Difference between revisions of "Team:RDFZ-China/Design"

 
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                        <ul>
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                        <li><a href="#section1">What are we facing?</a></li>
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                        <li><a href="#section2">Predecessors</a></li>
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                        <li><a href="#section3">Project Xscape</a></li>
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                        <li><a href="#section4">For Fermentation</a></li>
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                        <li><a href="#section5">For Therapy</a></li>
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                        <li><a href="#section6">Metabolic Stress</a></li>
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                        <li><a href="#section7">DIY Bio and Biosafety</a></li>
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                        <li><a href="#section8">Community and Future</a></li>
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                <!-- <li>
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                    <p>About</p>
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                    <ul>
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                        <li><a href="#section9">About our project</a></li>
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                    </ul>
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                    <p>Reference</p>
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                    <ul>
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                        <li><a href="#section10">Reference</a></li>
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                         <li><a href="#section1">What are we facing?</a></li>
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                         <li><a href="#section1">Overview</a></li>
                         <li><a href="#section2">Predecessors</a></li>
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                         <li><a href="#section2">Lethal Gene</a></li>
                         <li><a href="#section3">Project Xscape</a></li>
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                         <li><a href="#section3">For Fermenter</a></li>
                         <li><a href="#section4">For Fermentation</a></li>
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                         <li><a href="#section4">Therapeutic Bacteria</a></li>
                         <li><a href="#section5">For Therapy</a></li>
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                         <li><a href="#section5">References</a></li>
                        <li><a href="#section6">Metabolic Stress</a></li>
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                        <li><a href="#section7">DIY Bio and Biosafety</a></li>
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                        <li><a href="#section8">Community and Future</a></li>
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                        <li><a href="#section9">References</a></li>
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         <div class="description">
 
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 +
            <h1>Design</h1>
 +
 
             <div class="topic-title" id="section1">
 
             <div class="topic-title" id="section1">
                 <h3>What are we facing?</h3>
+
                 <h3>Overview</h3>
                 <p>Biosafety has always been the major concern to the public, to the companies and the researchers. Doubts and worries raised just as genetic technology was invented. With the rapidly growing of synthetic biology and iGEM community, more and more synthetic biology products are built with the widely distributed DNA toolkits or the inexpensive DNA synthesis service; we are facing unprecedented biosafety issue that unwanted leakage of synthetic biology products to the environment may cause an unexpected but definitely disastrous problem. </p>
+
                 <p>We want to build a device which can kill the engineered bacteria when it escapes from the fermenter and a device which can kill the therapeutic bacteria after it releases the drug. We used Thermal Sensitive Regulator and Quorum Sensing device to achieve the sensing and using ccdB and Colicin to achieve the killing. Furthermore, we used the capacity monitor to assess the resource occupied by our device, and optimized our device.</p>
 
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             <div class="topic-title" id="section2">
 
             <div class="topic-title" id="section2">
                 <h3>Predecessors</h3>
+
                 <h3>Lethal Gene</h3>
                 <p>For decades, researchers were striving to build biosafety devices through auxotrophy or external inducive kill switches[], holins and restriction enzymes are most commonly used. Most of the failures of the previous devices were caused by mutation and evolution of immune. </p>
+
                 <p>As we mentioned in the project description, the major problem of biosafety leakage is the spread of recombinant DNA to the environment, so this project we are mainly focused on Nuclease. From the parts registry, we found NucA/B, Colicin E9, and miniColicin E2. We found that miniColicin E2 is well documented by TU Darmstadt 2016, so we chose it as our lethal gene. Also, we found a nuclease from Bacteriophage which is reported as high efficiency at 65 degree Celsius. Moreover, we considered EndoG, derived from mammalian Caspase-independent apoptosis pathway, which we believe it is far in homology may lead to a reduced possibility of evolution of inhibitor.</p>
                <p>The two major threats of engineered microbes’ leakage are the possible Horizontal Gene Transfer which will lead to the spread of recombinant DNA to the entire ecosystem, or the engineered bacteria could contaminate or overrun the natural habitat.[]</p>
+
 
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             <div class="topic-title" id="section3">
 
