Team:Oxford/biosensor characterisation
From 2014.igem.org
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We started with the Gillespie Algorithm, which considers the expression of GFP to be binary; a molecule of GFP is either produced or degraded. Before we determined which reaction happened, we had to work out when the reaction happened. Using the random number r (taken from a uniform distribution between 0 and 1), we produced another random number τ, which determined the time until the next reaction. | We started with the Gillespie Algorithm, which considers the expression of GFP to be binary; a molecule of GFP is either produced or degraded. Before we determined which reaction happened, we had to work out when the reaction happened. Using the random number r (taken from a uniform distribution between 0 and 1), we produced another random number τ, which determined the time until the next reaction. | ||
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Where α_0 represents the probability that any reaction will happen, given by the following equation: | Where α_0 represents the probability that any reaction will happen, given by the following equation: | ||
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We modelled the probability of a molecule of GFP being created using the Michaelis-Menten model (α_1), incorporating a basal transcription rate (beta1). For the degradation, we assumed a simple proportional relationship; the more GFP you have the more likely it is that a molecule degrades (δ_1). The constant of proportionality will be a function of the intrinsic life time of the protein in the cell. We considered there to be no DCM originally, then a large step in DCM at time=0. This is similar to placing the detector in a DCM polluted source, to make the model more realistic the level of DCM would go down as it is degraded but we had no time to obtain data for this rate. | We modelled the probability of a molecule of GFP being created using the Michaelis-Menten model (α_1), incorporating a basal transcription rate (beta1). For the degradation, we assumed a simple proportional relationship; the more GFP you have the more likely it is that a molecule degrades (δ_1). The constant of proportionality will be a function of the intrinsic life time of the protein in the cell. We considered there to be no DCM originally, then a large step in DCM at time=0. This is similar to placing the detector in a DCM polluted source, to make the model more realistic the level of DCM would go down as it is degraded but we had no time to obtain data for this rate. | ||
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We only stored the time and amount of GFP when there was a reaction, to save on computation. However this made calculating the mean of realisation harder, but we got over the problem by…. | We only stored the time and amount of GFP when there was a reaction, to save on computation. However this made calculating the mean of realisation harder, but we got over the problem by…. | ||
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Stochastic modelling is useful because it can show us the stochastic effects which are often seen in real bacteria. By calculating the variation of the mean of multiple GFP producing bacteria, we can also work out the standard deviation. Then if we assume that the system varies with respect to the normal distribution, we can produce error bounds for the production of GFP. Such that we can say, 90% of the time we can expect the production of GFP from a single bacterium to be within these 2 curves. This could be useful for seeing if results are unexpected, or, if there are multiple outliers, that our model is incorrect. If we average more and more bacteria then the mean curve tend towards the deterministic response. This is to be expected as we are now looking at the system as a whole and fluctuations in the production from individual bacteria are averaged out. In terms of their use, when looking at small amounts of bacterium the stochastic model would be better, because real random fluctuations can be seen. For larger bacterium groups, the deterministic response models the growth very well. The stochastic model can also model large groups but requires large number of realisations which causes simulations to take a lot longer to run. | Stochastic modelling is useful because it can show us the stochastic effects which are often seen in real bacteria. By calculating the variation of the mean of multiple GFP producing bacteria, we can also work out the standard deviation. Then if we assume that the system varies with respect to the normal distribution, we can produce error bounds for the production of GFP. Such that we can say, 90% of the time we can expect the production of GFP from a single bacterium to be within these 2 curves. This could be useful for seeing if results are unexpected, or, if there are multiple outliers, that our model is incorrect. If we average more and more bacteria then the mean curve tend towards the deterministic response. This is to be expected as we are now looking at the system as a whole and fluctuations in the production from individual bacteria are averaged out. In terms of their use, when looking at small amounts of bacterium the stochastic model would be better, because real random fluctuations can be seen. For larger bacterium groups, the deterministic response models the growth very well. The stochastic model can also model large groups but requires large number of realisations which causes simulations to take a lot longer to run. |
Revision as of 18:14, 17 October 2014