Brown:iGEM proposal
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- | + | ==The iGEM competition: Where engineering meets biology== | |
This summer a cross-disciplinary team of Brown students will enter the MIT-based iGEM competition. The challenge is to design and implement a genetically engineered machine and students are set to draw on cross disciplinary expertice from biology, chemistry, computer science, engineering, mathematics, neuroscience and physics. | This summer a cross-disciplinary team of Brown students will enter the MIT-based iGEM competition. The challenge is to design and implement a genetically engineered machine and students are set to draw on cross disciplinary expertice from biology, chemistry, computer science, engineering, mathematics, neuroscience and physics. | ||
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http://static.flickr.com/51/110492293_8b13778e0d_m.jpg | http://static.flickr.com/51/110492293_8b13778e0d_m.jpg | ||
- | + | ==Synthetic Biology: A new field== | |
Science is constantly in a state of flux and the lines between the hard sciences are continually being redrawn. In the last decade, a revolution in genomics has shown us how the power of the human genome can be harnessed to find, understand and combat mutations that cause the human molecular machinery to breakdown (3). Synthetic Biology is a new field that allows us to not only decipher how DNA holds and translates information, but to use this understanding to produce novel biological machines to repair this damage, increase product yields(4) or deliver cancer drugs to targeted cells in the body(5). To this end, the field calls upon the knowledge and accomplishments of related disciplines. With the combined intellectual resources of the hard science, research in Synthetic Biology will be at the forefront of research in the next decade. | Science is constantly in a state of flux and the lines between the hard sciences are continually being redrawn. In the last decade, a revolution in genomics has shown us how the power of the human genome can be harnessed to find, understand and combat mutations that cause the human molecular machinery to breakdown (3). Synthetic Biology is a new field that allows us to not only decipher how DNA holds and translates information, but to use this understanding to produce novel biological machines to repair this damage, increase product yields(4) or deliver cancer drugs to targeted cells in the body(5). To this end, the field calls upon the knowledge and accomplishments of related disciplines. With the combined intellectual resources of the hard science, research in Synthetic Biology will be at the forefront of research in the next decade. | ||
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- | + | ==Student led research at Brown== | |
The main competition takes place over the summer with students spending their time designing novel engineered parts, modeling biochemical reactions and then implementing these designs in the lab. Here at Brown we already have support and offers of lab space from Gary Wessel in Molecular-Cellular Biology (MCB), Marc Tatar in Ecology and Evolutionary Biology (EEB) and offers from a number of faculty ranging from engineering, computer science and physics to join a multidisciplinary cross-campus faculty advisory board. This mentoring board will meet each week in order for students to report progress and to discuss ideas. The project gives students the opportunity to become directly involved with research at Brown. Previous entries in the iGEM competition have been published in Nature. [Engineering E.Coli to see light, 2005] | The main competition takes place over the summer with students spending their time designing novel engineered parts, modeling biochemical reactions and then implementing these designs in the lab. Here at Brown we already have support and offers of lab space from Gary Wessel in Molecular-Cellular Biology (MCB), Marc Tatar in Ecology and Evolutionary Biology (EEB) and offers from a number of faculty ranging from engineering, computer science and physics to join a multidisciplinary cross-campus faculty advisory board. This mentoring board will meet each week in order for students to report progress and to discuss ideas. The project gives students the opportunity to become directly involved with research at Brown. Previous entries in the iGEM competition have been published in Nature. [Engineering E.Coli to see light, 2005] | ||
- | + | ==Table of needs:== <br> | |
We hope to get departmental and university sponsorship to cover the following costs. <br> | We hope to get departmental and university sponsorship to cover the following costs. <br> | ||
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- | + | ==The future of iGEM==<br> | |
We hope that in coming years the Brown iGEM team can continue to grow, taking on new students and continuing research in synthetic biology. We hope to find industry sponsorship to support the competition. | We hope that in coming years the Brown iGEM team can continue to grow, taking on new students and continuing research in synthetic biology. We hope to find industry sponsorship to support the competition. | ||
- | + | ==Cross campus faculty support and mentoring==<br> | |
Marc Tatar - Associate Professor of Ecology and Evolutionary Biology <br> | Marc Tatar - Associate Professor of Ecology and Evolutionary Biology <br> | ||
Gary Wessel - Professor of Biology <br> | Gary Wessel - Professor of Biology <br> | ||
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<br> | <br> | ||
- | + | ==References== <br> | |
(1)Tom Knight 2005, iGEM: International Genetically Engineered Machine competition. <br>http://icampus.mit.edu/projects/iGem.shtml <br> | (1)Tom Knight 2005, iGEM: International Genetically Engineered Machine competition. <br>http://icampus.mit.edu/projects/iGem.shtml <br> | ||
(2)Chris Voigt 2005, Synthetic biology: Engineering Escherichia coli to see light, Nature 438, 441-442 (24 November 2005) <br> | (2)Chris Voigt 2005, Synthetic biology: Engineering Escherichia coli to see light, Nature 438, 441-442 (24 November 2005) <br> |
Revision as of 18:49, 12 March 2006
http://static.flickr.com/51/110487204_00eaddeb40.jpg
The iGEM competition: Where engineering meets biology
This summer a cross-disciplinary team of Brown students will enter the MIT-based iGEM competition. The challenge is to design and implement a genetically engineered machine and students are set to draw on cross disciplinary expertice from biology, chemistry, computer science, engineering, mathematics, neuroscience and physics.
http://static.flickr.com/51/110492293_8b13778e0d_m.jpg
Synthetic Biology: A new field
Science is constantly in a state of flux and the lines between the hard sciences are continually being redrawn. In the last decade, a revolution in genomics has shown us how the power of the human genome can be harnessed to find, understand and combat mutations that cause the human molecular machinery to breakdown (3). Synthetic Biology is a new field that allows us to not only decipher how DNA holds and translates information, but to use this understanding to produce novel biological machines to repair this damage, increase product yields(4) or deliver cancer drugs to targeted cells in the body(5). To this end, the field calls upon the knowledge and accomplishments of related disciplines. With the combined intellectual resources of the hard science, research in Synthetic Biology will be at the forefront of research in the next decade.
