
m |
|||
Line 159: | Line 159: | ||
<td valign="top"> | <td valign="top"> | ||
<!-- ALL PAGE CONTENT GOES HERE: between the <td> and </td> tags! --> | <!-- ALL PAGE CONTENT GOES HERE: between the <td> and </td> tags! --> | ||
- | < | + | <tr> |
- | <table style="padding-left: 0"> <!-- change padding to re-indent this content segment --> | + | <td colspan="2" style="padding-top:30px; padding-right:30px" valign="top" width="45%"><span style="font-size: 14pt">Diauxie Elimination by Xylose Inducible Promoters </span> |
+ | <hr /> | ||
+ | <p><img src="picture here" alt="[img]" style="float:left; margin:5px;"/>Microorganisms typically preferentially utilize glucose over other sugar carbon sources such as xylose. This is largely regulated through control of gene expression based on the response of regulatory elements to sugars available to the cell. In <em>E. coli</em>, the xylose metabolism operon is controlled by both the xylose-inducible XylR activator protein and the cAMP receptor protein (CRP). In this project we attempt to eliminate glucose control over xylose-inducible gene expression in <em>E. coli</em> by altering the natural transcriptional control region of the xylose operon. Designs constructed and tested include scrambling the CRP binding site, increasing the strength of the xyl promoter, and overexpressing XylR. Xylose-inducible gene expression that functions independently of glucose regulation provides a useful approach to improving microbial utilization of biomass feedstocks containing mixtures of glucose and xylose.</p> | ||
+ | </td> | ||
+ | </tr> | ||
+ | |||
+ | <table style="padding-left: 0"> <!-- change padding to re-indent this content segment --> | ||
<tr><td style="padding-top:30px; padding-right:30px" valign="top" width="90%"><span style="font-size:14pt">Hormone Prescreening <em>E. coli</em></span> | <tr><td style="padding-top:30px; padding-right:30px" valign="top" width="90%"><span style="font-size:14pt">Hormone Prescreening <em>E. coli</em></span> | ||
<hr /> | <hr /> | ||
Line 168: | Line 174: | ||
<table> <!-- this table separates content into column-like quadrants --> | <table> <!-- this table separates content into column-like quadrants --> | ||
<tr> | <tr> | ||
- | <td style="padding-top:30px; padding-right:30px" valign="top" width="45%"><span style="font-size: 14pt"> | + | <td style="padding-top:30px; padding-right:30px" valign="top" width="45%"><span style="font-size: 14pt">BPA Biosensor</span> |
<hr /> | <hr /> | ||
<img src="http://upload.wikimedia.org/wikipedia/en/8/87/PPARg.png" alt="[img]" style="float:left; margin:5px;width: 30%"/> | <img src="http://upload.wikimedia.org/wikipedia/en/8/87/PPARg.png" alt="[img]" style="float:left; margin:5px;width: 30%"/> | ||
- | + | <p>This <em>BPA Biosensor</em> project uses altered growth conditions so that the entire <acronym title="Human Peroxisome Proliferator Activated Receptor subtype Alpha">hPPARα</acronym> protein is successfully expressed in <em>E. coli</em> and used to transcriptionally report for the presence of phthalates. Rather than changing the receptor and possibly losing its usefulness, we are chemically optimizing the cell environment. Check out our Overview to find out how. | |
- | + | ||
- | + | ||
- | <p>This <em> | + | |
</p></td> | </p></td> | ||
<td style="padding-top:30px; padding-right:30px" valign="top" width="45%"><span style="font-size:18px">Nuclear Fusion</span> | <td style="padding-top:30px; padding-right:30px" valign="top" width="45%"><span style="font-size:18px">Nuclear Fusion</span> | ||
Line 180: | Line 183: | ||
<img src="https://static.igem.org/mediawiki/2008/d/d9/PSU2008iGEM_BPAimage.png" alt="[img]" style="float:left; margin:5px;width: 30%;"/> | <img src="https://static.igem.org/mediawiki/2008/d/d9/PSU2008iGEM_BPAimage.png" alt="[img]" style="float:left; margin:5px;width: 30%;"/> | ||
- | <p> The <em>Nuclear Fusion</em> project | + | <p> The <em>Nuclear Fusion</em> project involves a plasmid construct very generously donated to our iGEM team from David W. Wood, Department of Chemical Engineering at Princeton University. Research in their lab has constructed a biosensor containing just the ligand binding domain (LBD) of the estrogen receptor (ER). Our plan for this project is to work on the sensitivity of the biosensor in hopes of using this for water prescreens, similar to the <em>Smart Fold Reporter</em> project. The sensitivity will be focused for BPA which has a very different conformation than the natural agonist of the ER system (estradiol). This difference causes BPA to bind weakly but still disturbs normal ER function.</p><p>We intend to analyze the LBD of ER and perform directed evolution to increase BPA sensitivity. During directed evolution, certain regions of the ER LBD would be targeted for random mutagenesis providing a library of mutants in the trillions. The mutant library would be induced with BPA and the best growing colony would be selected, tested, and mutated for further sensitivity.</p> |
- | + | ||
- | + | ||
</p></td> | </p></td> | ||
</tr> | </tr> | ||
- | + | ||
- | + | ||
- | + | ||
- | + | ||
- | + | ||
- | + | ||
- | + | ||
</td> | </td> |
Revision as of 17:17, 25 October 2008
Home | The Team | The Project | Parts | Modeling | Notebook |
Hormone BiosensorsDiauxie Elimination |
||
Diauxie Elimination by Xylose Inducible Promoters
Microorganisms typically preferentially utilize glucose over other sugar carbon sources such as xylose. This is largely regulated through control of gene expression based on the response of regulatory elements to sugars available to the cell. In E. coli, the xylose metabolism operon is controlled by both the xylose-inducible XylR activator protein and the cAMP receptor protein (CRP). In this project we attempt to eliminate glucose control over xylose-inducible gene expression in E. coli by altering the natural transcriptional control region of the xylose operon. Designs constructed and tested include scrambling the CRP binding site, increasing the strength of the xyl promoter, and overexpressing XylR. Xylose-inducible gene expression that functions independently of glucose regulation provides a useful approach to improving microbial utilization of biomass feedstocks containing mixtures of glucose and xylose. |
Hormone Prescreening E. coli
Two of our projects aim to construct biosensors which will ultimately serve as a water prescreening tool. The focus of these biosensors will be to detect phthalate compounds utilizing the Peroxisome Proliferator Activated Receptor (PPAR) and detecting Bisphenol A (BPA) by the Estrogen Receptor (ER). Recent studies show phthalates cause negative health effects such as damage to the liver and kidneys and birth defects in rodents. Phthalates are introduced into our environment by their use as plastisizers for materials ranging from polyvinyl chloride to nail polish to small toys. BPA is also found in plastics but instead it is used for the synthesis of hard plastics. Once BPA enters the human body it is confused for estrogen and parallels the effects of estrogen after attaching to the ligand binding region of the ER. Analytical detection methods for water contamination are compound specific and very costly. Having a simple and cheap tool to screen for phthalates or BPA as a general class of compounds would eliminate the cost and time involved in detection. We are using two of the natural human nuclear hormone receptor proteins that recognize a large class of ligands, and attempting to express them heterologously in E. Coli. The complexity of this mammalian protein makes it difficult to express it in a prokaryote. We have two different strategies to express and use these receptors to detect compounds in E. Coli.
|