Team:RHIT/Modeling
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- | <p>Having defined what the model was supposed to answer, and what parts of the process were going to be included, the next step was to design a system of differential equations that would account for the various pieces of the model. The first draft of this system is shown below, along with a brief description of what each equation represents, and what the various terms in each equation account for.</p> | + | <p>Having defined what the model was supposed to answer, and what parts of the process were going to be included, the next step was to design a system of differential equations that would account for the various pieces of the model. The first draft of this system is shown below, along with a brief description of what each equation represents, and what the various terms in each equation account for.</p><br /> |
dP/dt eqn img here | dP/dt eqn img here | ||
- | <p>This equation represented the pheromone concentration, (matA or mata) available to interact with the receptors of the cell. The equation was designed to account for the pheromones secreted by the yeast cells, the binding of the pheromone to the receptor, and the possible unbinding of the pheromone from the receptor. The secretion of the pheromone from one yeast cell was assumed to be independent of the changes exhibited by the other yeast cells. It was also assumed that this pheromone was equally distributed around the whole environment of the cells.</p> | + | <p>This equation represented the pheromone concentration, (matA or mata) available to interact with the receptors of the cell. The equation was designed to account for the pheromones secreted by the yeast cells, the binding of the pheromone to the receptor, and the possible unbinding of the pheromone from the receptor. The secretion of the pheromone from one yeast cell was assumed to be independent of the changes exhibited by the other yeast cells. It was also assumed that this pheromone was equally distributed around the whole environment of the cells.</p><br /> |
dB/dt eqn img here | dB/dt eqn img here | ||
dU/dt eqn img here | dU/dt eqn img here | ||
- | These two equations represented the two possible states of the pheromone receptor, (Ste2 or Ste3) bound to pheromone or unbound. While these proteins like most proteins will decay overtime and must be reproduced, due to the relatively small time scale that these proteins significantly contribute to the behavior of the system, these terms were assumed to be negligible. Furthermore, this model also assumes that all unbound receptors are capable of being bound and that all bound receptors are capable of signal transduction.</p> | + | These two equations represented the two possible states of the pheromone receptor, (Ste2 or Ste3) bound to pheromone or unbound. While these proteins like most proteins will decay overtime and must be reproduced, due to the relatively small time scale that these proteins significantly contribute to the behavior of the system, these terms were assumed to be negligible. Furthermore, this model also assumes that all unbound receptors are capable of being bound and that all bound receptors are capable of signal transduction.</p><br /> |
dS/dt eqn img here | dS/dt eqn img here | ||
dA/dt eqn img here | dA/dt eqn img here | ||
- | <p>These two equations represented a hypothetical signal that directly stimulated the production of the team's fluorescent hetero-transcription factor. The S equation signified the series of protein kinase interactions, caused by the production of bound pheromone receptor and a decay of the signal as the proteins are turned off. The A equation represented the total sum of the factors contributing to the synthesis of the construct, including the signal from the S equation, the auto-regulation of the construct, and the loss of the signal as the construct is synthesized.</p> | + | <p>These two equations represented a hypothetical signal that directly stimulated the production of the team's fluorescent hetero-transcription factor. The S equation signified the series of protein kinase interactions, caused by the production of bound pheromone receptor and a decay of the signal as the proteins are turned off. The A equation represented the total sum of the factors contributing to the synthesis of the construct, including the signal from the S equation, the auto-regulation of the construct, and the loss of the signal as the construct is synthesized.</p><br /> |
dX/dt eqn img here | dX/dt eqn img here | ||
- | <p>Finally this equation represented the concentration of the synthetic hetero-transcription factor that is produced by the signal, and is lost over time due to decay.</p> | + | <p>Finally this equation represented the concentration of the synthetic hetero-transcription factor that is produced by the signal, and is lost over time due to decay.</p><br /> |
- | <p>After creating this simple model, the team began doing research on the kinetic rate constants and binding affinities for the various parts of the model. During this research, the team came across a published model from Kofahl and Klipp's paper, Modeling the dynamics of the yeast pheromone pathway. </p> | + | <p>After creating this simple model, the team began doing research on the kinetic rate constants and binding affinities for the various parts of the model. During this research, the team came across a published model from Kofahl and Klipp's paper, <i>Modeling the dynamics of the yeast pheromone pathway</i>.</p><br /> |
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Revision as of 19:35, 14 August 2012