             <div class="topic-title" id="section3">
                 <h2>Project Xscape</h2>
+
                 <img src="https://static.igem.org/mediawiki/parts/0/05/T--RDFZ-China--Fmtdemo.png" />
                 <p>Under this circumstance, this year we decided to be a fundamentalist to synthetic biology, by using genetic circuits and logic gates, to establish biosafety devices which can apply to the real-world situation.</p>
+
                <h3>For Fermenter</h3>
                 <p>Since cell death and lysis mean there is a continual presence of free DNA in the environment, holins, which are most widely used are excluded from our choices, and colicin E2 nucleases (Darmstadt iGEM2016) came into our site. We choose site non-specific nucleases since the entire genome and plasmids needed to be entirely digested to prevent the spread, and we use nucleases from a different family to prevent the possible evolution of nuclease inhibitors. Artificial DNA, RNA, and amino acids are a good solution, but due to its high cost so far, it is not applicable to most of the user.</p>
+
                <h4>1 Thermal Sensitive Regulator</h4>
 +
                 <p>When constructing a “fail-safe” device for a known condition but unknown timing incident, any chemical inducer that needed to be added manually should not be considered. Then, as the temperature is usually being set to a certain level in a fermenter, as the engineered bacteria escaped from the fermenter, changes in temperature can be detected. So, the thermal regulator came to our site. From part registry, we found thermal sensitive transcriptional factors which can initiate the transcription when the temperature reaches above a certain level. Bacteriophage’s cl repressor are commonly used, and the tlpA system came out in 2017. ETH Zurich was using tlpA’s original version, and NUS Singapore was using the modified version, TlpA36, which ought to be initiated at 36 degree Celsius. We choose TlpA36 since the original version showed bit intensive leakage at the temperature it supposed not to be turned on. Besides, we add TlpA39 (TlpA repressor respond at 39 degree Celsius) and Tcl42 (cI repressor respond to 42 degree Celsius) to the registry, giving the user more selective temperature for future users’ project. </p>
 +
                 <p>The first thing we want to verify is its function at a different temperature, we assumed that there would be leakage since the promoter we choose for TlpA protein was not the strongest promoter. Then we need it to sense the change from high to low temperature since, in the real-world scenario, the temperature is higher in the fermenter than the environment. According to the previously assumed mechanism by previous researches, we assumed that the dimerized TlpA protein would block the expression of TlpA promoter. Later, since lethal gene needs to turn on when the temperature drops, so the signal should be inverted, we decided to use repressor to invert this. dCas9 system was first mentioned, but it did not fit in to our project since cytotoxicity was too high for overexpression, and if the expression of this repression drops, lethal gene might be expressed ahead; Then we came up with the idea of tetR family repressor, (Stanton et al.), but the energy cost is quite high, so we chose sRNA(Storz et al.) as the repressor. sRNA will consume far less energy than protein repressor, also as a single strand RNA, it is unstable, so when the expression is blocked, the derepression will be quite fast. sRNA mainly consists of three regions: Seed Region, antisense to the target mRNA; the Hfq binding region, which binds to the Hfq protein which can stabilize the sRNA-mRNA complex, waiting for RNase to degrade it; and a termination region, it is a terminator. </p>
 +
                <p>We designed six set of sRNA, with different seed regions (one for 5’UTR and one for Coding Sequence) and different Hfq binding regions.</p>
 +
                <p>We designed sRNA based on the sequence of our reporter gene, mNeonGreen and our selected RBS, J61101. We designed nine sRNA, synthesized 6 of them, characterized 3, finally we chose 1 to use it on our final circuit.</p>
 +
                <p>sRNAs include a seed region, which is the region antisense to the target sequence; an Hfq protein binding region; a termination region, to stop the transcription of sRNA itself. Hfq protein was there to promote the sRNA-mRNA base pairing and increase the stability of sRNA-mRNA complex.</p>
 +
                <p>The seed region we choose was antisense to the 5’UTR region, which includes J61101 RBS and scar; also, we choose the protein coding sequence of mNeonGreen. Previous researches stated that the blocking could be performed by sRNA antisense to 70nt upstream or 15nt downstream. </p>
  
