Team:ETHZ Basel/Biology

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== Overview ==
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= Biology & Wet Laboratory: Overview =
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The goal of our iGEM project E.lemming is to take over the control of the tumbling frequency of ''E. coli''. This is achieved by reversibly localizing certain elements of the chemotactic pathway (che-proteins) and thus affecting their activity.
 
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For localization we use the PhyB-PIF3 system found in plants. PhyB or PIF3 is fused to a che-protein while the other one is fused to a localized protein (localizer) within the cell. Upon a light stimulus of a certain wavelength PhyB is activated, binds PIF3 and thereby localizes the che-protein. A light stimulus of a different wavelength reverses this process.
 
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<br>In order to increase the probability that the system will work we will try out a lot of combinations of several proteins:
 
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*che-proteins: cheY, cheB and cheR
 
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*localizer: trigger factor (binds the ribosome), MreB (actin analogue), tetR (binds tetO)
 
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The goal of the wet lab team is to implement this localization system into ''E. coli''.
 
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<html>
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<div class="thumb tright"><div class="thumbinner" style="width:402px;">
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<iframe title="YouTube video player" class="youtube-player" type="text/html" width="400" height="325" src="http://www.youtube.com/embed/yQdX8o8i_uc?hd=1" frameborder="0"></iframe>
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<div class="thumbcaption"><div class="magnify"><a href="http://www.youtube.com/watch?v=yQdX8o8i_uc?hd=1" class="external" title="Enlarge"><img src="/wiki/skins/common/images/magnify-clip.png" width="15" height="11" alt="" /></a></div><b>Molecular mechanism of E. lemming.</b> A light-sensitive dimerizing complex fused to proteins of the chemotaxis pathway at a spatially fixed location is induced by light pulses and therefore localization of the two molecules can be manipulated.</div></div></div>
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</html>
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== Cloning strategy ==
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The core idea of E. lemming is based on the '''spatial localization''' of one of the species of the chemotaxis network, so called '''Che proteins'''. Phosphorylated CheY (further referred to as CheYp) binds to the flagellar motor protein FliM, where it induces tumbling. Our research aimed at gaining control over this molecular switch and thus over the [https://2010.igem.org/Team:ETHZ_Basel/Modeling/Movement flagellar machine]. Through localizing (intracellular anchoring), the effective concentration of the free cytosolic CheY protein is decreased at its site of action, greatly affecting the activity on its downstream partners. Anchoring is achieved with the help of '''light-sensitive proteins (LSPs)''' that dimerize upon a light signal (photodimerization). The Che protein is fused to LSP1, while its binding partner LSP2 is itself fused to a so called '''anchor protein'''. Dimerization of the two LSPs into an LSP1/LSP2 complex, where LSP1 is still bound to CheY, results in spatial re-localization of the Che protein, which, as a final measurable output, induces a change in the ratio between tumbling and directed flagellar movement. The general idea is nicely represented by the video on the right side. Read more about the [[Team:ETHZ_Basel/Biology/Molecular_Mechanism|'''Molecular mechanism''']].
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As we plan to generate several fusion proteins with different linkers, we decided to use the cloning strategy BBF RFC 28: A method for combinatorial multi-part assembly based on the Type IIs restriction enzyme AarI (http://dspace.mit.edu/handle/1721.1/46721).
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A second approach for the design of E. lemming is the usage of a photoreceptor connected to the bacterial chemotaxis system. Find out more about the [[Team:ETHZ_Basel/Biology/Archeal_Light_Receptor|'''Archeal Light Receptor''']] that enabled us to '''successfully''' implement the light-inducible synthetic network via the fusion of archeal and eubactarial parts.  
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The advantage of this strategy is that we can clone up to 3 different inserts into one vector simultaneously in a 96 well format.
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== Parts ==
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The fusion proteins were constructed according to the [[Team:ETHZ_Basel/Biology/Cloning|'''Cloning Strategy BBF RFC28''']], a method for the combinatorial multi-part assembly based on the type II restriction enzmye AarI.
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<br>Currently we are working on putting all the BioBricks into a storage vector. The image shows all the constructs we plan to clone.[[Image:Constructs.jpg|200px|thumb|none|fusion proteins]]
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In the section [[Team:ETHZ_Basel/Biology/Implementation|'''Implementation''']], you find details on the experimental design such as the ideal conditions for the observation of chemotaxis behavior (strain, media, growth temperature, growth phase etc.) and the functionality and expression level assays of the fusion proteins. We also provide you with some lab impressions.
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Of course, we also reflected a lot about [[Team:ETHZ_Basel/Biology/Safety|'''Human Practices and Safety''']] during our project, because knowledge also means responsibility. This section summarizes our findings on potential risks and safety issues and the measures we have taken in order to work as safely as possible.
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== working process ==
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=== generation of parts ===
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==== generation of storage vectors ====
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We use the vector pSEVA of Victor de Lorenzo's lab. It has a kanamycin resistance and a BBR1 origin.
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The working process for the generation of the storage vectors is as follows:
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<br>Ordering of primers (if template is available) -> PCR -> clean-up of PCR product -> ligation into storage vector -> transformation of competent cells -> plating of cells -> selection of clones (blue-white-screening) -> sequencing
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<br>For proteins for which no template is available we let the let the genes synthesize directly.
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{| border="1"
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|+ subparts
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! Protein !! terminus on fusion !! status
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|-
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! CheY
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| N || clone selection
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|-
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! CheY
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| C || clone selection
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|-
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! CheR
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| N || clone selection
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|-
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! CheR
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| C || clone selection
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|-
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! CheB
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| N || clone selection
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|-
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! CheB
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| C || clone selection
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|-
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! TrigF
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| N (binds N-terminal to ribosome) || primers ordered
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! MreB
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| N || primers ordered
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! MreB
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| C || primers ordered
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! tetR
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| N || PCR
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! tetR
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| C || PCR
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|-
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! PhyB
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| N || primers ordered
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|-
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! PhyB
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| C || primers ordered
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|-
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! PhyB
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| N || primers ordered
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! PhyB
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| C || primers ordered
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! PIF3
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| N || primers ordered
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! PIF3
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| C || primers ordered
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! YFP
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| N || PCR
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! YFP
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| C || PCR
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! GFP
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| N ||
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! GFP
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| C ||
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|}
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==== generation of acceptor vectors ====
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==== testing of parts ====
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=== generation of ''E. coli'' mutants ===
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== Experimental Plan ==
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[[Image:100729_time plan.jpg|thumb|none|200px|experimental plan]]
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Latest revision as of 16:39, 2 March 2011

