Team:SDU-Denmark/project-t

From 2010.igem.org

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(Retinal production)
(Retinal Generator)
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Many plants and microbes have complete retinal biosynthesis pathways integrated into their genomes, to help drive their rhodopsins. In these organisms rhodopsins play an essential role, not only in photosensation but also directly in energy production, in fact in some organisms rhodopsins are used to create proton motive force directly by pumping protons out into the extracellular space using light energy to drive the process. Humans and other animals on the other hand often only have enzymes coding for the final steps of the pathway, more on which later. They rely on a supply of retinal precursors or Vitamin A (a group consisting of retinal and it's metabolites) in their diet. This is why Vitamin A defficiency causes night-blindness as an early symptom in humans.<br><br>
Many plants and microbes have complete retinal biosynthesis pathways integrated into their genomes, to help drive their rhodopsins. In these organisms rhodopsins play an essential role, not only in photosensation but also directly in energy production, in fact in some organisms rhodopsins are used to create proton motive force directly by pumping protons out into the extracellular space using light energy to drive the process. Humans and other animals on the other hand often only have enzymes coding for the final steps of the pathway, more on which later. They rely on a supply of retinal precursors or Vitamin A (a group consisting of retinal and it's metabolites) in their diet. This is why Vitamin A defficiency causes night-blindness as an early symptom in humans.<br><br>
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====Retinal Biosynthesis====
 
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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 its own, by transferring the gene for the enzyme that cleaves beta-carotene to retinal from flies (drosophila melanogaster). For the accumulation of beta-carotene we will use the biobrick 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:<br><br><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>
 
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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 its signalling function can be coupled to other pathways than chemotaxis.<br><br>
 
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=== BioBrick design ===
 
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SopII-HtrII-Tsr fusion,chimer coding sequence: [http://partsregistry.org/Part:BBa_K343003 K343003]<br>
 
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Photosensor generator: [http://partsregistry.org/Part:BBa_K343007 K343007]<br><br>
 
==== Retinal biosynthesis ====
==== Retinal biosynthesis ====
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=== The effect of retinal on the system ===
 
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=== Characterizing the retinal BioBrick ===
=== Characterizing the retinal BioBrick ===
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=== Further use of the retinal BioBrick ===
=== Further use of the retinal BioBrick ===
==== Role in light-based signal transduction ====
==== Role in light-based signal transduction ====
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Retinal plays an essential role in photosensing in both eukaryotes as well as bacteria and archaea. All work with rhodopsins and proteorhodopsins will need a retinal supply to function. This supply might come from the external environment, but it is an appealing thought that we might be able to supply the retinal from an internal source. Our project centers around phototaxis, but other constructs combining photorhodopsins with other membrane associated tyrosine kinases may also be imagined, opening vast posibilities for regulation of phopsphorylation cascades using light as input. In such systems, retinal biosynthesis could play a very valuable role.<br>
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Since retinal plays such an essential role in photosensing in both eukaryotes as well as bacteria and archaea, all work with rhodopsins and proteorhodopsins will need a retinal supply to function. This supply might come from the external environment, but it is an appealing thought that we might be able to supply the retinal from an internal source. Our project centers around phototaxis, but other constructs combining photorhodopsins with other membrane associated tyrosine kinases may also be imagined, opening vast posibilities for regulation of phopsphorylation cascades using light as input. In such systems, retinal biosynthesis could play a very valuable role.<br>
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==== Physiological functions functions in higher animals ====
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Vitamin A (retinal and related metabolites such as retinol) are important nutrients in humans and animals. Vitamin A is important in many physiological processes including regulation of gene transcription, skin and teeth maintenance, prenatal development and vision. <br>
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==== Global health issues ====
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Vitamin A deficiency is a serious global problem, estimated to affect one in three children under the age of five around the world according to WHO()
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== Hyperflagellation ==
== Hyperflagellation ==

Revision as of 16:06, 25 October 2010