Team:Valencia Biocampus/Project

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    <li class="active"><a href="#Project">Project Overall</a></li>
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      <li class="active"><a href="#Project">Project Overview</a></li>
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    <li><a href="#Coli">Escherichia coli</a></li>
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      <li><a href="#Coli"><i>Escherichia coli</i></a></li>
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    <li><a href="#Pseudomonas">Pseudomonas putida</a></li>
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      <li><a href="#Pseudomonas"><i>Pseudomonas putida</i></a></li>
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    <li><a href="#Elegance">Caenorhabditis elegans</a></li>
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      <li><a href="#Elegans"><i>Caenorhabditis elegans</i></a></li>
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      <li><a href="#Results">Results</a></li>
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      <li><a href="#Parts">Biobricks</a></li>
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      <li><a href="#Notebook">Notebook</a></li>
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== Project Overall==
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== Project Overview==
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Bacteria are essential in biotechnology, but they can hardly move. Nematodes, such as <i>Caenorhabditis elegans</i>, are fast crawling organisms, but they have limited biotechnological applications. By combining the best from both organisms, we present the first artificial synthetic symbiosis with bacteria engineered to ride on worms, which concentrate in hotspots where bacteria perform a desired biotechnological process, such as bioplastic (PHA) production. We have engineered <i>Pseudomonas putida</i> with a whole operon that allows the formation of a biofilm on the worm. Biofilm formation is switched on and off depending on the media, and thus bacteria get on and off the worm like travellers on a bus. We have also engineered a third partner, <i>Escherichia coli</i>, to express an interference RNA that promotes clumping. Taken together, our artificial symbiosis allows biotechnologically interesting bacteria to travel on nematodes, reach nutrient-rich biomass spots and maximize the efficiency of biotechnological fermentations in heterogeneous substrates.
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</div>
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<iframe src="//player.vimeo.com/video/75885404" style="float:right;width:340px;height:240px;padding-top:10px;" frameborder="0" wmode="Opaque" webkitallowfullscreen mozallowfullscreen allowfullscreen ></iframe>
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Explain your project
 
