Difference between revisions of "Team:William and Mary/RBS"
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<img src="https://static.igem.org/mediawiki/2016/b/b2/T--William_and_Mary--F1-V1-.png" width="800px"> | <img src="https://static.igem.org/mediawiki/2016/b/b2/T--William_and_Mary--F1-V1-.png" width="800px"> | ||
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| − | + | <b>Figure 1:</b> RiboJ acts to homogenize translational efficiency between promoters by cleaving the 5’ region upstream from | |
| − | + | RiboJ. -35 and -10 boxes are shown in bold, and transcription factor binding sites are underlined. Note how there is | |
| − | + | an operator sequence located within the transcribed region of the pTac promoter (BBa_K864400), and that pSal and pBad | |
| − | + | include transcribed regions. These untranslated regions can change translational efficiency of the downstream protein, | |
| − | the | + | leading to inconsistent expression between different combinations of promoters and coding sequences. Figure modified |
| + | from figure S1 of Lou et al. 2012. | ||
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Revision as of 17:31, 19 October 2016
One of the more familiar ways of tuning a biological circuit is to change the strength of a Ribosome binding site (RBS).
Changing the strength of an RBS allows for the alteration of the amplitude of a given transfer function. While this is
a familiar concept to most iGEM teams, it takes on a special importance in the context of the Circuit Control Toolbox.
This is because while transfer functions are preserved when shifted, the amplitude of those transfer functions is
oftentimes reduced due to increased metabolic load. So we characterized a library of variable strength RBSs for use
in amplitude tuning in the Circuit Control Toolbox.
While it would have been possible to construct brand new RBSs for use in the Circuit Control Toolbox, we thought that
it would be more useful to characterize existing commonly used RBSs on the registry. So we chose to characterize the
Community Collection, which is made up of 8 variable strength RBSs, and is commonly used by most iGEM teams.
For our characterization we chose to emulate the methods of Lou et al. 2012 (“Ribozyme-based insulator parts buffer
synthetic circuits from genetic context”) and used a super folder Green Fluorescent Protein (sfGFP) with RiboJ under
the control of pLacO1 (Bba_K2066014). The use of the IPTG inducible promoter pLacO1 allowed us to characterize the
functions over an induction curve, and the use of RiboJ, a self cleaving ribozyme from Lou et al. 2012 prevented the 5’
untranslated region of the promoter from effecting the translational efficiency of the mRNA transcript (Figure 1).
That means that unlike past iGEM characterization, our results are generalizable beyond the promoter pLacO1. (See the
RiboJ section for more details)
Figure 1: RiboJ acts to homogenize translational efficiency between promoters by cleaving the 5’ region upstream from
RiboJ. -35 and -10 boxes are shown in bold, and transcription factor binding sites are underlined. Note how there is
an operator sequence located within the transcribed region of the pTac promoter (BBa_K864400), and that pSal and pBad
include transcribed regions. These untranslated regions can change translational efficiency of the downstream protein,
leading to inconsistent expression between different combinations of promoters and coding sequences. Figure modified
from figure S1 of Lou et al. 2012.
for a PDF of more examples of learnsynbio exercises, click here.
Because LearnSynBio is hosted on an independent domain, it is easily accessible anywhere by anyone and can easily
be maintained and updated with feedback from teachers who use it. This allows our outreach efforts to continue even
in places and times where we cannot be physically present!
Finally, we are taking measures to get LearnSynBio incorporated into actual classrooms: We have established a
collaboration with the high school team Broad Run iGEM (see Collaborations page) to incorporate our modules into
their advanced science classes and after-school science clubs. Additionally, we are working with some of our former
high school teachers to introduce LearnSynBio to VAST, the Virginia Association of Science Teachers, for incorporation
in classrooms all around the state. Lastly, it is our hope that the presentation of LearnSynBio at the Jamboree
will encourage the spread of LearnSynBio to schools all around the world!
BwB
In addition to LearnSynBio, we also completed several public outreach events. We were awarded a grant from Building
with Biology to host public outreach events over the course of the iGEM 2016 season.
We held a science workshop
targeted at at local children and their parents which allowed them to get some hands-on experience with the exciting
world of modern biology. We had more than 70 people in attendance and together we extracted DNA from strawberries,
learned about synthetic biology and the benefit of standard biological parts, and discussed our questions and concerns
with GMO food.
We also held a forum on the topic of Genome Editing targeted at the general public. At the forum, we briefly discussed
the implications of the CRISPR/Cas9 genome editing tool and explored various ways that it could be applied to real
world problems. Among the topics discussed were: stabilizing the Honeybee population by increasing expression of
‘hygiene’ genes, engineering yeast for efficient biofuel production, and using CRISPR to decrease human susceptibility
to HIV infection. We had over 30 participants for the forum and we received great feedback from our attendees!
RBS Tuning
