Team:Cornell/project/wetlab

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<h6>Wet Lab</h6>
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<a href="https://2012.igem.org/Team:Cornell/project/wetlab">Overview</a>
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<a href="https://2012.igem.org/Team:Cornell/project/wetlab/chassis">Chassis</a>
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<a href="https://2012.igem.org/Team:Cornell/project/wetlab/assembly/arsenic">Arsenic Reporter</a>
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<a href="https://2012.igem.org/Team:Cornell/project/wetlab/assembly/naphthalene">Naphthalene Reporter</a>
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<a href="https://2012.igem.org/Team:Cornell/project/wetlab/results">Testing &amp; Results</a>
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<a href="https://2012.igem.org/Team:Cornell/project/wetlab/results/transcription">Transcriptional Characterization</a>
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<a href="https://2012.igem.org/Team:Cornell/project/wetlab/results/currentresponse">Current Response</a>
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<a href="https://2012.igem.org/Team:Cornell/project/wetlab/results/protein">MtrB Protein Expression</a>
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<a href="https://2012.igem.org/Team:Cornell/project/wetlab/future_work">Future Work</a>
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<h2 class="centered">Wet Lab Overview</h2>
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<h2 class="centered">Wetlab Overview</h2>
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<h3>Summary</h3>
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We have developed a novel biosensing platform to be used for long-term, continuous monitoring of environmental toxins, such as arsenic and naphthalene. Traditional biosensors commonly output fluorescence, pH, or luminescence&#8212;which then need to be interpreted. Our simpler bacterium-based biosensor directly outputs electric current. This platform offers several advantages.
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In order to improve Ecovative’s production efficiency and help standardize future fungal research, we developed a fungal toolkit of useful constructs for building complete genetic circuits. Our toolkit includes regulatory elements, selectable markers, fluorescent reporter characterization systems, as well as biosafety mechanisms. We have also explored different methods of transformation in order to successfully implement our constructs in fungi. We aimed to demonstrate the utility of our genetic circuit in expressing carotenoids and antifungals as potential real world applications. Carotenoid expression could allow affordable coloration of Organofoam without needing to add synthetic dyes. Antifungal expression would specifically inhibit the growth of contaminant molds in production batches, which would greatly enhance Ecovative’s production efficiency without needing to use harsh chemicals that would be nonspecific and toxic to the environment.
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In order to produce an electrical output in response to analyte, we base our biosensing solution on the well-characterized metal reduction (Mtr) pathway of Shewanella oneidensis MR-1. By shutting electrons through the Mtr pathway, MR-1 is capable of transferring electrons to inorganic solids and generating current at solid-state electrodes. In particular, we choose to utilize MtrB in our biosensing system, as it plays an essential role in localization of components in the Mtr pathway [3].  
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We have designed our biosensing platform to upregulate MtrB production in the presence of analyte. To construct reporter systems for both arsenic and naphthalene, we rely on a complementation strategy based on an mtrB deficient strain of S. oneidensis MR-1 [Strain JG700 [&Delta;mtrB], 2]. The endogenous copy of mtrB has been removed in JG700; therefore, by reintroducing mtrB to this knockout strain under the control of an analyte-sensitive regulation system, we restore the functionality of mtrB in proportion to the amount of analyte present in culture media. Because MtrB is essential for electrode reduction in microbial fuel cells, we will observe a current increase in response to analyte when our engineered strains are used to inoculate bioelectrochemical reactors [4].  
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Because of their capability to directly transfer electrons to acceptors outside the cell, Shewanella strains are often used in microbial electrochemical systems wherein an electrode serves as a terminal electron acceptor in the Mtr pathway. In general, a microbial electrochemical system is just like any other electrochemical cell, except that a microbe is responsible for catalyzing the oxidation/reduction reaction at either the anode or the cathode. For our purposes, we are interested in half-microbial electrochemical systems with three-electrode setups, since such systems can be easily maintained at constant conditions over extended periods of time by poising the potential of a working electrode—to which the bacteria respire—with respect to a reference.
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We are seeking to genetically engineer the fungus <i>Ganoderma lucidum</i>, a model organism for <i>Agaricomycota</i>, the class of wood-rot fungi that is used in Ecovative’s products. However, as <i>Ganoderma</i> does not have a well-standardized transformation protocol and takes several days to grow to an appropriate density, we are also conducting much of our basic fungal characterization work in <i>Cochliobolus heterostrophus</i>, a simpler fungus. In addition, we are seeking to introduce a novel T7 viral regulation system into fungi. Similar systems have been used successfully in mammalian cells, and this system would greatly expand the accessibility of fungal genetic engineering beyond experienced mycologists. This system also allows us to conduct preliminary characterization within <i>E. coli</i> BL21-AI, an arabinose-inducible expression strain for T7-regulated constructs.