 +
                <h4>2 Density Regulator</h4>
 +
                <p>The other environmental signal we can detect is the cell density. As engineered bacteria accidentally felt out from the fermenter, it will be diluted by the environment; the density will decrease. </p>
 +
                <p>Quorum sensing device in iGEM is quite commonly used until now it has been used for 227 times, the entire system has been well characterized, so we used it directly.</p>
 +
                <img src="https://static.igem.org/mediawiki/parts/4/4e/T--RDFZ-China--DensityR.png" />
 +
                <p>The circuit was quite similar to F2420, but we changed the pTet promoter to pTac. We want the device to express lethal genes when cell density drops, as they get into and diluted by the environment.</p>
 +
                <p>The genetic circuit designed for density-regulated sensor contains an AHL acceptor protein and the quorum sensing pLux promoter. The acceptor protein is LuxR, which is constantly expressed (under promoter pTac) and forms AHL-LuxR complex with AHL molecules. The complex consequently binds to an operator lux box in the promoter region (pLux), which up-regulates the expression of the gene downstream. </p>
 +
                <p>Same as the thermal regulator, we have to invert the signal, so we choose a tetR family repressor. Yes, we did mention that protein transcriptional regulator is resource consuming, but the sRNAs were not able to block the expression entirely during our characterization. So, according to previous research and characterization, we choose PhlF repressor, since its repression is very tight. (Stanton et al.) PhlF will repress pPhlF promoter at PhlO region; the derepression is carried out by LVA degradation tag.</p>
 +
                <h4>3 Integrase</h4>
 +
                <p>One of the basic building blocks of our logic gate is temperature, through which we expect to control suicide switch. Under high cell temperature should the kill switch be turned OFF and contrarily under low cell density, which resembles the situation of strain leakage, should the bacteria express DNase or cytotoxic genes to kill themselves. So, we went through the registry, found that Peking iGEM2017 characterized several integrases, which can be used as an initiator in our project.</p>
 +
                <p>In order to eliminate leakage in the expression of the cytotoxic gene, integrase is employed in the genetic circuit of the regulator. The promoter upstream the executor ccdB colicin E2 is reversed so that no suicide gene is transcribed before the temperature reaches 36 degrees Celsius. Reaching temperature turns on the temperature-sensitive promoter upstream serine integrase that consequently flips over the promoter upstream suicide genes and initiates transcription and cell death.</p>
 +
                <img src="https://static.igem.org/mediawiki/parts/b/bb/T--RDFZ-China--Integrase.png" />
 +
                <p>So the final circuit will be  a NOR gate </p>
 +
                <img src="https://static.igem.org/mediawiki/parts/6/60/T--RDFZ-China--AllCircuit.png" />
 +
                <h4>4 Cold-Lux-Repressible</h4>
 +
                <img src="https://static.igem.org/mediawiki/parts/b/b1/T--RDFZ-China--ColdRegulate-circuit.png" />
 +
                <p>Since we target to modify bacteria used in the fermentation industry, which primarily are used for material synthesis and production, our sequence inserts should occupy as limited resources in bacteria as possible to avoid significant expression burden. In order to reduce this expression stress, we designed another device for fermentation which used a LuxR repressive promoter (Peking-S, 2011) and the “Cold Box” in 5’UTR region of CspA (Ionis Paris, 2017). With only one transcriptional regulator, less energy will be consumed, which is beneficial for cell resource distribution.</p>
 
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             <div class="topic-title" id="section4">
 
             <div class="topic-title" id="section4">
                 <h2>For fermentation</h2>
+
                 <h3>Therapeutic Bacteria</h3>
                 <p>The first device we build is for the fermentation; we want to execute the escaped engineered bacteria from the fermenter, accidentally or intentionally. We used two environment factors to monitor the bacteria’s situation: temperature and population density, they are both high and tunable in the fermenter. So, the device will initiate when temperature and density are both low. We used thermal sensitive regulator (NUS iGEM2017) and quorum sensing regulator (MIT iGEM2004)as our sensor, sRNA and tetR family repressor PhlF(Glasgow iGEM2015) as the signal inverter. We add intergrase (Peking iGEM2017) controlled by the thermal sensitive regulator, which will turn the promoter of a lethal gene when temperature rise in the fermenter so that bacteria can survive at the very beginning. Also, we build a model to stimulate the minimum autoinducer required at the beginning of the fermentation[<a href="https://2018.igem.org/Team:RDFZ-China/Model" target=_blank>Modelling</a>], same as the purpose of integrase. This model is for keeping bacteria alive at the very beginning of fermentation. Together they form a NOR gate which will lead to cell death through genome degradation when temperature and density decrease.</p>
+
                 <p>In iGEM, bacteria for human are popular, almost a thousand pages in all the wiki pages mentioned therapeutic bacteria therapeutic bacteria such as diagnostic bacteria and drug delivery bacteria. However, project for drug delivery bacteria, drugs were released by the lysis of bacteria, so bacteria are destroyed, but naked recombinant DNA will enter the human body, which may be taken up by the human microbiome. </p>
 +
                <p>We designed a set of devices, which can carry out real-time tracking of the bacteria, drug release and genome degradation, all in one host bacteria.</p>
 +
                <img src="https://static.igem.org/mediawiki/parts/1/1a/T--RDFZ-China--Dddemo.png" />
 +
                <p>1. Tracking and locating of microorganisms in their host organism has always been a big challenge, previous methods like an optical reporter and radioactive reporter cannot be quickly or accurately track and locate it(Bourdeau et al.). From a set of research, we found that gas vesicle could act as a non-invasive reporter due to its unique acoustic characteristic.</p>
 +
                <p>Gas Vesicle is an organelle found in cyanobacteria, it acts as a buoyancy regulator by permitting air in and out of the vesicle, to send the bacteria to the optimum depth with sufficient oxygen needed. Several teams had tried to build a floating bacteria like OUC-China. </p>
 +
                <p>By using gas vesicle, we can carry out non-invasive imaging. We expect we can use ultrasound imaging to track the therapeutic bacteria to the nidus. </p>
 +
                <p>2. Then, using VioABDE designed by Cambridge 2009, utilized from SHSBNU 2017, we found it was a good candidate for the drug release since the product should be a small molecule which can diffuse out without cell lysis. So, we connect VioABDE to the pTlpA promoter, followed by TlpA39. In a real situation, we can use ultrasound tissue heating, to de-repress the pTlpA promoter, and activate the production of violacein, which is a precursor of antiphlogosis.</p>
 +
                <img src="https://static.igem.org/mediawiki/parts/0/0f/T--RDFZ-China--TlpAVioCircuit.png" />
 +
                <p>3. When the drug is released, we can keep heat the tissue. Using promoter pR followed by miniColicinE2 and Tcl42. So, when temperature reaches 42°C, miniColicin will be released, degrade the genome, and kill the bacteria. </p>
 +
                <img src="https://static.igem.org/mediawiki/parts/1/16/T--RDFZ-China--Tcl42miniColicin.png" />           
 
