Difference between revisions of "Team:TU Darmstadt/Lab"

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    <p><h5>Killswitch</h5>
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There are a lot of fears in the general public&#39;s mind when it comes to genetics and genetically modified organisms(GMOs).
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These represent a major burden, that synthetic biology has to overcome before it will gain widespread acceptance for more applications in daily life.
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Since the advent of synthetic biology, scientists have been hard at work to implement safeguards in their genetically modified organisms. They were making use of lots of different designs such as controlled essential gene regulations<sup><a href="source_one">1</a></sup>, engineered auxotrophies<sup><a href="source_two">2</a></sup> and inducible toxin switches<sup><a href="source_three">3</a> </sup>.
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One problem that arises with most of these systems is that they don't tackle the problem of bioorthogonal DNA escaping into the environment. The synthetic genetic systems remain, even if their host has died by the means of a killswitch. That DNA can not only be used for industrial espionage, but  bacteria in the environment could get transformed with these synthetic plasmids and thus propagate the pathways introduced into the lab-grown bacteria throughout ecosystems.
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The general aim of a killswitch is to kill its host, most often bearer of plasmids or other forms of non-wild-type DNA. They are generally designed with some sort of regulating mechanism followed by some form of host killing toxin. The toxin can be any sort of host killing mechanism, be that inhibiting proteins, toxin creating enzymes or other things.
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The toxin we chose for the design of our killswitch is colicin E2, a nicking endonuclease<sup><a href="source_four">4</a></sup>. Colicins occur in some wild type coliform bacteria and are used to kill rivaling strains of Escherichia coli.
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An essential part of the design is the way one regulates the release of the toxin. Colicin E2 has a natural counterpart, the immunity protein Im2, which suppresses colicin by tightly binding to it. It can be used as a suppression mechanism for our toxin, to protect the bearer of the colicin from its' martial  effects.
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We chose to use the so-called amber suppression<sup><a href="source_five">5</a></sup> system as our regulating mechanism for the expression of the immunity protein. By introducing a bioorthogonal pair of a tRNA (for more information on that, press this link) and synthase into our cells, we can insert a non-natural amino acid into our immunity protein. You can find more on the rational design of the insertion on our <a href="linkpage">modeling page</a> and on the specifics on our suppression system in our <a href="linkpage">orthogonal pair text</a>.
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By designing our killswitch like this, we aimed to enable the user to not only create genetically modified organisms safely, but also to minimize the risk of their vectors to propagate freely throughout ecosystems and to protect the users  intellectual property from being stolen or recreated. The activity of our toxin even after the death of the host assures, that all DNA in the vicinity of the host gets degraded.
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You can find out more about the design of our project on our <a href="linkpage">killswitch design page</a>.
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<span id="#source_one">1. Kong, W. et al. Regulated programmed lysis of recombinant Salmonella in host tissues to release protective antigens and confer biological containment. Proc. Natl Acad. Sci. USA105, 9361-9366 (2008)</span>
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<span id="#source_two">2. Steidler, L. et al. Biological containment of genetically modified Lactococcus lactis for intestinal delivery of human interleukin 10. Nature Biotechnol. 21, 785-789 (2003)</span>
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<span id="#source_three">3. Szafranski, P. et al. A new approach for containment of microorganisms: dual control of streptavidin expression by antisense RNA and the T7 transcription system. Proc. Natl Acad. Sci. USA 94, 1059-1063 (1997)</span>
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<span id="#source_four">4. Schaller, K. and Nomura, M. Colicin E2 is DNA endonuclease. Proc. Natl Acad. Sci. USA 73, No. 11, pp. 3989-S993 November (1976) Biochemistry</span>
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<span id="#source_five">5. Lang, K. and Chin, J. W., Cellular Incorporation of Unnatural Amino Acids and Bioorthogonal Labeling of Proteins, 114, 4764-4806 Chem. Rev. (2014)</span>
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<div class="verlinked" id="GI"><h5>METABOLIC BURDEN</h5></div>
 
<div class="verlinked" id="GI"><h5>METABOLIC BURDEN</h5></div>

Revision as of 12:45, 7 October 2016

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THE PROJECT
[...]

