Team:MIT projectContext
From 2010.igem.org
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- | In 2005, the <a href=" | + | In 2005, the <a href="https://2006.igem.org/UT_Austin_2005">UT Austin</a> team worked on a light-dependent bacterial printer. |
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- | In 2006 the McGill team attempted to use leucine zippers fused to split YFP to display on cells and cause the cells to adhere via the split YFP. | + | In 2006 the <a href="https://2006.igem.org/McGill_University_2006">McGill team</a> attempted to use leucine zippers fused to split YFP to display on cells and cause the cells to adhere via the split YFP.</li> |
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- | The 2009 Freiburg Bioware team used Fos/Jun for a 'programmable enzyme' using Fok-fused Fos/Jun as factor in DNA cleavage. | + | The <a href="https://2009.igem.org/Team:Freiburg_bioware/Project/FOS">2009 Freiburg Bioware team</a> used Fos/Jun for a 'programmable enzyme' using Fok-fused Fos/Jun as factor in DNA cleavage.</li> |
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- | Paris | + | The <a href="https://2009.igem.org/Team:Paris#top"> 2009 Paris team</a> attempted to use Jun/Fos as a snare; Jun on signal vesicle, Fos on membrane of receiving cell.</li> |
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- | This year, Duke's team is using Jun- and Fos-based synthetic leucine zippers for genetic regulation. | + | This year, <a href ="https://2010.igem.org/Team:Duke/Project#Leucine_Zippers">Duke's team </a>is using Jun- and Fos-based synthetic leucine zippers for genetic regulation.</li> |
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<li>Weiss and Sidhu. "Design and Evolution of Artificial M13 Coat Proteins". J Mol Bio. 2000.</li> | <li>Weiss and Sidhu. "Design and Evolution of Artificial M13 Coat Proteins". J Mol Bio. 2000.</li> | ||
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+ | <h4>Mammalian</h4> | ||
+ | <hr> | ||
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+ | <b>WORK FROM OTHER IGEM TEAMS</b> | ||
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+ | To our knowledge, no other iGEM team has worked with isolating mechanosensitive promoters and directed osteogenesis. | ||
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+ | <b>RELEVANT LITERATURE</b> | ||
+ | <ul> | ||
+ | <li>Kessler et al. "Fibroblasts in Mechanically Stressed Collagen Lattices Assume a “Synthetic” Phenotype". Journal of Biological Chemistry, 2001.</li> | ||
+ | <li>Silberman et al. "Shear stress-induced transcriptional regulation via hybrid promoters as a potential tool for promoting angiogenesis." Angiogenesis 2009. | ||
+ | <li>Peake and Haj. "Preliminary characterisation of mechanoresponsive regions of the c-fos promoter in bone cells." FEBS Letters, 2003. | ||
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+ | </ul> | ||
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Latest revision as of 19:53, 27 October 2010
project context |
UV ToggleWORK FROM OTHER IGEM TEAMS
RELEVANT LITERATURE
PhageWORK FROM OTHER IGEM TEAMS The following teams have used some component of our phage system previously. No other teams have used our method of polyphage with incorporated leucine zippers for polymerization (nor is it present in the literature).
RELEVANT LITERATURE
MammalianWORK FROM OTHER IGEM TEAMS To our knowledge, no other iGEM team has worked with isolating mechanosensitive promoters and directed osteogenesis. RELEVANT LITERATURE
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