Biology & Wet Laboratory: Overview

Molecular mechanism of E. lemming. A light-sensitive dimerizing complex fused to proteins of the chemotaxis pathway at a spatially fixed location is induced by light pulses and therefore localization of the two molecules can be manipulated.

The core idea of E. lemming is based on the spatial localization of one of the species of the chemotaxis network, so called Che proteins. Phosphorylated CheY (further referred to as CheYp) binds to the flagellar motor protein FliM, where it induces tumbling. Our research aimed at gaining control over this molecular switch and thus over the flagellar machine. Through localizing (intracellular anchoring), the effective concentration of the free cytosolic CheY protein is decreased at its site of action, greatly affecting the activity on its downstream partners. Anchoring is achieved with the help of light-sensitive proteins (LSPs) that dimerize upon a light signal (photodimerization). The Che protein is fused to LSP1, while its binding partner LSP2 is itself fused to a so called anchor protein. Dimerization of the two LSPs into an LSP1/LSP2 complex, where LSP1 is still bound to CheY, results in spatial re-localization of the Che protein, which, as a final measurable output, induces a change in the ratio between tumbling and directed flagellar movement. The general idea is nicely represented by the video on the right side. Read more about the Molecular mechanism.

A second approach for the design of E. lemming is the usage of a photoreceptor connected to the bacterial chemotaxis system. Find out more about the Archeal Light Receptor that enabled us to successfully implement the light-inducible synthetic network via the fusion of archeal and eubactarial parts.

The fusion proteins were constructed according to the Cloning Strategy BBF RFC28, a method for the combinatorial multi-part assembly based on the type II restriction enzmye AarI.

In the section Implementation, you find details on the experimental design such as the ideal conditions for the observation of chemotaxis behavior (strain, media, growth temperature, growth phase etc.) and the functionality and expression level assays of the fusion proteins. We also provide you with some lab impressions.

Of course, we also reflected a lot about Human Practices and Safety during our project, because knowledge also means responsibility. This section summarizes our findings on potential risks and safety issues and the measures we have taken in order to work as safely as possible.