Team:Tsinghua/Modeling

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Time series of the concentration of each species can be generated by simulation of the model with <b>initial conditions</b>. When AHL is added to the system, the concentration of ADE2 will increase in the initial phase. Finally the concentration of ADE2 will reach its <b>maximum</b> and keep <b>steady</b> for a time. The color of the yeast will also turn from red to white. The time it takes for the concentration of ADE2 to reach its <b>maximum</b> is defined as <b>response time</b> and the <b>maximum</b> concentration of ADE2 is defined as <b>response value<、b>.
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Time series of the concentration of each species can be generated by simulation of the model with <b>initial conditions</b>. When AHL is added to the system, the concentration of ADE2 will increase in the initial phase. Finally the concentration of ADE2 will reach its <b>maximum</b> and keep <b>steady</b> for a time. The color of the yeast will also turn from red to white. The time it takes for the concentration of ADE2 to reach its <b>maximum</b> is defined as <b>response time</b> and the <b>maximum</b> concentration of ADE2 is defined as <b>response value</b>.
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Latest revision as of 20:28, 27 September 2013

Modeling

The regulatory pathway is modeled as systems of ordinary equations dependent on time. After setting initial concentration of all species, a time series of the concentration of each species can be generated by simulation. Regression analysis relates concentration of the reporter gene product (ADE2) to yeast color. Simulation of the model predicts how yeast color changes with time. Sensitivity analysis predicts the relationship between input (AHL concentration) and output (yeast color). A dose-response curve (yeast color to AHL concentration) can be obtained by simulation of the model with different initial AHL concentration. Then the AHL concentration in the environment can be estimated from yeast color using the dose-response curve. As the AHL concentration is proportional to the population bacteria, the population of bacteria can also be estimated. By fitting the model to experiment data, we can detect the concentration of specific bacteria from yeast color.

  • Introduction
  • Assumptions
  • Model
  • Sensitivity Analysis

Introduction

After mating, the fused yeast cell gains both the sensor and reporter system. Then the yeast cell is capable of detection AHL in the environment and reports them.

There are three stages in the detection of AHL from bacteria. First, AHL in the environment diffuses across the cell membrane of the yeast. Second, AHL binds to modified LuxR transactivator and forms a complex, which enters the nucleus and binds to the LuxR promoter. Upon binding, the AHL-LuxR complex activates the expression of the transcription factor tTA1. tTA enters the nucleus and binds to Tet operator, activating the reporter gene ADE2. Expression of ADE2 changes the color of the yeast from red to white. An overview of the biochemical process is shown in Figure 1. The figure is drawn with CellDesigner2 4.3.

Figure 1. Overview of the biochemical process

Assumptions

AHL is secreted by bacteria and diffuses across the cell membrane of the yeast. It is assumed that the diffusion process reaches equilibrium within a short time so the concentration of AHL inside and outside the yeast cell membrane is the same.

After AHL binds to modified LuxR protein to form an AHL-LuxR complex, the complex must be transported into the cell nucleus. The nuclear localization sequence (NLS) on the LuxR protein is recognized by importin and then imported into the cell nucleus. To model the cell more accurately, the rate of transportation must be considered. However, without sufficient experiment data, it is difficult to estimate the kinetic parameters. In a simplified model, the concentrations of transcription factor inside and outside cell nucleus are assumed to be equal.

Three steps are required to activate expression of a protein: transcription factor binding, transcription and translation. If transportation of proteins and mRNAs are considered, there will be more steps. To simplify the model, we assume that the concentrations of transcription factors and mRNAs inside and outside the cell nucleus are equal. Transcription and translation can be modeled as a single process as they are tightly coupled.

Activation of transcription is modeled as a stochastic process. A promoter is either bound or unbound by one transcription factor molecule at a moment. Binding of transcription factor increases transcription rate of the target gene. The probability of transcription factor binding is determined by the concentration of transcription factor, gene copy number and binding affinity (or disassociation rate).

Model

The biochemical process is modeled as ordinary differential equations. The variables and equations are list as follows.

Species

  • AHL (concentration remains constant)
  • LuxR – LuxR in cytoplasm
  • LuxRC – LuxR-AHL complex (dimer)
  • tTA
  • ADE2

Kinetic parameters

NameDescription
k1basal expression rate under constitutive promoter
k2dimerization rate of AHL and LuxR
k3degradation rate of LuxR
k4degradation rate of LuxRC
k5expression rate of tTA
k6activation coefficient of LuxRC
k7degradation rate of tTA
k8basal expression rate of tTA
k9expression rate of ADE2
k10activation coefficient of tTA
k11degradation rate of ADE2
k12basal expression rate of ADE2

Equations

LuxR protein is synthesize at a constant rate k1. AHL binds to LuxR to form a complex. Then AHL-LuxR complex dimerizes to form a transcription factor3.

Activation of tTA expression is modeled using Hill function. Hill functions is commonly used to model the interactions between transcription factors and promoters4. The transcription factor cooperativity is 1 (single binding site). k5 is the expression rate of tTA if the promoter is fully activated.

Activation of ADE2 expression is also modeled in Hill function.

Sensitivity Analysis

Among all species considered in the model, initial AHL concentration is the main factor that determines the output of the system. The main output of the system is the color of the yeast which is correlated with the concentration of ADE2. The relationship between the concentration of ADE2 and the initial concentration of AHL will be analyzed.

Time series of the concentration of each species can be generated by simulation of the model with initial conditions. When AHL is added to the system, the concentration of ADE2 will increase in the initial phase. Finally the concentration of ADE2 will reach its maximum and keep steady for a time. The color of the yeast will also turn from red to white. The time it takes for the concentration of ADE2 to reach its maximum is defined as response time and the maximum concentration of ADE2 is defined as response value.

To analyze the sensitivity of the system to AHL concentration, we set different initial AHL concentrations. A dose-response curve can be drawn from a series of AHL concentrations and response values. The parameters of the dose-response curve can be estimated from experiment data. Then the curve can be used to estimate the AHL concentration in the environment from yeast color.

However, we didn’t collect sufficient data to estimate the model parameters. We set parameters adapted from literature3. A time series data is plotted as shown in Figure 2 by setting initial AHL concentration to 1 μM. A dose-response curve is shown in Figure 3. However, the parameters were estimated from experiments with E. coli, and might not be applied to yeast system. We can only know the shape of the curves. We will try to collect more data points to increase the predictive power of our model.

Figure2. Time series of the concentration of each species

Figure3. Dose-response curve

References

  1. Gossen, M. & Bujard, H. Tight control of gene expression in mammalian cells by tetracycline-responsive promoters. Proc. Natl. Acad. Sci. 89, 5547–5551 (1992).
  2. Funahashi, A., Morohashi, M., Kitano, H. & Tanimura, N. CellDesigner: a process diagram editor for gene-regulatory and biochemical networks. BIOSILICO 1, 159–162 (2003).
  3. Basu, S., Gerchman, Y., Collins, C. H., Arnold, F. H. & Weiss, R. A synthetic multicellular system for programmed pattern formation. Nature 434, 1130–1134 (2005).
  4. Goutelle, S. et al. The Hill equation: a review of its capabilities in pharmacological modelling. Fundam. Clin. Pharmacol. 22, 633–648 (2008).