Team:NTU-Singapore/Modelling/Stochastic Modeling
From 2008.igem.org
(→Stochastic Model For E7 + Imm Production) |
(→Gillespie Model) |
||
Line 53: | Line 53: | ||
[[Image:Sys1_DetermMod.jpg|thumb|center|700px| Cellware E7 production System Deterministic Models]]<br> | [[Image:Sys1_DetermMod.jpg|thumb|center|700px| Cellware E7 production System Deterministic Models]]<br> | ||
The model shows that there are differences in the output when the Lactose is changed but they are not exactly significant. However the model still shows very similar behaviour to the [https://2008.igem.org/Team:NTU-Singapore/Modelling/Deterministic_Modeling#E7_production_system model] we had obtained using Simulink earlier.<br> | The model shows that there are differences in the output when the Lactose is changed but they are not exactly significant. However the model still shows very similar behaviour to the [https://2008.igem.org/Team:NTU-Singapore/Modelling/Deterministic_Modeling#E7_production_system model] we had obtained using Simulink earlier.<br> | ||
- | ==Gillespie Model== | + | ===Gillespie Model=== |
The stochastic modeling results are as shown and a total of 10 runs was done. The results are also compared to the Deterministic Modeling Output. One might then think that since the Deterministic Models produce results in concentrations while the Stochastic Models give their results in the number of molecules, the results are not actually the same. That is perfectly true. The reason for putting the results together is for a simple visualisation of the results. Again, it is stressed that the behaviour of the models are of greater importance, not the numerical values.<br> | The stochastic modeling results are as shown and a total of 10 runs was done. The results are also compared to the Deterministic Modeling Output. One might then think that since the Deterministic Models produce results in concentrations while the Stochastic Models give their results in the number of molecules, the results are not actually the same. That is perfectly true. The reason for putting the results together is for a simple visualisation of the results. Again, it is stressed that the behaviour of the models are of greater importance, not the numerical values.<br> | ||
[[Image:Sys1_gillespie.jpg||center|thumb|800px|Cellware Gillespie model for E7 production system]]<br> | [[Image:Sys1_gillespie.jpg||center|thumb|800px|Cellware Gillespie model for E7 production system]]<br> | ||
- | The run was done with 10mM lactose induction. As seen, the model is simple and the stochastic model produces results that are close to the deterministic model. | + | The run was done with 10mM lactose induction. As seen, the model is simple and the stochastic model produces results that are close to the deterministic model. |
+ | |||
==Gibson Next Reaction Method== | ==Gibson Next Reaction Method== | ||
[[Image:Sys1_gibson.jpg|center|thumb|800px|Cellware Gibson Next Reaction method for E7 production system]]<br> | [[Image:Sys1_gibson.jpg|center|thumb|800px|Cellware Gibson Next Reaction method for E7 production system]]<br> |
Revision as of 07:24, 26 October 2008
|
Contents |
Stochastic Modeling
Preliminary Run
This model was generated using the program [http://www.cellware.org/index.html CellWare]. The above model was simulated using a Hybrid ODE solver that uses both deterministic and stochastic solvers. Work is now being done to see if this program can be used to build and simulate our systems.
All models below have been created using Cellware. [http://x.amath.unc.edu:16080/BioNetS/ Bionets2] is another option but we would first explore the use of the former program. The outputs are exported to MATLAB for plotting and visualisation.
Stochastic models using Gillispie Algorithm do not seem to work well as they seem to require a lot of computing power. Hybrid Stochastic ODEs seems to work better but the accuracy of the results seems to be compromised.
It is advised that the viewer observe the trends rather than the actual values given in the models. The modeling results would give us more of an idea of how the system would react rather than tell us exactly how much of a particular protein would be expressed. We hope that by doing this modeling exercise, we can learn more about our system.
Stochastic Model For E7 + Imm Production
The above image shows the model that was used in Cellware for the 1st System.
The Purple Rectangles represent the DNA.
The Green Rectangles represent the mRNA.
The Pink Diamonds represent the Protein.
The Red Concentric Circles represent a certain reaction (Mass Action Reactions only, since its a requirement for Stochastic simulations)
The Purple Full Circles represented degradation of a particular substance.