             </div>
 
             </div>
 +
        </div>
 +
        <div class="reference">
 
             <div class="topic-title" id="section5">
 
             <div class="topic-title" id="section5">
                 <h2>For Therapy</h2>
+
                 <h3>References</h3>
                 <p>The second device we build is for therapeutic bacteria, the device can carry out noninvasive tracing through ultrasound imaging of the gas vesicle, release the drug (from SHSBNU 2017) controlled by a thermal sensitive regulator at nidus by ultrasound tissue heating, and heat to a higher temperature to release nuclease and kill the bacteria after it finishes its mission. </p>
+
                 <p>Bourdeau, Raymond W., et al. “Acoustic Reporter Genes for Noninvasive Imaging of Microorganisms in Mammalian Hosts.” Nature, vol. 553, no. 7686, Nature Publishing Group, 2018, pp. 86–90, doi:10.1038/nature25021.</p>
 +
                <p>Stanton, Brynne C., et al. “Genomic Mining of Prokaryotic Repressors for Orthogonal Logic Gates.” Nature Chemical Biology, vol. 10, no. 2, 2014, pp. 99–105, doi:10.1038/nchembio.1411.</p>
 +
                <p>Storz, Gisela, et al. “Regulation by Small RNAs in Bacteria: Expanding Frontiers.” Molecular Cell, vol. 43, no. 6, 2011, pp. 880–91, doi:10.1016/j.molcel.2011.08.022.</p>
 +
                <p>Piraner, Dan I., et al. "Tunable thermal bioswitches for in vivo control of microbial therapeutics." Nature chemical biology 13.1 (2017): 75.</p>
 
             </div>
 
             </div>
            <div class="topic-title" id="section6">
 
                <h2>For Metabolic Stress</h2>
 
                <p>We applied capacity monitor [] to quantify the expression burden of all our systems, and to reduce the metabolic stress, we designed another device for fermentation which used a LuxR repressive promoter (Peking iGEM2011) and cold-regulated 5’UTR region (Ionis Paris 2017). This device only involves one transcriptional regulator, which will be less energy consuming. </p>
 
            </div>
 
            <div class="topic-title" id="section7">
 
                <h2>DIY bio and Biosafey</h2>
 
                <p>Back to the growing and glowing synthetic biology community, despite the ones doing it on campus, more and more people are starting it at home, they call themselves Genehacker or DIY biologists. The lack of sufficient training and efficient surveillance will be a time bomb which we do know there will be a monstrous harmful bioproduct will be made someday in the future, and indeed, it will be a significant threat to the current biosafety basis. Recall our memory to iGEM2009, Peking surveyed DIY bio, almost ten years later, we conducted a similar DIY bio-survey again. We tried to order materials for molecular experiments, using the delivery address to our home, the result was quite shocking that we can buy almost everything for the molecular experiment, from the internet. Then, we went through relevant laws and regulations throughout the world, which we found out that there are no laws related to the credit certification and the address certification about the people who book the biology reagent. Most of the laws are about the quality certification and how they would serve the user after they bought this. We interviewed the Director of the center for disease control and prevention. He said that within his experiment with the disease caused by the Bacteria leak, environmental pollution, the vast impact had been caused. Our country has been making all effort which is the highest effort that we have made in the history. He said it is not easy to solve the problem with hard work, it needs the cooperation between all the countries. He made an example of 731 army during the second world war two, the outbreak of pathogens can cause significant social harm. We are still on our way to win the battle, but the effort still needs to be put in.</p>
 
