Team:ETHZ Basel/Modeling

From 2010.igem.org

(Difference between revisions)
(Mathematical Modeling Overview)
Line 6: Line 6:
]]
]]
-
In order to support [[Team:ETHZ_Basel/Biology|wet laboratory experiments]] and to create a test bench for the [[Team:ETHZ_Basel/InformationProcessing|information processing]] part, a mathematical model of E. lemming was created. This goal was achieved by implementing and combining deterministic molecular models of the individual parts and probabilistic model for the bacterial movement.
+
In order to support [[Team:ETHZ_Basel/Biology|wet laboratory experiments]] and to create a test bench for the [[Team:ETHZ_Basel/InformationProcessing|information processing]] part, a complex mathematical model of E. lemming was created. This goal was achieved by implementing and combining deterministic molecular models of the [[Team:ETHZ_Basel/Modeling/Chemotaxis chemotaxis pathway]] and the [[Team:ETHZ_Basel/Modeling/Light_Switch light switch]] and probabilistic model for the [[Team:ETHZ_Basel/Modeling/Movement bacterial movement]].
== Implementation of mathematical models ==
== Implementation of mathematical models ==

Revision as of 00:16, 22 October 2010

Mathematical Modeling Overview

Schematical overview of the devices and change upon light pulse induction. LSP refers to light switch protein, AP to anchor protein, anchor to the plasmid anchor and Che to the attacked protein of the chemotaxis pathway. The core component of E. lemming is the fusion of one light-sensitive protein (LSP1) to a protein of the chemotaxis pathway (Che). Upon change of wavelength of light pulses, this component will dimerize with the corresponding light-sensitive protein (LSP2), which is linked to an anchor protein, bound to an anchor (plasmid). The result is a change of the spatial localization of Che and perturbation of the chemotaxis pathway, which ultimately leads to a different tumbling/directed movement state ratio.

In order to support wet laboratory experiments and to create a test bench for the information processing part, a complex mathematical model of E. lemming was created. This goal was achieved by implementing and combining deterministic molecular models of the Team:ETHZ_Basel/Modeling/Chemotaxis chemotaxis pathway and the Team:ETHZ_Basel/Modeling/Light_Switch light switch and probabilistic model for the Team:ETHZ_Basel/Modeling/Movement bacterial movement.

Implementation of mathematical models

Individual molecular and mathematical models

In a first step, we implemented individual molecular models of the subdevices and a mathematical model of the bacterial movement.

  • Light Switch: based upon the light-sensitive dimerizing Arabidopsis proteins PhyB and PIF3.
  • Chemotaxis Pathway: two similar models of the chemotactic receptor pathway.
  • Bacterial Movement: a probabilistic model of E. coli movement, determined by distribution of input bias.

Combined molecular and mathematical models

Combined models. Coupled individual models for the simulation of the whole process and their interfaces.

The next step, combination of the individual molecular and mathematical models to a comprehensive model of E. lemming was achieved in two substeps:

Experimental Design

Insights for wet laboratory

To create the biological implementation of E. lemming, the parts of the core components had to be chosen in an order to improve chances to result in a functioning ensemble. By using the combined molecular models for in silico evaluation of the best possible parts, it was possible to reduce the amount of different combinations to be tested.

Wet laboratory evaluation results have showed, that molecular modeling and experimental biology can interwork to gain new insight for both perceptions of the problem.

Insights for information processing

In order to adjust the controller to have optimal light pulse rates, the combined molecular model has been used to determine the corresponding time constants.

Information processing evaluation results provide further information how this has been accomplished.

Test bench for information processing

Test bench for information processing.

In order to create a first test bench for the information processing pipeline, the combined model has been used to create and evaluate the controller. By providing an input port for light pulse and an output port for bacterial movement, it was possible to close the loop and simulate the whole system.