Team:ETH Zurich/Circuit

From 2013.igem.org

(Difference between revisions)
Line 4: Line 4:
<h1> Biological circuit design</h1>
<h1> Biological circuit design</h1>
-
[[File:Circuitcolisweeper2.png|800px|center|thumb|<b>Figure 1: [AHL] dependent information processing</b>]]
+
[[File:Circuitcolisweeper2.png|800px|center|thumb|<b>Figure 1: Overview of different processing states in mines and non mines that lead to different colored outputs</b>]]
<h1>Circuit explanation</h1>
<h1>Circuit explanation</h1>
<div class="collapsibleContainer" title="Click here to expand">
<div class="collapsibleContainer" title="Click here to expand">

Revision as of 16:00, 28 October 2013

Header2.png
80px-Eth igem logo.png

Contents

Biological circuit design

Figure 1: Overview of different processing states in mines and non mines that lead to different colored outputs

Circuit explanation

Signal production by mine cells (sender cells)

Mine colonies constitutively express the "mine-cell reporter” hydrolase nagZ that reacts with the specific substrate in the multi-substrate solution to produce a chromogenic product. The colony turns blue, indicating that the colony is a mine and hence the game ends. At the same time, the mine colony is a sender module of AHL. LuxI is expressed constitutively and synthesizes the AHL signaling molecule. This means that the mine continuously produces AHL, that radially diffuses out to neighboring colonies. The signaling molecule AHL is processed by the receiver cells (also see below).



Information processing in non-mine cells (receiver cells)
Processing the AHL


1. Receiver cells respond to low AHL levels: If one mine cell is close to a non-mine colony and AHL diffusion takes place to reach the non-mine colony. Due to a high-pass filter using the LuxR system in the non-mine colony, low concentrations of AHL are detected and activate a reporter. Addition of the multi-substrate to this colony produces a salmon color, which indicates one mine is adjacent to the colony just played.

The wild type promoter [http://parts.igem.org/Part:BBa_R0062 BBa_R0062 PLuxR] is used for the detection of low AHL concentrations and therefore becomes activated when one mine cell is in the vicinity of the receiver cell. Then the wild type promoter induces the expression of gusA, a hydrolase able to convert a specific substrate to a visible red output.




2. Receiver cells respond to high AHL levels: If there are two or more mine colonies adjacent to a non-mine colony, a higher concentration of diffused AHL will be processed by the receiver colony. The LuxR system works as a high-pass filter again and induces the expression of another reporter to show that two or more mines surround the selected colony. Addition of the multi-substrate to this colony produces a magenta color which indicates that more than one mine is adjacent to this colony.

The mutated promoter [http://parts.igem.org/Part:BBa_K1216007?title=Part:BBa_K1216007 PluxR BBa_K1216007] was to less sensitive for our system, therefor we did partial sensitivity recovery by rational design to cover all possible "backmutations" (7 different promoters) of the [http://parts.igem.org/Part:BBa_K1216007?title=Part:BBa_K1216007 PluxR BBa_K1216007]. The model predicted from EC50 that the Single Mutant 1 (SM1) would fit to the required promoter characteristics (predicted by the analytical solution for the EC50) and will be used in our final set-up to only respond to high concentrations of AHL and therefore be activated, when two sender cells are surrounding the receiver cell, and expressing the aes hydrolase responsible for the colorimetric conversion of the specific substrate to a visible purple output.


3. Receiver cells signal with no mines in their vicinity. If there is no mine adjacent to a non-mine colony, no AHL is processed. Only the constitutive hydrolase phoA is expressed, which upon addition of the multi-substrate will produce a chromogenic compound. This indicates that there are no mines adjacent to this colony and the game can be continued.

Flagging
Placing a flag on a mine prevents the mine from detonating and is a visual help for the player.
Option 1 : We have implemented this feature of the computer game in Colisweeper. If the player is sure about a colony to be a mine, a second single substrate can be added on to this colony. All colonies express the native hydrolase lacZ reporter for flagging, a green colored product indicates a flagged colony. But remember, flagging does not reveal any information about mines in neighboring colonies.
Option 2: We implemented a second way of flagging, which is in contrast to the LacZ flagging, removable. THis is done by addind a Remazol blue dye to the colony which immediately became blue. The color can be removed within minutes by addind a laccase.

Circuit optimization


Already the data from the first experiments with GFP showed that the most important challenge in our circuit design would be to solve the problem of basal reporter expression and accumulation in the receiver cells. The reporter expression has to be minimal in the case where no mine colonies are around. Especially because we use an enzymatic reporter system with a multiple turnover of substrate this is crucial. With the GFP proof of concept experiments we could show that the basal expression is in fact quite low already with the simple PLac-LuxR-pLuxR-GFP receiver cell set-up. But early experiments replacing GFP with a hydrolase showed that the leakiness of the system is nevertheless too high. Hydrolase reporters are enzymatic systems. Multiple rounds of catalysis provide intrinsic signal amplification when compared to GFP. Therefore we observe a much higher sensitivity to basal expression. Moderate hydrolase expression levels can already result in total substrate conversion and signal saturation. In a first set of experiments we tried to identify the source of the leaky basal expression. Right after that we designed different variations of the first circuit that could be used to minimize the leakiness. We came up with three different strategies to approach the problem.


1. Introduction of a positive feedback loop to reduce LuxR
The first idea was to replace the constitutive LuxR expression with an AHL dependent induction. Using a self-regulation motif, only a residual amount of LuxR is present in the non-induced state, minimizing its interaction with the promoter. Upon induction the LuxR protein sustains its own production allowing for a full activation of the system. To achieve autoregulation one possibility is to use a direct positive feedback loop in which the luxR gene is placed under its own PLuxR promoter(Figure 2, center). Only upon induction with AHL LuxR would be produced. As an alternative we could use LacI expression to inhibit LuxR production in the uninduced state. By placing the lacI gene under a negatively LuxR/AHL regulated promoter (PLuxL) an indirect positive autoregulation for LuxR expression is obtained(Figure 2, right). For details and results please see the results page here.

Figure 2: Possible strategies to reduce basal LuxR expression using positive feedback loops.


2. Fine-tuning of the pLac driven LuxR using glucose
A second strategy could be to use the cells native LacI repressor to repress the PLac promoter driving LuxR in our receiver construct. Addition of glucose to the pre-culture medium and/or to the agar plates could repress the expression of LuxR to a level below the one necessary for basal reporter expression, whereas in the induced state there would still be enough LuxR to activate the system.

3. Destabilization of the enzymatic reporters with degradation tags
A third idea to minimize basal hydrolase activity would be to destabilize the reporter proteins with degradation tags. By lowering the half-life the accumulation of reporter could be reduced during incubation time. However we did not get to test this approach experimentally, but we analyzed the impact of such a degradation tag using our system model.