            </div>
 
            <div class="topic-title" id="section8">
 
                <h2>Community and Future</h2>
 
                <p>Also, we hosted two major meeting in Beijing, a Biosafety Forum in October, we invited team leader who runs his high school lab, lab teacher from a university lab, and a former team member from Peking iGEM2009, who participated in that DIY bio investigation ten years ago.</p>
 
                <p>We concluded that the development of DIY bio should be taken seriously, and the permanent way to solve it is through implanting Biosafety awareness into our academic culture. Also, as iGEMer, we should strive to be the considerable and responsible leaders in our community, to ensure the biosafety issue has been taken properly. Another meeting was with biology Olympians all around China, we discussed the future of biology community during the meeting, especially with more and more high school iGEM teams coming up in China, but lack of relevant instruction and education to the students. We came up with the idea of setting up a collaboration between school to share and overcome difficulties hand in hand. This kind of meeting will be continued after iGEM2018, since the community usually grows fast after every iGEM season. </p>
 
                <p>Hopefully, years later, biosafety awareness and considerations can be seriously taken in communities, laboratory studies, and real-world applications.</p>
 
            </div>
 
            <!-- <div class="insert">
 
                <p><img src="https://static.igem.org/mediawiki/2017/d/d6/Pdcomicexp1.png"></p>
 
            </div>
 
            <div class="topic-title" id="section9">
 
                <h3>About our project</h3>
 
                <br />
 
                <h4 id="insp">a) Inspiration</h4>
 
                <br />
 
                <p>Every year, iGEM competition motivates teams from all over the world to devise numerous great project, genetically engineered organisms are designed to serve in wide range of fields. However, when it comes to application, the regulation of gene expression is not the only rising issue, but also the resilience of these engineered organisms that we need to concern. For example, some team’s bacteria have to work in dessert with extremely low water content(<a href="https://2016.igem.org/Team:KAIT_Japan" title="Team: KAIT_Japan">.ref</a>), or when cell components are freeze dried on the test paper to make a paper based biosensor, the system must undergo severe dehydration for storage and transport, and this would probably hamper their effectiveness during work.(<a href="https://2016.igem.org/Team:Toronto" title="Team:Toronto">.ref</a>). Our investigationfor the 2016 iGEM projects showed that over 299 entries, x% engineered organisms are facing practical issues related with extreme working conditions or environmental stress. As a consequence, team SIAT-SCIE is focusing on how we can transform the resilience of tardigrades into the engineered organisms. Increasing their efficiency during work and gives them greater potential to be put into real practice. </p>
 
                <br />
 
                <div class="insert">
 
                    <p><img src="https://static.igem.org/mediawiki/2017/8/8c/Pdcomicexp2.png"></p>
 
                </div>
 
                <h4 id="whatr">b) What are we doing?</h4><br />
 
                <ol>
 
                    <li>Our first goal is to test whether TDPs can provide desiccation resistance for enzyme in vitro.</li>
 
                    <br />
 
                    <li>Secondly, we transfer our designed plasmid into DH5α and express TDP in vivo to see if it can confer desiccation resistance, by comparing the engineered strain with the E. coli that didn’t express the TDP gene. Hence a protection mechanism is developed, which can facilitate other iGEM teams engineered organisms to work efficiently. </li>
 
                    <br />
 
                    <li>During ametabolic state, the DNA repairing mechanism is halted and cells are vulnerable to mutagenic radiation. Hence our final goal is to ameliorate our protection system by expressing the protein Dsup, in providing resistance towards radiation for the engineered bacteria, as well as MnSOD, which protect against oxidative stress during desiccation process.</li>
 
                </ol>
 
 
            </div>
 
            <div class="topic-title" id="section10">
 
                <h5>Reference:</h5>
 
                <ol>
 
                    <li id="r1">Goldenberg JZ, Lytvyn L, Steurich J, Parkin P, Mahant S, Johnston BC. Probiotics for the prevention of pediatric antibiotic-associated diarrhea. Cochrane Database of Systematic Reviews 2015, Issue 12. Art. No.: CD004827. DOI: 10.1002/14651858.CD004827.pub4</li>
 
                    <li id="r2">Friedrich Schiller University, Institute of Nutritional Science, Jena, German.Long-term consumption of fermented dairy products over 6 months increases HDL cholesterol. September 2002, Volume 56, Number 9, Pages 843-849</li>
 
                    <li id="r3">Broeckx, Ge ́raldine, Vandenheuvel, Dieter, Claes, Ingmar J.J., Lebeer, Sarah, Kiekens, Filip, Drying techniques of probiotic bacteria as an important step towards the development of novel pharmabiotics.International Journal of Pharmaceutics http://dx.doi.org/10.1016/j.ijpharm.2016.04.002 </li>
 
