Team:RHIT/Modeling
From 2012.igem.org
Line 118: | Line 118: | ||
<p>For the team’s mathematical modeling section, two differential models of the system were created: a case with one or more independent binding sites and a case that exhibits cooperatively with various binding sites. Both of these systems of equations are shown below. The behavior of the steady-state solutions of the system of equations were analyzed using algebraic and graphical methods. This analysis provided insight into the possible results from this kind of system.</p><br /> | <p>For the team’s mathematical modeling section, two differential models of the system were created: a case with one or more independent binding sites and a case that exhibits cooperatively with various binding sites. Both of these systems of equations are shown below. The behavior of the steady-state solutions of the system of equations were analyzed using algebraic and graphical methods. This analysis provided insight into the possible results from this kind of system.</p><br /> | ||
<div align="center"><img src="https://static.igem.org/mediawiki/igem.org/0/0d/Diffeq1.png" width=40%/></div> | <div align="center"><img src="https://static.igem.org/mediawiki/igem.org/0/0d/Diffeq1.png" width=40%/></div> | ||
- | <div align="center">< | + | <div align="center"><p>Figure 1. Independent binding sites</p></div> |
<div align="center"><img src="https://static.igem.org/mediawiki/igem.org/c/c0/Diffeq2.png" width=40%/></div> | <div align="center"><img src="https://static.igem.org/mediawiki/igem.org/c/c0/Diffeq2.png" width=40%/></div> | ||
<div align="center"><h4>Figure 2. Cooperative binding</h4></div> | <div align="center"><h4>Figure 2. Cooperative binding</h4></div> | ||
<p>The figures below illustrate the three possible solutions predicted by the mathematical model. The X-axis is a measure of the external mating pheromone concentration, and the Y-axis depicts the amount of protein. The first illustration depicts a system where once any signal or protein is present the circuit is turned on and continues to produce more protein up to a cap. The second depicts a system where there a particular threshold of mating pheromone required to bring about a stable level of protein, below this level, the protein production is transient and returns to zero. The third depicts a system similar to the second where there is a threshold, where the protein is created up to cap, however once the signal drops below that threshold, it again returns to zero.</p><br /> | <p>The figures below illustrate the three possible solutions predicted by the mathematical model. The X-axis is a measure of the external mating pheromone concentration, and the Y-axis depicts the amount of protein. The first illustration depicts a system where once any signal or protein is present the circuit is turned on and continues to produce more protein up to a cap. The second depicts a system where there a particular threshold of mating pheromone required to bring about a stable level of protein, below this level, the protein production is transient and returns to zero. The third depicts a system similar to the second where there is a threshold, where the protein is created up to cap, however once the signal drops below that threshold, it again returns to zero.</p><br /> | ||
- | Signal/Response Diagrams here | + | Signal/Response Diagrams here<br /><br /> |
<p> While it is not yet possible to verify which, if any, accurately represents the actual system, the created models predict possible scenarios that would allow for the success of the project. Furthermore, the model predicts that the success of this project is dependent solely on the parameters of the system, in particular the ratios between _____. The results of the model make good biological sense and intuitively make sense. In order for the project to be successful, either the first or second depictions must hold true. The analysis, derivation, future work, and all the work leading to these conclusions are listed below in the named sections.</p> | <p> While it is not yet possible to verify which, if any, accurately represents the actual system, the created models predict possible scenarios that would allow for the success of the project. Furthermore, the model predicts that the success of this project is dependent solely on the parameters of the system, in particular the ratios between _____. The results of the model make good biological sense and intuitively make sense. In order for the project to be successful, either the first or second depictions must hold true. The analysis, derivation, future work, and all the work leading to these conclusions are listed below in the named sections.</p> | ||
</div> | </div> |
Revision as of 14:50, 17 August 2012