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#content { padding:0px; width:100%; margin-top:-12px; margin-left:0px;} | #content { padding:0px; width:100%; margin-top:-12px; margin-left:0px;} | ||
#body {background-color:#EDEADC; } | #body {background-color:#EDEADC; } | ||
− | #bodyContent h1, #bodyContent h2, #bodyContent h3, #bodyContent h4, #bodyContent | + | #bodyContent h1, #bodyContent h2, #bodyContent h3, #bodyContent h4, #bodyContent p { margin-bottom: 0px; } |
.w3-container { | .w3-container { | ||
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<div id="Gal_main_toggle" class="w3-row-padding w3-padding-64 w3-container w3-content"> | <div id="Gal_main_toggle" class="w3-row-padding w3-padding-64 w3-container w3-content"> | ||
<h1 class="w3-center">Gal 1/10</h1> <br /> | <h1 class="w3-center">Gal 1/10</h1> <br /> | ||
− | < | + | <p class="w3-justify" style="padding-right:30px;padding-left:30px;font-size:130%"> |
GAL 1- GAL 10 is a divergent promoter region of Saccharomyces cerevisiae, allowing it to regulate two genes simultaneously. | GAL 1- GAL 10 is a divergent promoter region of Saccharomyces cerevisiae, allowing it to regulate two genes simultaneously. | ||
Each complimentary strand promotes translation in opposing directions. | Each complimentary strand promotes translation in opposing directions. | ||
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This vector also contains the Leu2 gene, and Gal 1/10 promoters, but does not have the 44a genes inserted. </li><br/> | This vector also contains the Leu2 gene, and Gal 1/10 promoters, but does not have the 44a genes inserted. </li><br/> | ||
</ul> | </ul> | ||
− | </ | + | </p> |
<div class="w3-center"> | <div class="w3-center"> | ||
<img src="https://static.igem.org/mediawiki/parts/e/ed/T--HebrewU--GalBrickGraph.png" width="80%"> | <img src="https://static.igem.org/mediawiki/parts/e/ed/T--HebrewU--GalBrickGraph.png" width="80%"> | ||
</div><br/> | </div><br/> | ||
− | < | + | <p class="w3-justify" style="padding-right:30px;padding-left:30px;font-size:130%"> |
After growth, be split each strain into 2 treatments:<br /><br /> | After growth, be split each strain into 2 treatments:<br /><br /> | ||
<ul> | <ul> | ||
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indicating the minor levels could be background noise caused by non-specificity of primers, or primer dimer amplification. | indicating the minor levels could be background noise caused by non-specificity of primers, or primer dimer amplification. | ||
(We used SYBR, and not a probe, therefor the possibility of such background noise arises) | (We used SYBR, and not a probe, therefor the possibility of such background noise arises) | ||
− | </ | + | </p> |
</div> | </div> | ||
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<div id="Gibson_main_toggle" class="w3-row-padding w3-padding-64 w3-container w3-content"> | <div id="Gibson_main_toggle" class="w3-row-padding w3-padding-64 w3-container w3-content"> | ||
<h1 class="w3-center">Gibson brick</h1> <br /> | <h1 class="w3-center">Gibson brick</h1> <br /> | ||
− | < | + | <p class="w3-justify" style="padding-right:30px;padding-left:30px;font-size:130%"> |
An obstacle many team face is finding a way to assemble multiple genetic components into a single | An obstacle many team face is finding a way to assemble multiple genetic components into a single | ||
plasmid effectively and quickly. Though the biobrick standard addresses this issue, | plasmid effectively and quickly. Though the biobrick standard addresses this issue, |
Revision as of 17:10, 13 October 2018
Parts
Gal 1/10
GAL 1- GAL 10 is a divergent promoter region of Saccharomyces cerevisiae, allowing it to regulate two genes simultaneously.
Each complimentary strand promotes translation in opposing directions.
Galactose induces transcription, while Glucose serves as a repressor.
The promoter is inducible by as low as 2% Galactose in medium.
It is particularly useful for measuring protein-protein interactions, expressing proteins with two subunits, or can simply be used to effectively cut the amount of plasmids required for cloning in half, as two genes can be cloned into a single plasmid.
