Quorum Sensing based

From 2006.igem.org

Revision as of 08:53, 9 August 2005 by Gio (Talk | contribs)
Jump to: navigation, search

Back to ETH Zurich main page.

Contents

Design Group

Design group defined during teammeeting on Thu. 2005.08.04

Purpose

  • Discuss those projects assigned to us and develop them further, both conceptually (modularity, coolness, usefulness) and implementation-wise (feasability, availability of components).
  • Agree on some favored existing solution or merge current concepts into a new one.

Current Project Variants

Current Members

New members: please add your name here so that we know that you want to join.

Discussion Meetings

Everybody is more than welcome to join in!

2005.08.05, Friday, 15:30, Discussion/development of group topics, Giorgia & Dominic
2005.08.07, Sunday, 16:00, Discussion/development of group topics, Herve & Dominic
2005.08.08, Monday, 10:00, Discussion/development of group topics, all (visitors welcome)
2005.08.09, Tuesday, 17:00, Discussion of feasability/implementation regarding modules

Progress

During the first two meetings we mainly developed the existing concepts further or added variants. On monday we tried to find useful categories to identify what makes the projects similar and what makes them different - in order to reduce the number of true variants and merge interesting functions into a new project idea. We started to divide the existing project ideas further into certain behavior states and their possible expression:

Behavior States

  • pattern formation
    • oscillation behavior
    • conversion to specific states
  • pattern display
    • fluorescence
    • physical structures

Modules

Also, we tried to break down the existing variants into modules fulfilling a specific function:

quorum sensing aggregation / sticking killer behavior
cell division sensing cell division control induced apoptosis
chemotaxis (+/-) nutrition production nutrition dependence

Then we discussed the estimated (!) feasability and general usefulness of these modules to get a better feeling of what should be used and what will prove difficult to implement.

Problems with Pred-Prey

We quickly found that the implementation of true Predator-Prey behavior would be very interesting, but that there are serious drawbacks:

  • there are no layers: all functions would have to be successfully implemented at the same time (e.g. production of nutrients in pop A, dependence on nutrients of pop B, balancing the killing behavior of B vs. A) otherwise the whole project would fail.
  • the resulting population dynamics would be interesting, but neither very useful nor extendable.

Convergence

The remaining project ideas, however, seem to share many modules and can be merged into the following new project variant.

Project X

Basic Concept

Two engineered strains of E.coli, A and B, in a tank. B's cell division is inhibited. Population A is either much larger than population B in the beginning, or growing much faster.

  • Stage 1:
    • 1.1 A constitutively expresses aggregation factor for A
    • 1.2 A and B constitutively express fluorescence genes (different colors)
    • 1.3 A constitutively releases some signaling substance a1, B constitutively expresses b1
  • Stage 2:
    • 2.1 A starts to aggregate and form clusters
    • 2.2 B senses concentration of substance a1
  • Stage 3:
    • 3.1 The clusters of A reach a critical size. This leads to a certain concentration of a1 in the vicinity of the cluster
    • 3.2 The threshold of a1 is reached and sensed by B. This triggers intensive cell division of B.
    • 3.3 In parallel, B expresses an aggregation factor that makes B attach to A
  • Stage 4:
    • 4.1 A shell of B forms around the clusters of A.
    • 4.2 a1 and b1 reach certain concentrations at the B-shell-A-core boundary, which triggers the production of cellulose in both types. Either as AND-implementation or more simply just by b1 triggering A and a1 triggering B.
  • Stage 5:
    • 5.1 Due to the growing thickness of the cellulose shell, the A-core gets isolated and starts to express some different fluorescence gene.

That is only a rough status for now, but there are various variations possible, e.g. to reduce complexity if desired or use alternative solutions. Also, not all stages are dependent on each other, i.e. one could simulate the result of a previous stage and still get a result. We are confident that some variant of this concept would be fairly feasable and still lead to interesting results.

Next Steps

Checking out the individual modules and their feasability.

  • Herve: aggregation behavior, cell division control
  • Giorgia: quorum sensing, AND dependence
  • Dominic: cellulose, physical structures

Back to ETH Zurich main page.

Personal tools
Past/present/future years