Team:Caltech

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<br><center>[[Team:Caltech| <font face="verdana" style="color:#BB4400"> '''Home''' </font>]] <br><br>
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<div><p>Hi! We are the Caltech 2011 iGEM Team. We are interested in bioremediation of endocrine disruptors or organic pollutants :)</p><br/>
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EDCs (Endocrine Disrupting Chemicals) are substances which detrimentally effect the development and reproduction of wild organisms. To remedy that, the Caltech iGEM team hopes to engineer bacteria which can sense and degrade DDT, estrogen, bisphenol A, and nonylphenol to less toxic forms. Compared to more traditional forms of pollution removal, bioremediation would be relatively cheaper and less disruptive to the environment. However, a successful project must make sure that the bacteria used for remediation do not act as pollutants or introduce toxic byproducts into the environment.<br/><br/>
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To start, we hope to create genetic elements that initiate the production of signaling proteins upon exposure to endocrine disrupting chemicals and to identify enzymes that can degrade endocrine disruptors. Eventually, these components will be combined in a signal transduction system that can be used to detect and remove endocrine disruptors from bodies of water.<br/><br/>
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Update- We received a gold medal at the iGEM Americas Regional Jamborees!
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The detection pathway triggered by the binding of an endocrine disruptor to a receptor can be used to activate the production of the degradation enzymes. In our testing stages, the receptor will activate a visual reporter pathway instead. Our plan is to alter the human receptor-activation pathway for estrogen to fit our project.
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We're looking forward to the World Jamboree in Boston!
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When the human estrogen receptor binds to estrogen, it dimerizes into a construct that can bind to a responsive element on human DNA, triggering transcription. This receptor has been tested in E. coli in previous work, but has also shown a high toxicity to the organism. We will alter the receptor using protein tags such as maltose, green fluorescent protein, and ubiquitin, as these have been demonstrated to help the estrogen receptor fold and to minimize its toxicity in E. coli. Since the estrogen receptor shows low-specificity binding to general endocrine disruptors, we can use site-directed mutagenesis to increase its specificity to our target chemicals DDT, ethinyl estradiol, BPA, and nonylphenol.<br/><br/>
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[[File:Pac_Man_BPA.jpg|left]]
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<p> We are the Caltech 2011 iGEM Team. We are interested in the bioremediation of endocrine-disrupting chemicals in bodies of water.</p><br/>
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<p>Endocrine-disrupting chemicals are substances which detrimentally effect the development and reproduction of wild organisms. These chemicals mimic natural biological estrogen in their interaction with animal estrogen receptors. This interaction has negative effects for reproductive processes of several species of fish and birds. To remedy that, the Caltech iGEM team hopes to engineer bacteria which can degrade DDT, synthetic estrogen (17a-ethynylestradiol), bisphenol A, and nonylphenol to less toxic forms. Compared to traditional forms of pollution removal, bioremediation is relatively cheaper and less disruptive to the environment. However, a successful project must make sure that the bacteria used for remediation do not act as pollutants or introduce toxic byproducts into the environment.</p><br/>[[File:Pac_Man_BPA.jpg|right]]
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There are several standard methods of detection for endocrine disruptors to establish which bodies of water require bioremediation. One method involves examination of the local fish population for signs of male feminization, indicated by male expression of vitellogenin, a protein used in egg yolk. Another test developed by the EPA involves using human breast cancer cells containing genes that produce luciferase when an endocrine-disrupting chemical is detected. Once these tests establish the presence of a chemical that can interfere with estrogen receptors, we can use a degradation pathway to remove these chemicals from the body of water.<br/><br/>  
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We have explored many pathways for degradation. We created a genetic construct for E. coli containing the BisdA and BisdB proteins previously shown to degrade BPA and explored the efficacy of degradation using cell lysates. In addition, we constructed a gene optimized for producing the DDT dehydrochlorinase enzyme and characterized its efficacy at degrading our target chemicals. To do this, we mixed cell lysates of E. coli containing constructs designed to produce these degradation enzymes with our target endocrine disruptors, and then analyzed the results of these reactions using HPLC.<br/><br/>
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In addition to testing previously discovered degradation enzymes, we conducted a gene fishing experiment using samples from the L.A. river. We selected the L.A. river because it has previously been shown to contain a high level of plastic pollutants, so it is possible that some selection has already occurred in the river for bacteria that can degrade plastics. We grew up these samples in minimal media containing our target chemicals as the sole carbon source, and transferred each sample to new minimal media in a progressive selection process. When we plated the final transfers on LB plates, we saw colony growth, indicating that some bacteria were able to survive using endocrine disruptors as a carbon source and thus have a method for degrading these chemicals.<br/><br/>
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To investigate the feasibility of using E. coli genetic constructs to perform a reaction on large bodies of water we also prepared biofilms of E. coli on glass beads and prepared columns to test the concept using beta-galactosidase to degrade X-gal. In addition, we visited three different water treatment plants to learn about the methods they used for removing different pollutants from water and how bioremediation can integrate into these systems.<br/><br/>
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Multiple pathways for degradation are being explored. We hope to optimize previously established degradation pathways for DDT and BPA as well as search for novel pathways for all four chemicals. Prior research has indicated that there exist proteins can degrade DDT; however, these are poorly characterized and have not been successfully introduced into ''E. coli''. Luckily, enzymes and constructs which degrade BPA have established functionality in E. coli and are in the parts registry. We base our experiment upon these results by searching for new genes in LA river bacteria that can degrade endocrine disruptors and exploring the abilities of the aforementioned genes.
 
