Team:Heidelberg/Project/Summary
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==miTuner== | ==miTuner== | ||
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- | We have developed a novel method for miRNA-based gene expression tuning in mammalian cells. We show that the miTUNER method allows tuning of protein expression in fine intervals in vivo and in vitro. This enables us to create libraries of protein expression vectors with different | + | We have developed a novel method for miRNA-based gene expression tuning in mammalian cells. We show that the miTUNER method allows tuning of protein expression in fine intervals <i>in vivo</i> and <i>in vitro</i>. This enables us to create libraries of protein expression vectors with different strengths without exchanging the promoter. This is highly useful for the usage of certain promoters for an optimal protein expression. |
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- | We furthermore demonstrate the ability of the miTuner approach for off-targeting respectively for partial, selective down-regulation of protein expression in vivo and in vitro. The potential of miTuner for on-targeting respectively partial, selective up-regulation has been proven in vitro, in vivo measurements are currently undertaken and will be presented at the Jamboree. To | + | We furthermore demonstrate the ability of the miTuner approach for off-targeting respectively for partial, selective down-regulation of protein expression <i>in vivo</i> and <i>in vitro</i>. The potential of miTuner for on-targeting respectively partial, selective up-regulation has been proven <i>in vitro</i>, <i>in vivo</i> measurements are currently undertaken and will be presented at the Jamboree. To the best of our knowledge, this work is the first demonstration of a miRNA-based gene expression tuner, and it is moreover the first implementation of on-targeting with miRNA-based gene expression control systems.<br /> |
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- | + | An [[Media:miTuner_RFC.pdf|RFC]] describing the miTUNER method has been written (miTuner - a kit for microRNA based gene expression tuning in mammalian cells). Moreover, we describe a new measurement standard (miMeasure – a standard for miRNA binding site characterization in mammalian cells) in a second [[Media:RFC_miMeasure.pdf|RFC]]. We are currently waiting for the assignment of numbers for the submission of these two RFCs.<br /> | |
- | ==Capsid shuffling==<br /> | + | ==Capsid shuffling== |
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We have developed a standardized and fast approach towards the creation of AAV-based. We adopted two established methods for the shuffling of capsid genes – homology based shuffling by DNaseI digestion and self-primed PCR. Additionally we introduce ViroBytes, a random assembly protocol based on rationally designed capsid parts. These methods allow for the creation of libraries of randomized synthetic viruses and the consequent screening for novel viruses with improved efficiency and tissue specifity. We have achieved exceptionally selective tissue-specific targeting in vitro and in vivo with hepatocyte specific delivery vectors.<br /> | We have developed a standardized and fast approach towards the creation of AAV-based. We adopted two established methods for the shuffling of capsid genes – homology based shuffling by DNaseI digestion and self-primed PCR. Additionally we introduce ViroBytes, a random assembly protocol based on rationally designed capsid parts. These methods allow for the creation of libraries of randomized synthetic viruses and the consequent screening for novel viruses with improved efficiency and tissue specifity. We have achieved exceptionally selective tissue-specific targeting in vitro and in vivo with hepatocyte specific delivery vectors.<br /> | ||
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- | ==Modeling==<br /> | + | |
+ | ==Modeling== | ||
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Our suite of experimental contributions is complement by a powerful range of, accessible through the miBEAT GUI. This tool combines and connects the output of different models and scripts and then generates a suitable miTuner construct that expresses the gene of interest, miGENE, up to the desired level. miBEAT consists of three subparts; miRockdown, miBS designer and mUTING.<br /> | Our suite of experimental contributions is complement by a powerful range of, accessible through the miBEAT GUI. This tool combines and connects the output of different models and scripts and then generates a suitable miTuner construct that expresses the gene of interest, miGENE, up to the desired level. miBEAT consists of three subparts; miRockdown, miBS designer and mUTING.<br /> | ||
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The Fuzzy Logic Model is combining the strength of intuitive integration of prior knowledge with a sophisticated Global Genetic optimization Algorithm.<br /><br /> | The Fuzzy Logic Model is combining the strength of intuitive integration of prior knowledge with a sophisticated Global Genetic optimization Algorithm.<br /><br /> | ||
- | ==Outlook==<br /> | + | |
+ | ==Outlook== | ||
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We see great potential in the combined usage of synthetic promoters (as proposed by the Heidelberg iGEM team 2009), with miRNA-based post-transcriptional gene expression control and with cell-specific gene delivery. The 3-fold usage of selective gene expression control will allow for very tight coupling of gene expression to target cells, e.g. to cancer cells.<br /> | We see great potential in the combined usage of synthetic promoters (as proposed by the Heidelberg iGEM team 2009), with miRNA-based post-transcriptional gene expression control and with cell-specific gene delivery. The 3-fold usage of selective gene expression control will allow for very tight coupling of gene expression to target cells, e.g. to cancer cells.<br /> | ||
Moreover, the possibility of RNA-based logic gates provides an attractive option for the design and fine-tuning of synthetic networks. As we have demonstrated, miTuner allows for the usage of synthetic miRNAs. This opens up the perspective of engineering orthogonal networks which can be run in parallel to cellular calculation processes. | Moreover, the possibility of RNA-based logic gates provides an attractive option for the design and fine-tuning of synthetic networks. As we have demonstrated, miTuner allows for the usage of synthetic miRNAs. This opens up the perspective of engineering orthogonal networks which can be run in parallel to cellular calculation processes. |
Latest revision as of 03:58, 28 October 2010
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