Difference between revisions of "Team:New York City/Design"

 
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{{New_York_City}}
 
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                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Description">Description</a>
 
                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Description">Description</a>
 
                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Design">Design</a>
 
                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Design">Design</a>
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                                <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Model">Model</a>
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                                <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/InterLab">InterLab</a>
 
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                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/InterLab">InterLab</a>
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                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Notebook">Notebook</a>
 
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                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Integrated_Practices">Integrated
 
                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Integrated_Practices">Integrated
 
                                     Practices</a>
 
                                     Practices</a>
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                                <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Public_Engagement">Public
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                                    Engagement</a>
 
                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Collaborations">Collaborations</a>
 
                                 <a class="dropdown-item" href="https://2018.igem.org/Team:New_York_City/Collaborations">Collaborations</a>
 
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     <p class="lead">Our goal is to create a viable short term cure for Huntington's Disease by developing an RNA strand displacement technology that consists of a chaperone strand, a correct HTT mRNA strand, and a fluorescent reporter. The computational aspect of our project uses the program Vienna to fold and create various models of diseased Huntington's mRNA strands with varying numbers of CAG repeats. All the models will be compared to find a common hairpin loop to target. The structure of the toehold of our chaperone strand will be based upon the universal hairpin loop, and the entire strand itself will be mostly complementary to a synthetic-mRNA strand that codes for the HTT gene followed by a fluorophore. RNA strand displacement will be able to readily occur as the toehold of the chaperone has a small RNAi like sequence that is specific to the hairpin loop of the diseased mRNA.</p>
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     <p class="lead">Our goal is to create a cure for Huntington’s Disease (HD) by developing a RNA strand displacement technology that can target and block mutated huntingtin (HTT) mRNA strands and replace them with corrected strands for proper protein synthesis. Since an increased number of CAG repeats in the HTT gene coding for the polyglutamine tail characteristic of HD contributes to neurotoxicity in this disease, we decided to find a cure for HD in the level of RNA. Last year, we designed a modified plasmid consisting of a chaperone strand and a corrected HTT mRNA strand using the software programs Vienna and mFold. The chaperone strand contains a small RNAi like toehold sequence designed to bind to the hairpin loop sequence of mutated HTT mRNA strands. Upon binding of the chaperone strand to the mutated mRNA strand, the corrected HTT mRNA strand would be released into the cytoplasm for proper protein synthesis.</p>
 
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     <p class="lead">Once these complexes have been developed, the wet-lab team will come into play. Several types of diseased HTT DNA sequences, along with a sequence coding for another fluorophore, will be cloned into plasmids and then into E.coli. Afterwards, our complexes will be transfected into the E.coli. Over time, we should be able to observe the increasing presence of the fluorescent protein on the synthetic-mRNA strand of the HTT gene than the fluorophore of the diseased mRNA, which will prove that the RNA strand displacement has occurred. We will also further legitimize our findings by establishing negative and positive controls to show that the only reason for the changes in presence of the two fluorophores is due to the RNA strand displacement.</p>
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     <p class="lead">After developing this modified plasmid, we looked into in vitro models to test the efficacy of our RNA strand displacement technology. Our literature review into research involving HD cell lines revealed that not much is known about the role of normal, endogenous HTT protein in non-neuronal cells. Therefore, we decided to initially test the efficacy of our modified plasmid in HeLa cell lines modified to express a polyglutamine tail adhered to cyan fluorescent protein (CFP). After maintaining the HeLa/polyQ-mCFP cell line, we transfected the cells at two different concentrations, performed cell lysis, followed by western blotting. Since the mutated HTT protein would be too large to blot, we used a probe for CFP as a proxy for the quantity of HTT protein in cells. The western blot was used to determine whether transfecting cells at increasing concentrations of the modified plasmid would result in a decreased quantities of HTT protein.</p>
 
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Latest revision as of 01:38, 17 October 2018

Project Design

Our goal is to create a cure for Huntington’s Disease (HD) by developing a RNA strand displacement technology that can target and block mutated huntingtin (HTT) mRNA strands and replace them with corrected strands for proper protein synthesis. Since an increased number of CAG repeats in the HTT gene coding for the polyglutamine tail characteristic of HD contributes to neurotoxicity in this disease, we decided to find a cure for HD in the level of RNA. Last year, we designed a modified plasmid consisting of a chaperone strand and a corrected HTT mRNA strand using the software programs Vienna and mFold. The chaperone strand contains a small RNAi like toehold sequence designed to bind to the hairpin loop sequence of mutated HTT mRNA strands. Upon binding of the chaperone strand to the mutated mRNA strand, the corrected HTT mRNA strand would be released into the cytoplasm for proper protein synthesis.

After developing this modified plasmid, we looked into in vitro models to test the efficacy of our RNA strand displacement technology. Our literature review into research involving HD cell lines revealed that not much is known about the role of normal, endogenous HTT protein in non-neuronal cells. Therefore, we decided to initially test the efficacy of our modified plasmid in HeLa cell lines modified to express a polyglutamine tail adhered to cyan fluorescent protein (CFP). After maintaining the HeLa/polyQ-mCFP cell line, we transfected the cells at two different concentrations, performed cell lysis, followed by western blotting. Since the mutated HTT protein would be too large to blot, we used a probe for CFP as a proxy for the quantity of HTT protein in cells. The western blot was used to determine whether transfecting cells at increasing concentrations of the modified plasmid would result in a decreased quantities of HTT protein.