Team:NYC Wetware/BioNumbers
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Deinococcus Radioduran (D. rad) is famous for being resistant to 3000 times the radiation dose lethal to humans. Inspired to prove the potential of genetic engineering, the New York City iGEM Team chose to create radiation-resistant biobricks. We planned to find the genes that give D. rad extraordinary radiation resistance, and put them into loserish bacteria like E. coli, and see if we could turn the E. coli into super-hero bacteria.<br/> | Deinococcus Radioduran (D. rad) is famous for being resistant to 3000 times the radiation dose lethal to humans. Inspired to prove the potential of genetic engineering, the New York City iGEM Team chose to create radiation-resistant biobricks. We planned to find the genes that give D. rad extraordinary radiation resistance, and put them into loserish bacteria like E. coli, and see if we could turn the E. coli into super-hero bacteria.<br/> | ||
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- | By finding genes that allow life to thrive in extremely harsh environments, we help develop the emerging field of genetic engineering into a classic engineering | + | By finding genes that allow life to thrive in extremely harsh environments, we help develop the emerging field of genetic engineering into a classic engineering discipline like electrical or mechanical engineering. We will demonstrated that we too can tackle the complex problems. Below find a table of extremophile values. Achieve these and demonstrate the power of synthetic biology to yourselves, fellow iGEM teams, fellow engineers and the general public. In addition to the list below, we have submitted these values to the <a href="http://bionumbers.hms.harvard.edu"> BioNumbers</a> Database. Good Luck!<br/> |
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Latest revision as of 23:27, 22 December 2011
There’s a Gene for That
Deinococcus Radioduran (D. rad) is famous for being resistant to 3000 times the radiation dose lethal to humans. Inspired to prove the potential of genetic engineering, the New York City iGEM Team chose to create radiation-resistant biobricks. We planned to find the genes that give D. rad extraordinary radiation resistance, and put them into loserish bacteria like E. coli, and see if we could turn the E. coli into super-hero bacteria.By finding genes that allow life to thrive in extremely harsh environments, we help develop the emerging field of genetic engineering into a classic engineering discipline like electrical or mechanical engineering. We will demonstrated that we too can tackle the complex problems. Below find a table of extremophile values. Achieve these and demonstrate the power of synthetic biology to yourselves, fellow iGEM teams, fellow engineers and the general public. In addition to the list below, we have submitted these values to the BioNumbers Database. Good Luck!
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Extremophile Numbers
High Radiation: Deinocuccus radiodurans can live in 17500 Gy
Low Temperature: Assorted Bacteria can live in < 1 celsius
High Temperature: Strain 121 can live in 130 celsius
High Pressure: Pyrococcus CH1 can survive 120 MPa
Vacuum: Tardigrades can live in a near perfect vacuum
Salinity (Concentration): Dunaliella salina can live in 30% NaCl
High pH : Assorted Bacteria can live in 13.2
Low pH: Cyanidium caldarium can survive 0.05
Low Water Activity : Xeromyces bisporus can live in 0.62
Some Extraordinary Synthetic Biology Numbers
Longest synthetic genome: The 1.08-mega-base pairMycoplasma mycoides JCVI-syn1.0 Genome
Longest sustained expression of a pore-forming protein in a liposome was 4 Days
Enzyme efficiency of wintergreen-smell producing Biobrick BBa_J45004 (mM-1⋅s-1) in E. coli is 7.65 ± 0.618
BioNumbers is the database of useful biological numbers. It aims to enable you to find in one minute any common biological number important for your research, such as the rate of translation of the ribosome, concentrations of metabolites or the number of bacteria in your gut. You will find full references as well as additional extraordinary numbers. Check it out at: www.bioNumbers.hms.harvard.edu.
Please let us know any suggestions and comments: ron.milo@weizmann.ac.il or joseph.steinberger@weizmann.ac.il