To validate this part we preformed Real-Time PCR on yeast with our Leu-44a vector, containing two subunits of the same protein- 44a-Dioxygenase (44a) . This enzyme contains to subunits: 44a Large Subunit (LS) and 44a Small Subunit (SS). We used Leu2 as a regulating gene, as it is found on the same plasmid, but it transcription is not dependent on the Gal 1/10 Promoter.
We grew 2 strains of yeast in SD media (containing glucose) for 36 hours. The strains were as follows:
- 1. 44a- Containing the vector showed in the map above, with the LS transcription being promoted by Gal 10 and SS transcription being promoted by Gal1.
- 2. CTRL strain, containing a similar but "empty" vector. This vector also contains the Leu2 gene, and Gal 1/10 promoters, but does not have the 44a genes inserted.
After growth, be split each strain into 2 treatments:
- 1. Induced: SG media, containing 2% galactose in the media
- 2. Uninduced: SD media, containing 2% glucose in the media
In the induced treatment, we see expression rise more than 20 fold over the uninduced treatment.
Additionally, we see approximately equal expression between the uninduced treatment and the control group, indicating the minor levels could be background noise caused by non-specificity of primers, or primer dimer amplification. (We used SYBR, and not a probe, therefor the possibility of such background noise arises)
Gibson brick
An obstacle many team face is finding a way to assemble multiple genetic components into a single plasmid effectively and quickly. Though the biobrick standard addresses this issue, we found that using newer, more advanced methods of can help save time and resources. We, as many iGEM teams before us, decided to use Gibson Assembly. Since no restriction is required for this method, the multi-cloning sites in the biobrick prefix and suffix were not particularly helpful. Gibson Assembly utilizes homologous overlaps on each DNA fragment allowed for their cloning in to a single vector. This set of 8 oligos, that help to convert any biobrick into a Gibson Assembly ready fragment. Each of our oligos are approximately 40 Bp long, consisting of two components:
- 1. Biobrick prefix / suffix region- allowing them to be used as primers for any (RFC10) biobricks currently in the iGEM library.
- 2. 20 bp region with no secondary structures and about 50% GC content, allowing for extremely efficient Gibson Assembly.
Parts in Registry:
BioBrick |
Name |
Sequence |
---|---|---|
BBa_K2667002 |
GibsonBrick 1 Fw |
GCACTGAAGGTCCTCAATCGCGAATTCGCGGCCGCTTCTAG |
BBa_K2667003 |
GibsonBrick 1 Rv |
TACTAGTAGCGGCCGCTGCAGGCACTGAAGGTCCTCAATCGC |
BBa_K2667004 |
GibsonBrick 2 Fw |
CTGACCTCCTGCCAGCAATAGGAATTCGCGGCCGCTTCTAG |
BBa_K2667005 |
GibsonBrick 2 Rv |
TACTAGTAGCGGCCGCTGCAGCTGACCTCCTGCCAGCAATAG |
BBa_K2667006 |
GibsonBrick 3 Fw |
CTATTGCTGGCAGGAGGTCAGGAATTCGCGGCCGCTTCTAG |
BBa_K2667007 |
GibsonBrick 3 Rv |
TACTAGTAGCGGCCGCTGCAGCTATTGCTGGCAGGAGGTCAG |
BBa_K2667008 |
GibsonBrick 4 Fw |
TCTTAGGTGGCAGCGAACGAGGAATTCGCGGCCGCTTCTAG |
BBa_K2667009 |
GibsonBrick 4 Rv |
TACTAGTAGCGGCCGCTGCAGTCTTAGGTGGCAGCGAACGAG |
Fragments should be amplified in the following order:
- Fragment 1: Custom Vector Primer 1 + GibsonBrick 1 Rv.
- Fragment 2: GibsonBrick 1 Fw + GibsonBrick 2 Rv.
- Fragment 3: GibsonBrick 2 Fw + GibsonBrick 3 Rv.
- Fragment 4: GibsonBrick 3 Fw + GibsonBrick 4 Rv.
- Fragment 5: GibsonBrick 4 Fw + Custom Vector Primer 2.
homologous regions that will allow for assembly with the Vector your team is using.