Team:TU Munich/Modeling
From 2010.igem.org
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The question whether anti-termination occurs is not only guided by the folding process of the signal-terminator pair, but also by how long the signal takes to diffuse to the terminator sequence. To account for the diffusion time, we estimated the hit rate τ (following 6.), which is the time until the signal meets the terminator sequence for the first time: <br> | The question whether anti-termination occurs is not only guided by the folding process of the signal-terminator pair, but also by how long the signal takes to diffuse to the terminator sequence. To account for the diffusion time, we estimated the hit rate τ (following 6.), which is the time until the signal meets the terminator sequence for the first time: <br> | ||
- | τ = 1/(3D*a/r<sup>3</sup>) <br> | + | τ = 1/(3D*a/r<sup>3</sup>), <br> |
where ''D'' is the diffusion constant, ''a'' the radius of gyration of the signal molecule and ''r'' the radius of the cell.<br> | where ''D'' is the diffusion constant, ''a'' the radius of gyration of the signal molecule and ''r'' the radius of the cell.<br> | ||
- | For E.coli ''r'' is 1 μm. The radius of gyration ''a''can be estimated using the worm-like-chain model by <br> | + | For E.coli ''r'' is 1 μm. The radius of gyration ''a'' can be estimated using the worm-like-chain model by <br> |
a = (n*l)/3, <<br> | a = (n*l)/3, <<br> | ||
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The diffusion constant ''D'' was obtained by <br> | The diffusion constant ''D'' was obtained by <br> | ||
- | D = k<sub>B</sub> T/ | + | D = k<sub>B</sub> T/ (6 π * 10*10<sup>-3</sup>*a),<br> |
- | + | ||
- | + | where ''k<sub>B</sub>'' is the Boltzmann constant and ''T'' is the absolute temperature. <br> | |
- | As the folding time is | + | Using the ''a'' we calculated above, we get D = 3,4318 m<sup>2</sup>/s. <br> |
+ | |||
+ | Thus, for a cell containing 100 signal molecules, the signal needs '''0,1518 s''' until it first hits the terminator sequence. | ||
+ | |||
+ | As the folding time is significantly larger than the diffusion and thus much less relevant for modeling our signal-terminator constructs, we didn't employ more elaborate techniques to model diffusion. | ||
</div> | </div> | ||
Revision as of 12:24, 19 October 2010
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OverviewWe simulated the termination and anti-termination properties of our signal-terminator constructs with the Kinefold web server and used some standard estimations for diffusive terms. Our main goal was to prove that our constructs work and that termination is stopped efficiently, that is that the signal molecule binds and anti-terminations occurs before the RNA polymerase falls off. DiffusionThe question whether anti-termination occurs is not only guided by the folding process of the signal-terminator pair, but also by how long the signal takes to diffuse to the terminator sequence. To account for the diffusion time, we estimated the hit rate τ (following 6.), which is the time until the signal meets the terminator sequence for the first time: τ = 1/(3D*a/r3), where D is the diffusion constant, a the radius of gyration of the signal molecule and r the radius of the cell. a = (n*l)/3, < where n is the length of the signal which is 0,3 nm/monomer, l is the persistency length which is following (5.) 2nm for single-stranded RNA. Thus, for a signal of length 32 nt, a = 6,4 nm. The diffusion constant D was obtained by D = kB T/ (6 π * 10*10-3*a), where kB is the Boltzmann constant and T is the absolute temperature. Thus, for a cell containing 100 signal molecules, the signal needs 0,1518 s until it first hits the terminator sequence. As the folding time is significantly larger than the diffusion and thus much less relevant for modeling our signal-terminator constructs, we didn't employ more elaborate techniques to model diffusion. SwitchModelingResultsNetworkModelingResultsOutlook |