"Can simple biological systems be built from standard, interchangeable parts and operated in living cells? Or, is biology simply too complicated to be engineered in this way?" [Knight, 2005]
The International Genetically Engineered Machine competition (iGEM) was developed to address this question. The competition challenges students to design and implement a machine capable of performing an engineered task. Unlike other engineering challenges, the machines produced by these competitors are transcribed from DNA sequences, rather than blue prints, and the constituent parts are RNA, proteins and cells, instead of steel. This project bridges fields from biology through engineering and computer science and demonstrates the essential nature of an interdisciplinary approach to hard scientific research.
High-profile international competition
"Started in 2003, MIT students created biological oscillators coupled to fluorescent reporters. The summer of 2004 brought the first Synthetic Biology Competition. Student teams from five schools (Princeton, MIT, Caltech, UT Austin, and Boston University) and competed to build cellular state machines and counters. The teams gathered in early November to compare their results. The most graphic project was "photographic biofilm" that could capture an image. In the summer of 2005, student teams from thirteen schools (Berkeley, Caltech, Cambridge UK, Davidson, ETH Zurich, Harvard, MIT, Oklahoma, Penn State, Princeton, Toronto, UCSF, and UT Austin) participated in the 2005 International Genetically Engineered Machine (iGEM) competition. Later, during the first weekend of November, over 150 of these students, instructors, and PIs came together to share and celebrate their work. The iGEM 2005 student projects displayed the designs of chemotaxis regulation systems, cell-cell genetic communications systems, cellular/biological wires, thermometers, biological sketch pads (drawing systems), cellular relay races, a digital counter, and many more. At the core of these activities is the notion of a standard biological part that is well specified and able to be paired with other parts into subassemblies and whole systems. Once the parameters of these parts are determined and standardized, simulation and design of genetic systems will become easier and more reliable."[Knight 2005] |
Student led research at Brown
The main competition takes place over the summer with students spending their time designing novel engineered parts, modeling biochemical reactions and then implementing these designs in the lab. Here at Brown we already have support and offers of lab space from Gary Wessel in Molecular-Cellular Biology (MCB), Marc Tatar in Ecology and Evolutionary Biology (EEB) and offers from a number of faculty ranging from engineering, computer science and physics to join a multidisciplinary cross-campus faculty advisory board. This mentoring board will meet each week in order for students to report progress and to discuss ideas. The project gives students the opportunity to become directly involved with research at Brown. Previous entries in the iGEM competition have been published in Nature. [Engineering E.Coli to see light, 2005]
==Table of needs:==
We hope to get departmental and university sponsorship to cover the following costs.
8 undergraduate summer support stipends ($3500 x 8) | $ 28,000 |
DNA Synthesis costs | $ 4,000 |
Lab reagents | $ 7,000 |
Travel costs to MIT events, invited talk expenses | $ 1,000 |
Total | $ 40,000 |
==The future of iGEM==
We hope that in coming years the Brown iGEM team can continue to grow, taking on new students and continuing research in synthetic biology. We hope to find industry sponsorship to support the competition.
==Cross campus faculty support and mentoring==
Marc Tatar - Associate Professor of Ecology and Evolutionary Biology
Gary Wessel - Professor of Biology
Alex Brodsky, Assistant Professor in MCB, Ship Street
Karen Marie Haberstroh - Assistant Professor of Engineering
Sorin Istrail - Professor of Computer Science
Tayha Palmore - Associate Professor of Engineering
Art Soloman, Assistant Professor of Biology/Proteomics/Biochemistry
David Targan - Dean for Science Programs
Marjorie Thompson - Associate Dean of Biological Sciences
Jim Valles - Professor of Physics
Herman Vandenburgh - Professor of Pathobiology
Potential support (TBC)
Nicola Neretti, Assistant Professor of Physics
==References==
(1)Tom Knight 2005, iGEM: International Genetically Engineered Machine competition.
http://icampus.mit.edu/projects/iGem.shtml
(2)Chris Voigt 2005, Synthetic biology: Engineering Escherichia coli to see light, Nature 438, 441-442 (24 November 2005)
(3)The International HapMap Consortium. A haplotype map of the human genome.
Nature 437, 1299-1320. 2005.
(4) Jay D Keasling, Engineering a mevalonate pathway in Escherichia coli for production of terpenoids, Nature Biotechnology 21, 796 - 802 (2003)
(5)Anderson, J. C., Clarke, E. J., Arkin, A. P., & Voigt, C. A. (2005) Environmentally Controlled Invasion of Cancer Cells by Engineered Bacteria, Journal of Molecular Biology, in press.