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== Project - Coli==
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==Why ''E.coli''==
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<p>
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    <b><i>Escherichia coli</i></b>
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    is a model organism widely used in fields such as microbiology, molecular biology and genetics. Because of this, there is a great range of genetic manipulation
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    techniques related with this Gram negative bacterium. There is also a lot of information about the biochemistry and genetics of this
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    microorganism. All this allows us to work easily with it in the lab and perform assays testing different conditions that will be tried out in other
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    organisms unstudied in such depth. Moreover, <i>E.coli</i> is the main food of <i>C.elegans</i>, organism that is able to incorporate nucleic acids from the
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    bacteria, RNA, to its cells (Mello et al., 2004). This is the usual mechanism to transform C.elegans, introducing exogenous genetic material from
 +
    the bacteria and altering the expression of the worm’s genome in order to make modifications of interest.
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</p>
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 +
<h2>Controlling the mechanism</h2>
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<p>
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    The role of <i>E.coli</i> in our project is to carry out the synthesis of an iRNA to induce the social feeding behaviour of <i>Caenorhabditis elegans</i>
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  , the <b>clumping. </b>To achieve this, we cloned the biobrick Bba_K1112000 in <i>E.coli</i>, </b></i><b>XL1-Blue strain (fig. 1). </b>
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</p>
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<div style="clear:both;width:100%;height:auto;overflow:auto;">
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<img src="https://static.igem.org/mediawiki/2013/4/46/Vlc_biocampus_ecoli_ov1.png" style="float:left" />
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<div style="float:left;width:650px;padding-left:15px;clear:right;">
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<p>
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    <b> Fig. 1.</b>
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</p>
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<ul style="padding-left:25px">
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<li>
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    <b>pSB1C3</b> is a high copy number plasmid (RFC [10]) carrying chloramphenicol resistance.
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</li>
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<li>
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    The replication origin is a <b>pUC19-derived pMB1 </b>(copy number of 100-300 per cell).
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</li>
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<li>
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    pSB1C3 has terminators bracketing its MCS which are designed to prevent transcription from *inside* the MCS from reading out into the vector. The
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    efficiency of these terminators is known to be &lt; 100%. Ideally we would construct a future set of terminators for bracketing a MCS that were 100%
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    efficient in terminating both into and out of the MCS region.
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</ul>
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<div class="cleafix"></div>
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<p>
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This<b> construction</b> consists of the <i>E.coli </i>fadA promoter, which is <b>activated in the presence of fatty acids</b> (Clark, 1981), and the
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    antisense sequence of the mRNA <i>FLP-21 </i>from <i>C.elegans</i> which encodes a protein involved in the solitary feeding behaviour of the worm, the formation
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    of the dsRNA complex inhibits the expression of this protein, inducing the social feeding behaviour (<b>fig. 2)</b>.
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</p>
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<p style="text-align:center">
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  <img src="https://static.igem.org/mediawiki/2013/f/fa/Vlc_biocampus_ecoli_ov2.png" alt="Fig.2" style="width:700px" />
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</p>
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==''Pseudomonas putida'' and PHA production==
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<p>
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<b><i>Pseudomonas putida</i> </b> is a gram-negative bacterium that is found in most soil and water habitats where there is oxygen. Its diverse metabolism and its capacity to break down
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    organic harmful solvents (most of its genes are involved in degrading aromatic or aliphatic hydrocarbons) in contaminated soils make this microorganism
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    irreplaceable for research studies in the field of bioremediation but also for biosynthesis of value-added products. In addition, <i>Pseudomonas putida</i> has several strains including KT2440, the one we have worked with. This strain can colonize plant roots, from which they take nutrients, while at the same time it offers protection for the plant against pathogens.
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</p>
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Risas
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<p>
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For example, it is capable of converting <a href="http://en.wikipedia.org/wiki/Styrene" target="_blank">styrene</a> oil into the <b><a href="http://en.wikipedia.org/wiki/Biodegradable_plastic" target="_blank">biodegradable <a href="http://en.wikipedia.org/wiki/Polyhydroxyalkanoates" target="_blank">PHA</a> plastic</a> </b>. This helps the degradation of the polystyrene foam which
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     was thought to be non-biodegradable. Styrene is a major environment toxic pollutant released from industrial sites. The conversion to PHA allows the cure
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    of styrene pollution but it is also beneficial for society because of its applications in tissue engineering.
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<br/>
 +
PHA is also environmentally friendly and has a long self-life therefore it is also used in everyday items. Unlike styrene, PHA can break down in soil or water.
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</p>
 +
<p>
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    Within <i>Pseudomonas putida</i>, PHA accumulates under unbalanced growth conditions as a means of intracellular storage, storing excess carbon and energy.
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    These PHA polymers are synthesized by the enzyme PHA synthase which is bound to the surface of the PHA granules and uses coenzyme A thioesters of
 +
    hydroxyalkanoic acids as substrates.
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<img src="https://static.igem.org/mediawiki/2013/9/9e/Vlc_biocampus_Pseudomonas_overview.jpg" alt="P. putida" style="float:left;margin-left:50px;width:300px" />
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<p>
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    The role of <i>P. putida </i>in the Synthetic symbiosis that we have designed is to be carried by <i>C. elegans </i>to hotspots of interest where it would
 +
    produce bioplastic, PHA.
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</p>
