Team:SDU-Denmark/project-t

From 2010.igem.org

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In this section we will review the theory behind our approach to establishing a flow through a microtube.  
In this section we will review the theory behind our approach to establishing a flow through a microtube.  
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===Phototaxis===
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== Phototaxis ==
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'''Background:'''
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=== Background: ===
We want to be able to control, switching on and off, our flow through a remote signal. Our preferred signal is light, since light does not have any effect on the rest of the system and only interacts with the membrane receptor in E.Coli. This means that the probability of unwanted side effects is minimized, since there are no excess interactions between the signal and its target environment. <br><br>
We want to be able to control, switching on and off, our flow through a remote signal. Our preferred signal is light, since light does not have any effect on the rest of the system and only interacts with the membrane receptor in E.Coli. This means that the probability of unwanted side effects is minimized, since there are no excess interactions between the signal and its target environment. <br><br>
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<br> We will only have to add retinal to the system, which is needed for proper function of the fusion,chimera-protein. Therefore we want E.Coli to produce retinal on it's own, by transferring the gen for the enzyme that cleaves beta-carotene to retinal from flies (drosophilia). For the accumulation of beta-carotene we will use the biobrick BBa_K274210, which was constructed by the Cambridge team in 2009 [https://2009.igem.org/Team:Cambridge]. We will expand this brick's functionality by coupling it with the enzyme that cleaves beta-carotene to retinal. In that way we will be able to construct a retinal generator with the help of Cambridge's and our part. Here is a model of the retinal generator:<html><img width="600px" height="400px" src="https://static.igem.org/mediawiki/2010/c/cb/Team-SDU-Denmark-Retinal_generator.png"></img></html><br><br>  
<br> We will only have to add retinal to the system, which is needed for proper function of the fusion,chimera-protein. Therefore we want E.Coli to produce retinal on it's own, by transferring the gen for the enzyme that cleaves beta-carotene to retinal from flies (drosophilia). For the accumulation of beta-carotene we will use the biobrick BBa_K274210, which was constructed by the Cambridge team in 2009 [https://2009.igem.org/Team:Cambridge]. We will expand this brick's functionality by coupling it with the enzyme that cleaves beta-carotene to retinal. In that way we will be able to construct a retinal generator with the help of Cambridge's and our part. Here is a model of the retinal generator:<html><img width="600px" height="400px" src="https://static.igem.org/mediawiki/2010/c/cb/Team-SDU-Denmark-Retinal_generator.png"></img></html><br><br>  
In the end we want to split the whole fusion, chimer into two biobricks that can be fused as a composite part. By doing this we hopefully introduce biobricks that give E.Coli phototaxic abilities and also introduce modularity into the complex, so that it's signalling function can be coupled to other pathways than chemotaxis.<br><br>
In the end we want to split the whole fusion, chimer into two biobricks that can be fused as a composite part. By doing this we hopefully introduce biobricks that give E.Coli phototaxic abilities and also introduce modularity into the complex, so that it's signalling function can be coupled to other pathways than chemotaxis.<br><br>
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'''Biobrick design:'''
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=== Biobrick design: ===
Retinal generator biobrick: BBa_K343002 (Sandboxed)<br>
Retinal generator biobrick: BBa_K343002 (Sandboxed)<br>
SopII-HtrII-Tsr fusion,chimer coding sequence: BBa_K343003 (Sandboxed)<br><br>
SopII-HtrII-Tsr fusion,chimer coding sequence: BBa_K343003 (Sandboxed)<br><br>
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=== Hyperflagellation ===
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== Hyperflagellation ==
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'''Background:'''<br>
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=== Background: ===<br>
To maximize the microflow system's effectivity, we want to increase the force each single bacterium can generate. Since the main motor for the flow is the flagellum we will have to modify this factor for increasing the force. Flagella in E.Coli rotate at a maximum speed around 6000 rpm, which can not easily be exceeded. So if we wanted to increse the generated force we would have to opt for more flagella on the surface of our bacteria, instead of faster flagella. This is called hyperflagellation, which is a process that is not all too well studied in normally-flagellated coli, so we will have to test it out.<br>
To maximize the microflow system's effectivity, we want to increase the force each single bacterium can generate. Since the main motor for the flow is the flagellum we will have to modify this factor for increasing the force. Flagella in E.Coli rotate at a maximum speed around 6000 rpm, which can not easily be exceeded. So if we wanted to increse the generated force we would have to opt for more flagella on the surface of our bacteria, instead of faster flagella. This is called hyperflagellation, which is a process that is not all too well studied in normally-flagellated coli, so we will have to test it out.<br>
The way we are hoping to achieve the hyper flagellation is bz upregulating the FlhD,C operon. This operon is the master regulator of flagella expression, which is controlled by three classes of regulons. The products of FlhD,C regulate the transcription of the class II factors, which in turn again regulate class III, FliC, the major subunit in flagella. Since FlhD,C is sitting on top of the regulating cascade we want to overexpress it, so that we will get an increase in flagellar count.<br>
The way we are hoping to achieve the hyper flagellation is bz upregulating the FlhD,C operon. This operon is the master regulator of flagella expression, which is controlled by three classes of regulons. The products of FlhD,C regulate the transcription of the class II factors, which in turn again regulate class III, FliC, the major subunit in flagella. Since FlhD,C is sitting on top of the regulating cascade we want to overexpress it, so that we will get an increase in flagellar count.<br>
The way we are going to achieve that is by isolating the operon from an E.Coli and inserting the coding sequence into a biobrick where we can control both the ribosome binding site and the type of promoter. We are going to use a constitutive promoter, so that flagella will be constantly expressed. The effects of this on other areas of the organism like the cell cycle are not entirely clear, but we will first try to overxpress the operon and then analyse the effect on the cells behavior.<br><br>
The way we are going to achieve that is by isolating the operon from an E.Coli and inserting the coding sequence into a biobrick where we can control both the ribosome binding site and the type of promoter. We are going to use a constitutive promoter, so that flagella will be constantly expressed. The effects of this on other areas of the organism like the cell cycle are not entirely clear, but we will first try to overxpress the operon and then analyse the effect on the cells behavior.<br><br>
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'''Biobrick design:'''<br>
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=== Biobrick design: ===<br>
FlhD,C coding sequence: BBa_K343000 (Sandboxed)
FlhD,C coding sequence: BBa_K343000 (Sandboxed)

Revision as of 17:55, 3 July 2010