                    <li id="r4">Lievense, L.C., van‟t Riet, K., 1994. Convective drying of bacteria II. Factors influencing survival. Adv. Biochem. Eng. Biotechnol. 51, 71–89. doi:10.1007/BFb0008734 </li>
 
                    <li id="r5">Ghandi, A., Powell, I.B., Howes, T., Chen, X.D., Adhikari, B., 2012. Effect of shear rate and oxygen stresses on the survival of Lactococcus lactis during the atomization and drying stages of spray drying: A laboratory and pilot scale study. J. Food Eng. 113, 194–200. doi:10.1016/j.jfoodeng.2012.06.005 </li>
 
                    <li id="r6">Behboudi-Jobbehdar, S., Soukoulis, C., Yonekura, L., Fisk, I., 2013. Optimization of spray- drying process conditions for the production of maximally viable microencapsulated L. acidophilus NCIMB 701748. Dry. Technol. 31, 1274–1283. doi:10.1080/07373937.2013.788509</li>
 
                    <li id="r7">Poolman, B., 2002. Transporters and their roles in LAB cell physiology. Antonie van Leeuwenhoek, Int. J. Gen. Mol. Microbiol. 82, 147–164. doi:10.1023/A:1020658831293 </li>
 
                    <li id="r8">Santivarangkna, C., Kulozik, U., Foerst, P., 2008b. Inactivation mechanisms of lactic acid starter cultures preserved by drying processes. J. Appl. Microbiol. 105, 1–13. doi:10.1111/j.1365-2672.2008.03744.x </li>
 
                    <li id="r9">Garvey, C.J., Lenné, T., Koster, K.L., Kent, B., Bryant, G., 2013. Phospholipid membrane protection by sugar molecules during dehydration-insights into molecular mechanisms using scattering techniques. Int. J. Mol. Sci. 14, 8148–8163. doi:10.3390/ijms14048148</li>
 
                    <li id="r10">Bielecka, M., Majkowska, A., 2000. Effect of spray drying temperature of yoghurt on the survival of starter cultures, moisture content and sensoric properties of yoghurt powder. Nahrung 44, 257–260. doi:0027-769X/2000/0407-0257S17.50+.50/0 </li>
 
                    <li id="r11">Lebeer, S., Vanderleyden, J., De Keersmaecker, S.C.J., 2008. Genes and molecules of lactobacilli supporting probiotic action. Microbiol. Mol. Biol. Rev. 72, 728–764. doi:10.1128/MMBR.00017-08 </li>
 
                    <li id="r12">Jalali, M., Abedi, D., Varshosaz, J., Najjarzadeh, M., Mirlohi, M., Tavakoli, N., 2012. Stability evaluation of freeze-dried Lactobacillus tolerance and Lactobacillus delbrueckii subsp. bulgaricus in oral capsules. Res. Pharm. Sci. 7, 31–36. </li>
 
                    <li id="r13">Jofré, A., Aymerich, T., Garriga, M., 2015. Impact of different cryoprotectants on the survival of freeze-dried Lactobacillus rhamnosus and Lactobacillus casei/paracasei during long- term storage. Benef. Microbes 6, 381–386. doi:10.3920/BM2014.0038 </li>
 
                    <li id="r14">Yamaguchi A, Tanaka S, Yamaguchi S, Kuwahara H, Takamura C, et al. (2012) Two Novel Heat-Soluble Protein Families Abundantly Expressed in an Anhydrobiotic Tardigrade. PLoS ONE 7(8): e44209. doi:10.1371/journal.pone.0044209 </li>
 
                    <li id="r15">Tunnacliffe A, Lapinski J, McGee B. (2005) A putative LEA protein, but no trehalose, is present in anhy- drobiotic bdelloid rotifers. Hydrobiologia 546: 315–321. </li>
 
                    <li id="r16">Hengherr S, Heyer AG, Kohler H-R, Schill RO. (2008) Trehalose and anhydrobiosis in tardigrades-evi- dence for divergence in responses to dehydration. FEBS J. 275: 281–288. PMID: 18070104</li>
 
                    <li id="r17">Zhang, Z.-Q. (2011). "Animal biodiversity: An introduction to higher-level classification and taxonomic richness" . Zootaxa. 3148: 7–12.</li>
 
                    <li id="r18">Rebecchi, L.; et al. "Two Tardigrade Species On Board the STS-134 Space Flight" in "International Symposium on Tardigrada, 23–26 July 2012" . p. 89. Retrieved 2013-01-14.</li>
 
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Latest revision as of 03:38, 18 October 2018

Design

Overview

We want to build a device which can kill the engineered bacteria when it escapes from the fermenter and a device which can kill the therapeutic bacteria after it releases the drug. We used Thermal Sensitive Regulator and Quorum Sensing device to achieve the sensing and using ccdB and Colicin to achieve the killing. Furthermore, we used the capacity monitor to assess the resource occupied by our device, and optimized our device.

