Silver: Synthetic Biology

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Synthetic biology is a new discipline focused on design and construction of synthetic genomes and programmed cells through cycles of computer modeling, assembly, and testing (not necessarily in that order).  The goal of synthetic biology (at least in our lab) is to both enhance our understanding of biology and to develop tools for constructing organisms with defined functions.   Current projects focus on using the added complexity of eukaryyotes in our designs and include the construction of a cellular oscillator based on nuclear/cytoplasmic localization and a lifespan counter for analyzing cellular aging.
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Synthetic biology is a new discipline focused on design and construction of synthetic genomes and programmed cells through cycles of computer modeling, assembly, and testing (not necessarily in that order).  The goal of synthetic biology (at least in our lab) is to both enhance our understanding of biology and to develop tools for constructing organisms with defined functions. In the long term, we hope to develop a set of parts and principles for building eukaryotic cells that might act as novel sensors or memory cells.  We also hope to use standardized parts to build novel proteins that could have therapeutic value.
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Current projects focus on using the added complexity of eukaryyotes in our designs and include the construction of standardized parts for desginer proteins with well-defined functions, a cellular oscillator based on nuclear/cytoplasmic localization and a lifespan counter for analyzing cellular aging.

Revision as of 05:52, 19 October 2005

Synthetic biology is a new discipline focused on design and construction of synthetic genomes and programmed cells through cycles of computer modeling, assembly, and testing (not necessarily in that order). The goal of synthetic biology (at least in our lab) is to both enhance our understanding of biology and to develop tools for constructing organisms with defined functions. In the long term, we hope to develop a set of parts and principles for building eukaryotic cells that might act as novel sensors or memory cells. We also hope to use standardized parts to build novel proteins that could have therapeutic value.

Current projects focus on using the added complexity of eukaryyotes in our designs and include the construction of standardized parts for desginer proteins with well-defined functions, a cellular oscillator based on nuclear/cytoplasmic localization and a lifespan counter for analyzing cellular aging.

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