ORTHOGONAL PAIR

ABSTRACT

In order to detect the presence of a specific non-natural amino acid (nnAA) in vivo the concept of amber suppression is used. This means the occurrence of the amber stop codon (UAG) in an ORF does not cancel protein translation but codes for a specific nnAA, in our case O-methyl-l-tyrosine (OMT). However, the incorporation requires the presence of the nnAA in the medium, otherwise the translation stops. The mechanism requires a tRNA with an anticodon complementary to the amber stop codon and an aminoacyl RNA synthetase (aaRS) loading the tRNA with the specific nnAA. The tRNA and aaRS combination is called an 'orthogonal pair'.

REPORTER

ABSTRACT

Glow before you go- What does this actually mean? The aim of our project is to make biology safer by introducing a suicide system to E. coli. Before the suicide is triggered, a reporter protein is expressed to indicate the release of E. coli or to show a deficiency of the non-natural amino acid in the surrounding medium which is necessary for the bacteria to survive. As a reporter protein, we chose mVenus which is a mutant of eYFP. mVenus is located downstream of a promoter which is repressed by a dimeric protein, the Zif23-GCN4 repressor. This repressor carries an amber mutation at position 4 (F4OMT). As a result, the non-natural amino acid O-methyl-L-tyrosine (OMT) is integrated into the protein sequence as long as there is enough OMT in the medium. With decreasing OMT concentration, the translation of the repressor stops due to the early amber stop codon and the repressor cannot bind to the promoter. This leads to expression of the reporter protein mVenus which can be detected by fluorescence measurements.

KILL(switch)

ABSTRACT

Synthetic suicide systems have been choice safeguards in synthetic biology for as long as the field exists. There are different kinds of designs, often based on a regulating mechanism and a toxin such as host killing proteins or different kinds of metabolism inhibiting pathways. However, these most often don't tackle the problem of synthetic DNA surviving the death of the host cell.
Here we show a possible design for a simple synthetic killswitch based on an endonuclease called colicin E2 and its corresponding suppressing protein, Im2. It is regulated by amber suppression, the usage of an amber stop codon to code for a non-natural amino acid O-methyl-L-tyrosine. The aim of the system is to not only kill its host, but also to destroy all DNA within the cell and its surroundings, preventing the escape of transgenic DNA.

METABOLIC BURDEN

ABSTRACT

Artificial plasmids are a significant burden to the host. The design of our pathways, for example the combination of a promoter and RBS, results in different amounts of product. The measurement of the metabolic burden is the key for a quantitative optimization in metabolic engineering. We want to establish a new approach to iGEM by providing a measurement strain to the community. As described by F. Ceroni et al., we genomically integrated one copy of GFP into E. coli, which offers us a highly accurate and instantaneous measurement of the impact of our plasmids on the host. This is of economical interest because it enables academic and industrial researchers to test a lot of different pathways at once in a short time just by using a microplate reader. For the integration we used the λ‑Integrase site‑specific recombination pathway, described by A. Landy in 2015. Therefore, we designed two plasmids (BBa_K1976000 and BBa_K1976001) and measured them using single cell measurement and via microplate reader.

CHEMICAL SYNTHESIS

ABSTRACT

Since non‑natural amino acids are expensive in comparison to natural amino acids we searched for a high yield synthesis method for O‑methyl‑L‑tyrosine. Problems with chemical alterations of amino acids to form non‑natural derivates often lie in the higher reactivity of amino and carboxyl groups compared to other reactive groups. For this reason both groups need to be kept in mind while searching for a possible reaction for the desired synthesis.
For the protection of the amino group an acetylation reaction was carried out to form N‑acetyl‑L‑tyrosine. The tested method used N‑acetyl‑L‑tyrosine as a reagent which was then methylated at the carboxyl group and at the hydroxyl group using dimethyl sulfate by Williamson ether synthesis. To finally form the non‑natural amino acid, an acidic hydrolysis using hydrochloric acid was performed.