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</div><div class="tab-pane fade" id="Elegans">
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<h2>An overview about our nematode</h2>
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<p>
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  One of the main characters of our work is a nematode known as <b><i>Caenorhabditis elegans, </i></b>from the Rhabditidae family. It was first used as an
 +
  experimental model in Developmental Genetics studies and nowadays it is also used in other fields such as Clinical Biology, Neurobiology and Cell Biology,
 +
  being a good model to study Alzheimer disease, obesity, diabetes and aging, among others.
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</p>
 +
<p>
 +
  Another interesting thing is that it feeds on <b><i>Escherichia coli</i></b>. Its “favorite” strain is OP50, although we checked that it’s also able to
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  feed on <b>XL1-Blue strain</b>, the one that we used in all our molecular biology experiments.
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</p>
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<p>
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  Some advantages of C. elegans when compared with other model organisms are:
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</p>
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<ul style="list-style: url('https://static.igem.org/mediawiki/2013/b/b9/Vlc_biocampus-bullet_list-small.png');display:block;width:420px;padding-left:50px;padding-right:40px;float:left;">
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<li>
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    Lifespan ranges between 2 and 3 weeks, so experimentation times are reduced.
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</li>
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<li>
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    Its maintenance and study is cheap and simple (it is transparent, which facilitates microscopic observation).
 +
</li>
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<li>
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    It is very small (1 mm), so it is possible to carry out experiments with a huge number of worms in a small Petri dish having a great statistical support.
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</li>
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</ul>
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<img src="https://static.igem.org/mediawiki/2013/4/46/C_elegans_overview.jpg" alt="C. elegans" style="height:180px;" />
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<div class="clearfix"></div>
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<p>
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  <h2>Why use <i>C. elegans</i> as a transport?</h2>
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</p>
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<p>
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  When we were considering on creating a new system for the transport of bacteria, we found different key advantages that made the nematode the best option.
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  For example, <i>C. elegans</i> is able to move very fast around solid substrates (soil actually is its natural habitat) and also in agar, so it’s very
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  useful for both lab experiments and real-environment tests.
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</p>
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<p>
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  Its movement, in addition to being very fast, has two modes: <b>random </b>and <b>directed.</b>
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</p>
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<p>
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When there is no attractant in the medium, <i>C. elegans</i> moves doing uncoordinated movements in several directions in what is known as  <b>'random walk'.</b>
 +
</p>
 +
<p>
 +
  The situation changes when there is an attractant in the medium. Here, our 'transport system' begins to direct its movements to the focus of the substance
 +
  (volatile or soluble) which acts as an attractant in a process known as <b>'chemotaxis'</b> thanks to the amazing sense of smell of our nematode. This allows us to
 +
  ‘guide’ the nematodes <b>towards defined spots in irregular substrates.</b>
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</p>
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<p>
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Chemotaxis is the foundation to guide the transport of bacteria and is therefore the focus of experimentation with <i>C. elegans</i>, with <b>the aim of finding the best attractant.</b> This ability makes <i>C. elegans </i>a perfect 'bus' for bacteria.  <b>(<a href="https://2013.igem.org/Team:Valencia_Biocampus/Simuelegans-Chemotaxis">simuelegans online here</a>)</b>
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</p>
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<p>
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  Moreover, we found two pathogens (<i>Yersinia pestis</i> and <i>Xhenorhabus nematophila</i>) with the ability to form biofilms on <i>C. elegans</i> thanks
 +
to the proteins of the <b>operon hmsHFRS.</b> When genetically-engineered strains of commonly used bacteria such as <i>Escherichia coli</i> or  <i>Pseudomonas</i> <i>putida</i> express this hmsHFRS operon, they have the 'ticket' to travel: they are able to adhere to the worm’s surface by means of
 +
  forming a synthetic biofilm.
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</p>
 +
<p>
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<h2>Expanding our knowledge about <i>C. elegans</i>...</h2>
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</p>
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<p>
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  Once we knew that <i>C. elegans</i> was the best option, we began to discover interesting things for further study.
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</p>
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<p>
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  There are several strains of our nematode. The one that drew our attention was called 'N2', which had a fairly interesting behaviour: under normal
 +
  conditions, it eats individually, whereas under certain conditions (such as starvation), a social feeding behaviour known as <b>“clumping”</b> is induced.
 +
But this phenomenon can also be induced if the expression of some particular genes is interfered. This fact gave us the opportunity to develop the  <b>first artificial symbiosis between worms and bacteria</b>, based on the manipulation of the behaviour of <i>C. elegans</i> by simply nourishing it with
 +
  transformed <i>E.coli </i>able to synthesize the iRNA.
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</p>
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<p>
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  <b>With it, while<i> C. elegans </i>acts as transport, bacteria return the favour giving it the ability to eat in company. </b>
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</p>
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<p style="text-align:center">
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<img src="https://static.igem.org/mediawiki/2013/f/fc/Vlc_biocampus_c_elegans2.jpg" alt="" />
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</p>
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<div class="tab-pane fade" id="Results">
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<p>
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We have created a <b>Results Section</b> to organise our results depending on the activity they belong to (<b>The Riding, The Calling, The Clumping and The Building</b>) in order to make it more intuitive.
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</p>
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<p style="text-align:center">
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  <a href="https://2013.igem.org/Team:Valencia_Biocampus/Results" class="btn btn-primary">Go to Results section</a>