Lethal Gene

As we mentioned in the project description, the major problem of biosafety leakage is the spread of recombinant DNA to the environment, so this project we are mainly focused on Nuclease. From the parts registry, we found NucA/B, Colicin E9, and miniColicin E2. We found that miniColicin E2 is well documented by TU Darmstadt 2016, so we chose it as our lethal gene. Also, we found a nuclease from Bacteriophage which is reported as high efficiency at 65 degree Celsius. Moreover, we considered EndoG, derived from mammalian Caspase-independent apoptosis pathway, which we believe it is far in homology may lead to a reduced possibility of evolution of inhibitor.

For Fermenter

1 Thermal Sensitive Regulator

When constructing a “fail-safe” device for a known condition but unknown timing incident, any chemical inducer that needed to be added manually should not be considered. Then, as the temperature is usually being set to a certain level in a fermenter, as the engineered bacteria escaped from the fermenter, changes in temperature can be detected. So, the thermal regulator came to our site. From part registry, we found thermal sensitive transcriptional factors which can initiate the transcription when the temperature reaches above a certain level. Bacteriophage’s cl repressor are commonly used, and the tlpA system came out in 2017. ETH Zurich was using tlpA’s original version, and NUS Singapore was using the modified version, TlpA36, which ought to be initiated at 36 degree Celsius. We choose TlpA36 since the original version showed bit intensive leakage at the temperature it supposed not to be turned on. Besides, we add TlpA39 (TlpA repressor respond at 39 degree Celsius) and Tcl42 (cI repressor respond to 42 degree Celsius) to the registry, giving the user more selective temperature for future users’ project.

The first thing we want to verify is its function at a different temperature, we assumed that there would be leakage since the promoter we choose for TlpA protein was not the strongest promoter. Then we need it to sense the change from high to low temperature since, in the real-world scenario, the temperature is higher in the fermenter than the environment. According to the previously assumed mechanism by previous researches, we assumed that the dimerized TlpA protein would block the expression of TlpA promoter. Later, since lethal gene needs to turn on when the temperature drops, so the signal should be inverted, we decided to use repressor to invert this. dCas9 system was first mentioned, but it did not fit in to our project since cytotoxicity was too high for overexpression, and if the expression of this repression drops, lethal gene might be expressed ahead; Then we came up with the idea of tetR family repressor, (Stanton et al.), but the energy cost is quite high, so we chose sRNA(Storz et al.) as the repressor. sRNA will consume far less energy than protein repressor, also as a single strand RNA, it is unstable, so when the expression is blocked, the derepression will be quite fast. sRNA mainly consists of three regions: Seed Region, antisense to the target mRNA; the Hfq binding region, which binds to the Hfq protein which can stabilize the sRNA-mRNA complex, waiting for RNase to degrade it; and a termination region, it is a terminator.

We designed six set of sRNA, with different seed regions (one for 5’UTR and one for Coding Sequence) and different Hfq binding regions.

We designed sRNA based on the sequence of our reporter gene, mNeonGreen and our selected RBS, J61101. We designed nine sRNA, synthesized 6 of them, characterized 3, finally we chose 1 to use it on our final circuit.

sRNAs include a seed region, which is the region antisense to the target sequence; an Hfq protein binding region; a termination region, to stop the transcription of sRNA itself. Hfq protein was there to promote the sRNA-mRNA base pairing and increase the stability of sRNA-mRNA complex.

The seed region we choose was antisense to the 5’UTR region, which includes J61101 RBS and scar; also, we choose the protein coding sequence of mNeonGreen. Previous researches stated that the blocking could be performed by sRNA antisense to 70nt upstream or 15nt downstream.

2 Density Regulator

The other environmental signal we can detect is the cell density. As engineered bacteria accidentally felt out from the fermenter, it will be diluted by the environment; the density will decrease.

Quorum sensing device in iGEM is quite commonly used until now it has been used for 227 times, the entire system has been well characterized, so we used it directly.

The circuit was quite similar to F2420, but we changed the pTet promoter to pTac. We want the device to express lethal genes when cell density drops, as they get into and diluted by the environment.

The genetic circuit designed for density-regulated sensor contains an AHL acceptor protein and the quorum sensing pLux promoter. The acceptor protein is LuxR, which is constantly expressed (under promoter pTac) and forms AHL-LuxR complex with AHL molecules. The complex consequently binds to an operator lux box in the promoter region (pLux), which up-regulates the expression of the gene downstream.