Unlike the previous Simulink deterministic models, Cellware does not allow the user to inject certain variables at stipulated times. Therefore, the model shows inoculation of Lactose at the VERY START of the simulation. This is equivalent to exposing a newly divided cell to an environment of lactose rather than allowing it time to reach a certain steady state for its constitutive proteins. Nevertheless, we hope that the model can still allow us some insights into the system.
Parameter | Deterministic(m/l) | Stochastic(No. of Molecules) |
GA | 28 | 28 |
GC | 28 | 28 |
Lactose | 10 | 10 |
Before we actually use the program to run any form of stochastic simulations, it would be necessary to check how its deterministic models would turn out. By varying the amount of Lactose input, a few graphs were obtained and they are as shown.
The model shows that there are differences in the output when the Lactose is changed but they are not exactly significant. However the model still shows very similar behaviour to the model we had obtained using Simulink earlier.
Gillespie Model
The stochastic modeling results are as shown and a total of 10 runs was done. The results are also compared to the Deterministic Modeling Output. One might then think that since the Deterministic Models produce results in concentrations while the Stochastic Models give their results in the number of molecules, the results are not actually the same. That is perfectly true. The reason for putting the results together is for a simple visualisation of the results. Again, it is stressed that the behaviour of the models are of greater importance, not the numerical values.
The run was done with 10mM lactose induction. As seen, the model is simple and the stochastic model produces results that are close to the deterministic model.
Gibson Next Reaction Method
Stochastic Model For Lysis Production
The above diagram shows how we have modeled the Lysis Production system in Cellware. Again the legend is the same as the first E7 production system. We would also like to see how the Deterministic models turn out. The results are as shown.
Parameter | Deterministic(m/l) | Stochastic(No. of Molecules) |
GC | 85 | 10 |
GD | 85 | 10 |
GE | 85 | 10 |
GF | 85 | 10 |
Ai-2(Present) | 238 | 28 |
Ai-2(Not Present) | 0 | 0 |
Fe(Present) | 130.05 | 15.3 |
Fe (Not Present) | 127.5 | 15 |
As we can see, a very similar outcome is observed as compared to the model we had obtained in Simulink. The difference in the Lysis protein output under the conditions that Ai-2 is present alone and when Iron and Ai-2 is present is not very pronounced.
Gillespie Model
For the Stochastic model, the number of molecules are also a guess and more work has to be done is refining the parameters. Presented here is the initial results for the condition that both Ai-2 and iron ions are present, thereby activating the and gate. The stochastic model results are also compared with the deterministic model.
A total of 10 runs was done to observe the results. As expected, the random nature of the algorithm will give unique results for each run. Although the variations here are much larger compared to the first system, the general trend is still similar.
Gibson Next Reaction Method
Hybrid Model
A run using the Hybrid Stochastic ODE solver was also done just to see how the results would vary. The model's basis is to introduce noise elements into the deterministic model and the solvers employ both deterministic ODE solvers and stochastic solvers. The result is as shown.
A total of 3 runs using the Hybrid ODE solver was done and the outputs were put together with the Deterministic Model for easy comaprison. The modeling results show the Hybrid model results don't vary much as they overlap one another. To fully appreciate the stochastic nature of the systems, the Gillispie Algorithm and other Stochastic Algorithms seem to be a better choice
Stochastic Model For New Lysis System Production
As discussed beforein the deterministic modeling section, a new lysis system was introduced and a new model was built to see how the results would turn out.
As seen, the Lysis production modeled using the Gillespie model after 10 runs show that the Lysis production would tend to a steady state after some time.
For the sake of interest, we can see that the models also show that the Lysis production with AND gate has a slower response time to the new Lysis production. The new system can achieve the faster lysis of the cell, but again, fails in specificity.
Updates
Currently the Simulations for the Lysis Production system tend to terminate prematurely at time = 70 min. The reason is still unknown but it could be due to the fact that the system is much more complicated than the E7 production system. Work is still being done to see if more models can be generated using Cellware. The program is generally easy to manipulate and the interface is quite user-friendly. If you have any comments on how our modeling exercise can be improved, don't hesitate to leave us an email . All contributions will be acknowledged by our team.