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</p>
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<div class="tab-pane fade" id="Parts">
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== Parts ==
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<p>
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These are the BioBricks we have designed, constructed, and characterized. We have submitted them to the <a href="http://parts.igem.org/Main_Page">Registry of Standard Biological Parts</a>
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</p>
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<br/>
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<!--An important aspect of the iGEM competition is the use and creation of standard  biological parts. Each team will make new parts during iGEM and will place them in the [http://partsregistry.org Registry of Standard Biological Parts]. The iGEM software provides an easy way to present the parts your team has created . The "groupparts" tag will generate a table with all of the parts that your team adds to your team sandbox.  Note that if you want to document a part you need to document it on the [http://partsregistry.org Registry], not on your team wiki.
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Remember that the goal of proper part documentation is to describe and define a part such that it can be used without a need to refer to the primary literature. The next iGEM team should be able to read your documentation and be able to use the part successfully. Also, you should provide proper references to acknowledge previous authors and to provide for  users who wish to know more.
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<groupparts>iGEM013 Valencia_Biocampus</groupparts>
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-->
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<table class="table-modeling" border="0" style="background-color: #FFFFFF;" width="950">
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    <thead>
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        <tr>
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            <th> Works? </th>
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            <th> Name </th>
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            <th> Type </th>
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            <th> Description </th>
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            <th> Designer </th>
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            <th> Length </th>
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            <th> Fav </th>
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        </tr>
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    </thead>
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        <td><img class="table-check" src="https://static.igem.org/mediawiki/2013/0/01/CheckIcon.gif" alt="Yes" height="24" width="24"/></td>
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        <td> <a href="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1112000">BBa_K1112000</a> </td>
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        <td> Regulatory </td>
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        <td> fadB promoter + FLP-21 iRNA </td>
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        <td> Pedro Luis Dorado Morales </td>
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        <td> 344 </td>
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        <td> <img src="https://2013.igem.org/common/tablesorter/themes/groupparts/heart13.gif" alt="" /></td>
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    </tr>
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    <tr>
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        <td><img class="table-cross" src="https://static.igem.org/mediawiki/2013/0/01/CheckIcon.gif" alt="Yes" height="24" width="24"/></td>
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        <td> <a href="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1112001">BBa_K1112001</a> </td>
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        <td> Coding </td>
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        <td> pGlnA + hmsHFRS operon </td>
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        <td> Alba Iglesias Vilches </td>
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        <td> 6342</td>
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        <td> </td>
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    </tr>
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    <tr>
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        <td><img class="table-check" src="https://static.igem.org/mediawiki/2013/0/01/CheckIcon.gif" alt="Yes" height="24" width="24"/></td>
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        <td> <a href="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1112002">BBa_K1112002</a> </td>
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        <td> Coding </td>
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        <td> Cluster PHA </td>
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        <td> Alba Iglesias Vilches </td>
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        <td> 4978</td>
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        <td> </td>
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    </tr>
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</table>
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<br/>
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<p>
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<a href="http://parts.igem.org/Part:BBa_K1112000"><h3>BBa_K1112000: fadB promoter + FLP-21 iRNA</h3></a>
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 +
    This construction is made up by a fatty acid-sensitive promoter that directs the transcription of an iRNA responsible for the social or solitary behavior of <i>C.elegans</i>.
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 +
</p>
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 +
<p>
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<a href="http://parts.igem.org/Part:BBa_K1112001"><h3>BBa_K1112001: pGlnA + hmsHFRS operon</h3></a>
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    We reused our nitrogen sensitive promoter from one of our last year constructs and we used it to control the expression of the operon that triggers the formation of a biofilm over <i>C.elegans</i>.
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</p>
 +
 +
<p>
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<a href="http://parts.igem.org/Part:BBa_K1112002"><h3>BBa_K1112002: cluster PHA</h3></a>
 +
    This BioBrick contains the complete natural sequence that induces the production of PHA in <i>Pseudomonas putida</i> (KT2440).
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</p>
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<div class="tab-pane fade" id="Notebook">
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==Notebook==
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<html>
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<p>
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During the whole project, we have been working on a notebook in order to show the world what we have been working on and to collect all our progress.
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</p>
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<p>You'll be able to see our results, the picture of the day, the song that was being played in the lab while we were working and our iGEM News.</p>
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<p style="text-align:center">
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  <a href="https://2013.igem.org/Team:Valencia_Biocampus/Notebook" class="btn btn-primary">Go to Notebook</a>
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</p>
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</div>
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<br/>
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Latest revision as of 19:18, 24 October 2013