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Latest revision as of 01:05, 29 October 2011


Caltech iGEM 2011



Home

Project

Data

Parts

Team

Notebook

Biosafety

Human Impact

References

Support

Caltech logo watermark.png

Update- We received a gold medal at the iGEM Americas Regional Jamborees!
We're looking forward to the World Jamboree in Boston!

We are the Caltech 2011 iGEM Team. We are interested in the bioremediation of endocrine-disrupting chemicals in bodies of water.


Endocrine-disrupting chemicals are substances which detrimentally effect the development and reproduction of wild organisms. These chemicals mimic natural biological estrogen in their interaction with animal estrogen receptors. This interaction has negative effects for reproductive processes of several species of fish and birds. To remedy that, the Caltech iGEM team hopes to engineer bacteria which can degrade DDT, synthetic estrogen (17a-ethynylestradiol), bisphenol A, and nonylphenol to less toxic forms. Compared to traditional forms of pollution removal, bioremediation is relatively cheaper and less disruptive to the environment. However, a successful project must make sure that the bacteria used for remediation do not act as pollutants or introduce toxic byproducts into the environment.


Pac Man BPA.jpg

There are several standard methods of detection for endocrine disruptors to establish which bodies of water require bioremediation. One method involves examination of the local fish population for signs of male feminization, indicated by male expression of vitellogenin, a protein used in egg yolk. Another test developed by the EPA involves using human breast cancer cells containing genes that produce luciferase when an endocrine-disrupting chemical is detected. Once these tests establish the presence of a chemical that can interfere with estrogen receptors, we can use a degradation pathway to remove these chemicals from the body of water.

We have explored many pathways for degradation. We created a genetic construct for E. coli containing the BisdA and BisdB proteins previously shown to degrade BPA and explored the efficacy of degradation using cell lysates. In addition, we constructed a gene optimized for producing the DDT dehydrochlorinase enzyme and characterized its efficacy at degrading our target chemicals. To do this, we mixed cell lysates of E. coli containing constructs designed to produce these degradation enzymes with our target endocrine disruptors, and then analyzed the results of these reactions using HPLC.

In addition to testing previously discovered degradation enzymes, we conducted a gene fishing experiment using samples from the L.A. river. We selected the L.A. river because it has previously been shown to contain a high level of plastic pollutants, so it is possible that some selection has already occurred in the river for bacteria that can degrade plastics. We grew up these samples in minimal media containing our target chemicals as the sole carbon source, and transferred each sample to new minimal media in a progressive selection process. When we plated the final transfers on LB plates, we saw colony growth, indicating that some bacteria were able to survive using endocrine disruptors as a carbon source and thus have a method for degrading these chemicals.

To investigate the feasibility of using E. coli genetic constructs to perform a reaction on large bodies of water we also prepared biofilms of E. coli on glass beads and prepared columns to test the concept using beta-galactosidase to degrade X-gal. In addition, we visited three different water treatment plants to learn about the methods they used for removing different pollutants from water and how bioremediation can integrate into these systems.



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