Team:XMU-China/Content2
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Revision as of 12:20, 15 September 2013
First
By constructing robust circuits in E.coli, we want to build a gene network capable of synchronizing genetic oscillations in multiple levels. Cells can be synchronized at the colony level via quorum sensing, and a gas-phase redox will be signaling (mainly H2O2) between colonies simultaneously. Two scales of coupling ensured extremely consistent oscillations.
First
By constructing robust circuits in E.coli, we want to build a gene network capable of synchronizing genetic oscillations in multiple levels. Cells can be synchronized at the colony level via quorum sensing, and a gas-phase redox will be signaling (mainly H2O2) between colonies simultaneously. Two scales of coupling ensured extremely consistent oscillations.
First
By constructing robust circuits in E.coli, we want to build a gene network capable of synchronizing genetic oscillations in multiple levels. Cells can be synchronized at the colony level via quorum sensing, and a gas-phase redox will be signaling (mainly H2O2) between colonies simultaneously. Two scales of coupling ensured extremely consistent oscillations.
First
By constructing robust circuits in E.coli, we want to build a gene network capable of synchronizing genetic oscillations in multiple levels. Cells can be synchronized at the colony level via quorum sensing, and a gas-phase redox will be signaling (mainly H2O2) between colonies simultaneously. Two scales of coupling ensured extremely consistent oscillations.