Same as the thermal regulator, we have to invert the signal, so we choose a tetR family repressor. Yes, we did mention that protein transcriptional regulator is resource consuming, but the sRNAs were not able to block the expression entirely during our characterization. So, according to previous research and characterization, we choose PhlF repressor, since its repression is very tight. (Stanton et al.) PhlF will repress pPhlF promoter at PhlO region; the derepression is carried out by LVA degradation tag.

3 Integrase

One of the basic building blocks of our logic gate is temperature, through which we expect to control suicide switch. Under high cell temperature should the kill switch be turned OFF and contrarily under low cell density, which resembles the situation of strain leakage, should the bacteria express DNase or cytotoxic genes to kill themselves. So, we went through the registry, found that Peking iGEM2017 characterized several integrases, which can be used as an initiator in our project.

In order to eliminate leakage in the expression of the cytotoxic gene, integrase is employed in the genetic circuit of the regulator. The promoter upstream the executor ccdB colicin E2 is reversed so that no suicide gene is transcribed before the temperature reaches 36 degrees Celsius. Reaching temperature turns on the temperature-sensitive promoter upstream serine integrase that consequently flips over the promoter upstream suicide genes and initiates transcription and cell death.

So the final circuit will be a NOR gate

4 Cold-Lux-Repressible

Since we target to modify bacteria used in the fermentation industry, which primarily are used for material synthesis and production, our sequence inserts should occupy as limited resources in bacteria as possible to avoid significant expression burden. In order to reduce this expression stress, we designed another device for fermentation which used a LuxR repressive promoter (Peking-S, 2011) and the “Cold Box” in 5’UTR region of CspA (Ionis Paris, 2017). With only one transcriptional regulator, less energy will be consumed, which is beneficial for cell resource distribution.

Therapeutic Bacteria

In iGEM, bacteria for human are popular, almost a thousand pages in all the wiki pages mentioned therapeutic bacteria therapeutic bacteria such as diagnostic bacteria and drug delivery bacteria. However, project for drug delivery bacteria, drugs were released by the lysis of bacteria, so bacteria are destroyed, but naked recombinant DNA will enter the human body, which may be taken up by the human microbiome.

We designed a set of devices, which can carry out real-time tracking of the bacteria, drug release and genome degradation, all in one host bacteria.

1. Tracking and locating of microorganisms in their host organism has always been a big challenge, previous methods like an optical reporter and radioactive reporter cannot be quickly or accurately track and locate it(Bourdeau et al.). From a set of research, we found that gas vesicle could act as a non-invasive reporter due to its unique acoustic characteristic.

Gas Vesicle is an organelle found in cyanobacteria, it acts as a buoyancy regulator by permitting air in and out of the vesicle, to send the bacteria to the optimum depth with sufficient oxygen needed. Several teams had tried to build a floating bacteria like OUC-China.

By using gas vesicle, we can carry out non-invasive imaging. We expect we can use ultrasound imaging to track the therapeutic bacteria to the nidus.

2. Then, using VioABDE designed by Cambridge 2009, utilized from SHSBNU 2017, we found it was a good candidate for the drug release since the product should be a small molecule which can diffuse out without cell lysis. So, we connect VioABDE to the pTlpA promoter, followed by TlpA39. In a real situation, we can use ultrasound tissue heating, to de-repress the pTlpA promoter, and activate the production of violacein, which is a precursor of antiphlogosis.

3. When the drug is released, we can keep heat the tissue. Using promoter pR followed by miniColicinE2 and Tcl42. So, when temperature reaches 42°C, miniColicin will be released, degrade the genome, and kill the bacteria.

References

Bourdeau, Raymond W., et al. “Acoustic Reporter Genes for Noninvasive Imaging of Microorganisms in Mammalian Hosts.” Nature, vol. 553, no. 7686, Nature Publishing Group, 2018, pp. 86–90, doi:10.1038/nature25021.

Stanton, Brynne C., et al. “Genomic Mining of Prokaryotic Repressors for Orthogonal Logic Gates.” Nature Chemical Biology, vol. 10, no. 2, 2014, pp. 99–105, doi:10.1038/nchembio.1411.

Storz, Gisela, et al. “Regulation by Small RNAs in Bacteria: Expanding Frontiers.” Molecular Cell, vol. 43, no. 6, 2011, pp. 880–91, doi:10.1016/j.molcel.2011.08.022.

Piraner, Dan I., et al. "Tunable thermal bioswitches for in vivo control of microbial therapeutics." Nature chemical biology 13.1 (2017): 75.

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