Team:UCSC/Project

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<p> <font color="SteelBlue"> <font size = "3"><b>Biofuel</b> is growing all around us in grasses and trees, we just haven’t unlocked it yet. Our team wants to give an archea a little push to digest cellulose, the stuff that makes our paper, into biofuel for our engines. Normally a fortress of ligands keeps cellulose under lock and key. To make the cellulose accesible, we need to add an ionic solution to the plant material, which would shrivel up your typical cell. That’s where <b><i>Haloferax volcanii</i></b>  comes in. <i>H. volcanii</i>  is a halophile archea, which means it’s cozy in high salt environments. It may be the agent we need to break down the cellulose and survive the ionic solution. <i>H. volcanii</i>  can already make butanol out of cellulose. The only problem is, once it has the butanol <i>H. volcanii</i>  keeps processing it into parts for its cell membrane. We want to knock out the right gene so <i>H. volcanii</i>  won’t process the butanol. The butanol should then start piling up, and we’ll have biofuel. This biofuel will still emit CO2 but it won’t add new carbon into the climate because its carbon came from plants instead of fossil fuels. Whatever carbon we add to the climate by using biofuel will be reused on the same scale as we grow more plants that will take in CO2. We can effectively shorten the carbon cycle and stop adding to the accumulation of greenhouse gases in our atmosphere </p>
<p> <font color="SteelBlue"> <font size = "3"><b>Biofuel</b> is growing all around us in grasses and trees, we just haven’t unlocked it yet. Our team wants to give an archea a little push to digest cellulose, the stuff that makes our paper, into biofuel for our engines. Normally a fortress of ligands keeps cellulose under lock and key. To make the cellulose accesible, we need to add an ionic solution to the plant material, which would shrivel up your typical cell. That’s where <b><i>Haloferax volcanii</i></b>  comes in. <i>H. volcanii</i>  is a halophile archea, which means it’s cozy in high salt environments. It may be the agent we need to break down the cellulose and survive the ionic solution. <i>H. volcanii</i>  can already make butanol out of cellulose. The only problem is, once it has the butanol <i>H. volcanii</i>  keeps processing it into parts for its cell membrane. We want to knock out the right gene so <i>H. volcanii</i>  won’t process the butanol. The butanol should then start piling up, and we’ll have biofuel. This biofuel will still emit CO2 but it won’t add new carbon into the climate because its carbon came from plants instead of fossil fuels. Whatever carbon we add to the climate by using biofuel will be reused on the same scale as we grow more plants that will take in CO2. We can effectively shorten the carbon cycle and stop adding to the accumulation of greenhouse gases in our atmosphere </p>
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<a href="https://2014.igem.org/File:UCSC_CCycle_Fossil_Fuel.png"><img src = "https://static.igem.org/mediawiki/2014/c/c9/UCSC_CCycle_Fossil_Fuel.png" width = 350px style = "padding-left: 15px"></a>
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<a href="https://2014.igem.org/File:UCSC_CCycle_Fossil_Fuel.png"><img src = "https://static.igem.org/mediawiki/2014/c/c9/UCSC_CCycle_Fossil_Fuel.png" width = 375px style = "padding-left: 35px" ></a>
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<a href="https://2014.igem.org/File:UCSC_CCycle_Biofuel.png"><img src = "https://static.igem.org/mediawiki/2014/d/d9/UCSC_CCycle_Biofuel.png"  width = 350px style = "padding-left: 25px"></a>
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<a href="https://2014.igem.org/File:UCSC_CCycle_Biofuel.png"><img src = "https://static.igem.org/mediawiki/2014/d/d9/UCSC_CCycle_Biofuel.png"  width = 375px style = "padding-left: 25px"></a>
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<p style = "padding-left: 15px"> Compare these two carbon cycles: On the left is the current carbon cycle using fossil fuels. <br>On the right, we have the shorter cycle displaying the effect of switching to biofuel.</p>
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<p style = "padding-left: 35px"> Compare these two carbon cycles: On the left is the current carbon cycle using fossil fuels. <br>On the right, we have the shorter cycle displaying the effect of switching to biofuel.</p>
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<td > <myh3> Our Project Design </myh3></td>
<td > <myh3> Our Project Design </myh3></td>
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<td > <myh3> Protocol Examples </myh3></td>
<td > <myh3> Protocol Examples </myh3></td>
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<td > <myh3> Goals for Future Research </myh3></td>
<td > <myh3> Goals for Future Research </myh3></td>

Revision as of 21:41, 27 August 2014



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Introduction

Biofuel is growing all around us in grasses and trees, we just haven’t unlocked it yet. Our team wants to give an archea a little push to digest cellulose, the stuff that makes our paper, into biofuel for our engines. Normally a fortress of ligands keeps cellulose under lock and key. To make the cellulose accesible, we need to add an ionic solution to the plant material, which would shrivel up your typical cell. That’s where Haloferax volcanii comes in. H. volcanii is a halophile archea, which means it’s cozy in high salt environments. It may be the agent we need to break down the cellulose and survive the ionic solution. H. volcanii can already make butanol out of cellulose. The only problem is, once it has the butanol H. volcanii keeps processing it into parts for its cell membrane. We want to knock out the right gene so H. volcanii won’t process the butanol. The butanol should then start piling up, and we’ll have biofuel. This biofuel will still emit CO2 but it won’t add new carbon into the climate because its carbon came from plants instead of fossil fuels. Whatever carbon we add to the climate by using biofuel will be reused on the same scale as we grow more plants that will take in CO2. We can effectively shorten the carbon cycle and stop adding to the accumulation of greenhouse gases in our atmosphere


Compare these two carbon cycles: On the left is the current carbon cycle using fossil fuels.
On the right, we have the shorter cycle displaying the effect of switching to biofuel.



Our Project Design

Protocol Examples

Goals for Future Research