Biomod/2011/UTAustin/Hook'em Hybridizers: Difference between revisions
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====The Counting Machine as a Modular Nanoscale DNA Component.==== | |||
One major goal of nanotechnology is to control chemical | |||
reactions pera logical specification. Nano-biological devices have | |||
been"programmed" to function as AND / OR gates, timed oscillators, | |||
motors,and to have other forms of controlled responses to their | |||
environment.We have engineered a prototype of an enzyme-free DNA | |||
circuit based on toeholdexchange to 'count' signal pulses | |||
corresponding to additions of adefined chemical. Counting, by our | |||
definition, needs to meet twocriteria: First, the input being being | |||
counted is a single chemicalused for each pulse. Second, the counter | |||
should output an ON signalonly when some fixed number of pulses have | |||
been encountered,regardless of the amount of input added in any pulse, | |||
and the strengthof the ON signal should be independent of the amount | |||
of input addedeach pulse. The molecular basis of our prototype | |||
count-to-two unitincludes (1) a time-delayedsignal transduction series | |||
coupled to an AND gate and (2) a mechanism forconstant input | |||
degradation. In theory such units can be connected seriallyto make a | |||
counter that is capable to count to any pre-specified finitenumber. | |||
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Revision as of 17:46, 18 October 2011
The Hook'em Hybridizers
Team
- Team name: The Hook'em Hybridizers
- Institution: The University of Texas at Austin
- Team Members
- Postdoc Mentors
- Dr. Peter Allen
- Dr. Xi Chen
- Faculty mentors
About
The Counting Machine as a Modular Nanoscale DNA Component.
One major goal of nanotechnology is to control chemical reactions pera logical specification. Nano-biological devices have been"programmed" to function as AND / OR gates, timed oscillators, motors,and to have other forms of controlled responses to their environment.We have engineered a prototype of an enzyme-free DNA circuit based on toeholdexchange to 'count' signal pulses corresponding to additions of adefined chemical. Counting, by our definition, needs to meet twocriteria: First, the input being being counted is a single chemicalused for each pulse. Second, the counter should output an ON signalonly when some fixed number of pulses have been encountered,regardless of the amount of input added in any pulse, and the strengthof the ON signal should be independent of the amount of input addedeach pulse. The molecular basis of our prototype count-to-two unitincludes (1) a time-delayedsignal transduction series coupled to an AND gate and (2) a mechanism forconstant input degradation. In theory such units can be connected seriallyto make a counter that is capable to count to any pre-specified finitenumber.