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Project Overview

Bacteria are essential in biotechnology, but they can hardly move. Nematodes, such as Caenorhabditis elegans, are fast crawling organisms, but they have limited biotechnological applications. By combining the best from both organisms, we present the first artificial synthetic symbiosis with bacteria engineered to ride on worms, which concentrate in hotspots where bacteria perform a desired biotechnological process, such as bioplastic (PHA) production. We have engineered Pseudomonas putida with a whole operon that allows the formation of a biofilm on the worm. Biofilm formation is switched on and off depending on the media, and thus bacteria get on and off the worm like travellers on a bus. We have also engineered a third partner, Escherichia coli, to express an interference RNA that promotes clumping. Taken together, our artificial symbiosis allows biotechnologically interesting bacteria to travel on nematodes, reach nutrient-rich biomass spots and maximize the efficiency of biotechnological fermentations in heterogeneous substrates.

Why E.coli

Escherichia coli is a model organism widely used in fields such as microbiology, molecular biology and genetics. Because of this, there is a great range of genetic manipulation techniques related with this Gram negative bacterium. There is also a lot of information about the biochemistry and genetics of this microorganism. All this allows us to work easily with it in the lab and perform assays testing different conditions that will be tried out in other organisms unstudied in such depth. Moreover, E.coli is the main food of C.elegans, organism that is able to incorporate nucleic acids from the bacteria, RNA, to its cells (Mello et al., 2004). This is the usual mechanism to transform C.elegans, introducing exogenous genetic material from the bacteria and altering the expression of the worm’s genome in order to make modifications of interest.

Controlling the mechanism

The role of E.coli in our project is to carry out the synthesis of an iRNA to induce the social feeding behaviour of Caenorhabditis elegans , the clumping. To achieve this, we cloned the biobrick Bba_K1112000 in E.coli, XL1-Blue strain (fig. 1).

Fig. 1.

  • pSB1C3 is a high copy number plasmid (RFC [10]) carrying chloramphenicol resistance.
  • The replication origin is a pUC19-derived pMB1 (copy number of 100-300 per cell).
  • pSB1C3 has terminators bracketing its MCS which are designed to prevent transcription from *inside* the MCS from reading out into the vector. The efficiency of these terminators is known to be < 100%. Ideally we would construct a future set of terminators for bracketing a MCS that were 100% efficient in terminating both into and out of the MCS region.

This construction consists of the E.coli fadA promoter, which is activated in the presence of fatty acids (Clark, 1981), and the antisense sequence of the mRNA FLP-21 from C.elegans which encodes a protein involved in the solitary feeding behaviour of the worm, the formation of the dsRNA complex inhibits the expression of this protein, inducing the social feeding behaviour (fig. 2).

Fig.2

Pseudomonas putida and PHA production

Pseudomonas putida is a gram-negative bacterium that is found in most soil and water habitats where there is oxygen. Its diverse metabolism and its capacity to break down organic harmful solvents (most of its genes are involved in degrading aromatic or aliphatic hydrocarbons) in contaminated soils make this microorganism irreplaceable for research studies in the field of bioremediation but also for biosynthesis of value-added products. In addition, Pseudomonas putida has several strains including KT2440, the one we have worked with. This strain can colonize plant roots, from which they take nutrients, while at the same time it offers protection for the plant against pathogens.

For example, it is capable of converting styrene oil into the biodegradable PHA plastic . This helps the degradation of the polystyrene foam which was thought to be non-biodegradable. Styrene is a major environment toxic pollutant released from industrial sites. The conversion to PHA allows the cure of styrene pollution but it is also beneficial for society because of its applications in tissue engineering.
PHA is also environmentally friendly and has a long self-life therefore it is also used in everyday items. Unlike styrene, PHA can break down in soil or water.

Within Pseudomonas putida, PHA accumulates under unbalanced growth conditions as a means of intracellular storage, storing excess carbon and energy. These PHA polymers are synthesized by the enzyme PHA synthase which is bound to the surface of the PHA granules and uses coenzyme A thioesters of hydroxyalkanoic acids as substrates.

P. putida

The role of P. putida in the Synthetic symbiosis that we have designed is to be carried by C. elegans to hotspots of interest where it would produce bioplastic, PHA.


