Team:USTC Software/What

From 2009.igem.org

Revision as of 04:00, 19 October 2009 by Heyu3 (Talk | contribs)


About Team and People Project Standard Notebook Demo Safety External Links

USTCSW What.png

USTCSW hoW.png

USTCSW Who.png

USTCSW When.png

Example 1. Synthetic Oscillator

Introduction

The synthetic oscillatory network designed by Elowitz and Leibler is ...........

Mathematical Formulation

The activities of a gene are regulated by other genes through the interactions between them, i.e., the transcription and translation factors. Here, we assume that this system follows Hill kinetic law.

<math>\begin{align} \frac{dm_{i}}{dt} &=-a_{i}m_{i}+\sum\limits_{j}b_{ij}\frac{p_{j}^{H_{ij}}}{K_{ij}+p_{j}^{H_{ij}}}+l_{i}, \\ \frac{dp_{i}}{dt} &=-c_{i}p_{i}+d_{i}m_{i}, (i=1,2,...,n) \end{align}\,\!</math>

where <math>m_{i}(t), p_{i}(t)\in {\mathbb{R}}</math> are concentrations of mRNA and protein of the <math>i</math>th node at time <math>t</math>, respectively, <math>a_{i}</math> and <math>c_{i}</math> are the degradation rates of the mRNA and protein, <math>d_{i}</math> is the translation rate. Term (1) describes the transcription process and term (2) describes the translation process. Negative and positive signs of <math>b_{ij}</math> indicates the mutual interaction relationship that could be attributed to negative or positive feedback. The values describe the strength of promoters which is tunable by inserting different promoters in gene circuits. <math>H_{ij}</math> is Hill coefficient describing cooperativity. <math>K_{ij}</math> is the apparent dissociation constant derived from the law of mass action (equilibrium constant for dissociation). We can write <math>K_{ij}=\left( \hat{K}_{ij}\right) ^{n}</math> where <math>\hat{K}</math> is ligand concentration producing half occupation (ligand concentration occupying half of the binding sites), that is also the microscopic dissociation constant.

A Tunable Oscillator

The original three repressors model is described as follows:%

<math>\begin{align} \frac{dm_{1}}{dt} &=-am_{1}+b\frac{p_{3}^{H_{13}}}{K+p_{3}^{H_{1}}}, \\ \frac{dm_{2}}{dt} &=-am_{2}+b\frac{p_{1}^{H_{21}}}{K+p_{1}^{H_{2}}}, \\ \frac{dm_{3}}{dt} &=-am_{3}+b\frac{p_{2}^{H_{32}}}{K+p_{2}^{H_{32}}}, \\ \frac{dp_{1}}{dt} &=-cp_{1}+dm_{1}, \\ \frac{dp_{2}}{dt} &=-cp_{2}+dm_{2}, \\ \frac{dp_{3}}{dt} &=-cp_{3}+dm_{3},\text{ } \end{align}\,\!</math>

where <math>a, b,</math> <math>c,</math> <math>d,</math> <math>H_{1},</math> <math>H_{2},</math> <math>H_{3},</math> <math>K</math> are tunable parameters that could change wave amplitude and frequency. For simplicity, we assume that <math>H_{13}=H_{21}=H_{32}=2,</math> meaning that the system contains only positively cooperative reaction that once one ligand molecule is bound to the enzyme, its affinity for other ligand molecules increases.

<math>\begin{align} figure\text{ 1}\text{: wave amplitude} && \\ figure\text{ 2}\text{: wave frequency} && \\ figure\text{ 3}\text{: sensitivity analysis} && \end{align}\,\!</math>

[[Image:]]

An Alternative Topology That Leads to Oscillation

The original three repressors model is described as follows:%

<math>\begin{align} \frac{dm_{1}}{dt} &= -a_{1}x_{1}+\frac{b_{1}}{K_{1}+p_{2}^{H_{12}}}, \\ \frac{dm_{2}}{dt} &= -a_{2}x_{2}+\frac{b_{2}p_{3}^{H_{23}}}{% K_{2}+p_{1}^{H_{21}}+p_{3}^{H_{23}}}, \\ \frac{dm_{3}}{dt} &= -a_{3}x_{3}+\frac{b_{3}}{K_{3}+p_{2}^{H_{32}}} \\ \frac{dp_{1}}{dt} &= -c_{1}p_{1}+d_{1}m_{1}, \\ \frac{dp_{2}}{dt} &= -c_{2}p_{2}+d_{2}m_{2}, \\ \frac{dp_{3}}{dt} &= -c_{3}p_{3}+d_{3}m_{3}, \end{align}\,\!</math>

[[Image:]]



Automatic Biological Circuits Design
Team Logo: wanna know more about the hinding metaphors and inspirations in this little red square? Click to check out how much fun this year's iGEM has brought us!



Sponsorship


Teaching Affair Office, USTC

School of Life Sicences, USTC

Foreign Affair Office, USTC

Graduate School, USTC

School of Information Science and Technology, USTC

School for the Gifted Young, USTC