Difference between revisions of "Team:Newcastle/Design"

 
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                         Hydroponics
 
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              Naringenin Operon
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                    <span>Scroll Down</span>
 
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                <h3 class="subhead subhead--dark">Naringenin Operon</h3>
 
                <h1 class="display-1 display-1--light">DESIGN</h1>
 
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<p class="about-para"> In order to produce the flavonoid naringenin, construction of a naringenin operon that would be synthesised from the sequence in the iGEM parts registry to gblocks by IDT was required. This operon was based on that used by the TU Darmstadt 2014 iGEM team, allowing the production of nitrogen to attract nitrogen fixing bacteria. It contains the genes for four enzymes: 4 – Coumaryl ligase, Tyrosine ammonia lyase, Chalcone isomerase and Chalcone synthase. Each of these genes will contain a strong ribosome binding site. This construct will be under the control of a J23100 constitutive promoter to observe its expression in E. coli as a proof of concept. Once biosynthesis under the control of J23100 is achieved, the construct future experiments would test this under a T7 promoter in E. coli. Parts for biosynthesis in the final chassis organism, root-colonising Pseudomonas fluorescens, will be constructed in the plasmid backbone pSB1C3.</p>
 
 
<imgsrc=''https://static.igem.org/mediawiki/2018/e/e8/T--Newcastle--j23100plasmid.jpeg''width="500" height="250" alt="Pathway"> <p></p>
 
 
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                <h5>UP TO</h5>
 
                <div class="stats__count">1344</div>
 
                <h5>SEEDS CAN BE GROWN</h5>
 
                <h5>IN HYDROPONICS</h5>
 
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            <div class="col-block stats__col">
 
                <h5>APPROXIMATELY</h5>
 
                <div class="stats__count">70</div>
 
                <h5>KWH OF POWER ANNUALLY</h5>
 
                <h5>USED TO POWER SYSTEM</h5>
 
               
 
            </div>
 
            <div class="col-block stats__col">
 
                <h5>PROVIDES UP TO</h5>
 
                <div class="stats__count">1700</div>
 
                <h5>LUX OF LIGHT</h5>
 
                <h5>TO GROW SEEDS</h5>
 
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            <div class="col-block stats__col">
 
                <h5>CONTAINS</h5>
 
                <div class="stats__count">120</div>
 
                <h5>INDIVIDUALLY ADDRESSABLE</h5>
 
                <h5>LOW-POWER LED'S</h5>
 
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Latest revision as of 09:19, 15 October 2018

Alternative Roots/Design

Alternative Roots

Design

Hydroponics

DESIGN

Once the project idea was finalised, the team began looking for cheap, efficient and standardised methods for growing plants in iGEM. The hope was that such an item existed that would meet these specifications as well as being a closed container to prevent contamination and also providing a high throughput of plants. It was soon established that such an item did not exist to meet our specifications. Therefore, to combat this issue, it was decided that the best way forward would be to design our own hydroponics system. This would allow us to grow large amounts of Arabidopsis in a controlled setting for the purposes of our project. Several team members were assigned to this “sub-project”.

Before getting hands-on in building the system, the team as a whole established a few design parameters. For example, the system needed to be cheap and easy to build from scratch. This is so future iGEM teams are able to construct the system for their own needs and even build upon our design, as necessary. Additionally, the system must be versatile, open-source and easily adapted for various conditions such as light intensity and wavelength. By adopting such an open and adaptable design the intention is that the end-user is able to effortlessly match the system to their needs, without getting entangled in streams of code.

Several weeks were spent modifying the design until a design was found that met all the above criteria, the specifications of the design can be seen below.

UP TO
1344
SEEDS CAN BE GROWN
IN HYDROPONICS
APPROXIMATELY
70
KWH OF POWER ANNUALLY
USED TO POWER SYSTEM
PROVIDES UP TO
1700
LUX OF LIGHT
TO GROW SEEDS
CONTAINS
120
INDIVIDUALLY ADDRESSABLE
LOW-POWER LED'S