An overview about our nematode

One of the main characters of our work is a nematode known as Caenorhabditis elegans, from the Rhabditidae family. It was first used as an experimental model in Developmental Genetics studies and nowadays it is also used in other fields such as Clinical Biology, Neurobiology and Cell Biology, being a good model to study Alzheimer disease, obesity, diabetes and aging, among others.

Another interesting thing is that it feeds on Escherichia coli. Its “favorite” strain is OP50, although we checked that it’s also able to feed on XL1-Blue strain, the one that we used in all our molecular biology experiments.

Some advantages of C. elegans when compared with other model organisms are:


  • Lifespan ranges between 2 and 3 weeks, so experimentation times are reduced.
  • Its maintenance and study is cheap and simple (it is transparent, which facilitates microscopic observation).
  • It is very small (1 mm), so it is possible to carry out experiments with a huge number of worms in a small Petri dish having a great statistical support.
C. elegans

Why use C. elegans as a transport?

When we were considering on creating a new system for the transport of bacteria, we found different key advantages that made the nematode the best option. For example, C. elegans is able to move very fast around solid substrates (soil actually is its natural habitat) and also in agar, so it’s very useful for both lab experiments and real-environment tests.

Its movement, in addition to being very fast, has two modes: random and directed.

When there is no attractant in the medium, C. elegans moves doing uncoordinated movements in several directions in what is known as 'random walk'.

The situation changes when there is an attractant in the medium. Here, our 'transport system' begins to direct its movements to the focus of the substance (volatile or soluble) which acts as an attractant in a process known as 'chemotaxis' thanks to the amazing sense of smell of our nematode. This allows us to ‘guide’ the nematodes towards defined spots in irregular substrates.

Chemotaxis is the foundation to guide the transport of bacteria and is therefore the focus of experimentation with C. elegans, with the aim of finding the best attractant. This ability makes C. elegans a perfect 'bus' for bacteria. (simuelegans online here)

Moreover, we found two pathogens (Yersinia pestis and Xhenorhabus nematophila) with the ability to form biofilms on C. elegans thanks to the proteins of the operon hmsHFRS. When genetically-engineered strains of commonly used bacteria such as Escherichia coli or Pseudomonas putida express this hmsHFRS operon, they have the 'ticket' to travel: they are able to adhere to the worm’s surface by means of forming a synthetic biofilm.

Expanding our knowledge about C. elegans...

Once we knew that C. elegans was the best option, we began to discover interesting things for further study.

There are several strains of our nematode. The one that drew our attention was called 'N2', which had a fairly interesting behaviour: under normal conditions, it eats individually, whereas under certain conditions (such as starvation), a social feeding behaviour known as “clumping” is induced. But this phenomenon can also be induced if the expression of some particular genes is interfered. This fact gave us the opportunity to develop the first artificial symbiosis between worms and bacteria, based on the manipulation of the behaviour of C. elegans by simply nourishing it with transformed E.coli able to synthesize the iRNA.

With it, while C. elegans acts as transport, bacteria return the favour giving it the ability to eat in company.



We have created a Results Section to organise our results depending on the activity they belong to (The Riding, The Calling, The Clumping and The Building) in order to make it more intuitive.

Go to Results section

Parts

These are the BioBricks we have designed, constructed, and characterized. We have submitted them to the Registry of Standard Biological Parts



Works? Name Type Description Designer Length Fav
Yes BBa_K1112000 Regulatory fadB promoter + FLP-21 iRNA Pedro Luis Dorado Morales 344
Yes BBa_K1112001 Coding pGlnA + hmsHFRS operon Alba Iglesias Vilches 6342
Yes BBa_K1112002 Coding Cluster PHA Alba Iglesias Vilches 4978

BBa_K1112000: fadB promoter + FLP-21 iRNA

This construction is made up by a fatty acid-sensitive promoter that directs the transcription of an iRNA responsible for the social or solitary behavior of C.elegans.

BBa_K1112001: pGlnA + hmsHFRS operon

We reused our nitrogen sensitive promoter from one of our last year constructs and we used it to control the expression of the operon that triggers the formation of a biofilm over C.elegans.

BBa_K1112002: cluster PHA

This BioBrick contains the complete natural sequence that induces the production of PHA in Pseudomonas putida (KT2440).

Notebook

During the whole project, we have been working on a notebook in order to show the world what we have been working on and to collect all our progress.

You'll be able to see our results, the picture of the day, the song that was being played in the lab while we were working and our iGEM News.

Go to Notebook