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<h3>References</h3>
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1. Dowdesw, L., Dillon, P., Miall, A., &amp; Smol, J. P. (2010). A foundation for the future: building an environmental monitoring system for the oil sands, Environment Canada.
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We identified <a href="https://2013.igem.org/Team:Cornell/project/wetlab/fungal_toolkit/regulatory_elements">Regulatory Elements</a> as a critical component of our toolkit to allow for expression of novel constructs in our various fungal chassis. Specifically, we included constitutive promoters for strong homologous and heterologous expression and inducible promoters for controlled expression. Thus, with our ultimate applications in mind, constitutive promoters were employed for selection markers and inducible promoters for our biosafety mechanisms.  
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2. Coursolle, D., and Gralnick, J.A. (2012). Reconstruction of extracellular respiratory pathways for iron(III) reduction in Shewanella oneidensis strain MR-1. Frontiers in Microbiology 3(56)
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<a href="https://2013.igem.org/Team:Cornell/project/wetlab/fungal_toolkit/selectable_markers">Selectable Markers</a> were also crucial in determining successful transformants. Specifically, we are using the genes conferring resistance to hygromycin (<i>hph</i>), geneticin (<i>nptII</i>), and bialaphos (<i>bar</i>) because the corresponding antibiotics are reportedly effective against several species of basidiomycetes. Additionally, we have tested the sensitivity of <i>G. lucidum</i> to kanamycin, chloramphenicol, and ampicillin. Our toolkit includes resistance genes behind various promoters, and we have tested the functionality of our T7 promoter and hygromycin resistance construct using zone of inhibition assays.
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3. Hartshorne, R. S., Reardon, C. L., Ross, D., Nuester, J., Clarke, T. A., Gates, A. J., Mills, P. C., et al. (2009). Characterization of an electron conduit between bacteria and the extracellular environment . Proceedings of the National Academy of Sciences . doi:10.1073/pnas.0900086106
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For <a href="https://2013.igem.org/Team:Cornell/project/wetlab/fungal_toolkit/characterization">Characterization</a> of our constructs, we utilized green fluorescent protein (GFP) and monomeric red fluorescent protein (mRFP). We cloned these behind several promoters to quantitatively determine their strength in bacterial and fungal chassis.
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4. Coursolle, D., Baron, D.B., Bond, D.R., and Gralnick, J.A. (2010). The Mtr respiratory pathway is essential for reducing flavins and electrodes in Shewanella oneidensis. Journal of Bacteriology 192(2): 467-474
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We utilized homologous recombination to insert our <a href="https://2013.igem.org/Team:Cornell/project/wetlab/fungal_toolkit/homologous_constructs">Homologous Constructs</a> into fungal genomes. We placed our genes of interest between known regions of homology in order to increase its chances of being incorporated into the genome. The genes inserted into the homology flanking regions include trpc promoter, gpd promoter, T7 promoter, and the resistance genes hph and nptII.
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5. Nivens, D.E., McKnight, T.E., Moser, S.A., Osbourn, S.J., Simpson, M.L., &amp; Sayler, G. S. (2004). Bioluminescent bioreporter integrated circuits: potentially small, rugged and inexpensive whole-cell biosensors for remote environmental monitoring. Journal of Applied Microbiology, 96(1): 33-46.
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We were able to achieve successful <a href="https://2013.igem.org/Team:Cornell/project/wetlab/fungal_toolkit/biosafety">Fungal Transformation</a> of several constructs into <i>Cochliobolus</i> by using homologous recombination though <a href="https://2013.igem.org/Team:Cornell/project/wetlab/protoplasting">Protoplasting</a>. We are also seeking to successfully transform into <i>Ganoderma lucidum</i> using the <i>Agrobacterium</i>-mediated transformation method.
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6. Siegfried, K., Endes, C., Bhuiyan, A. F. M. K., Kuppardt, A., Mattusch, J., van der Meer, J. R., Chatzinotas, A., et al. (2012). Field testing of arsenic in groundwater samples of Bangladesh using a test kit based on lyophilized bioreporter bacteria. Environmental Science &amp; Technology 46(6), 3281-7
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We are also implementing a number of <a href="https://2013.igem.org/Team:Cornell/project/wetlab/fungal_toolkit/biosafety">Biosafety</a> measures within our toolkit, including a site-specific recombination system to target and remove antibiotic resistance genes and antifungal compounds in order to prevent their horizontal transfer into the environment. The strain we are seeking to develop would ensure that our strains would be safe to use in Ecovative’s sustainable biomaterials.
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We are still working to introduce our <a href="https://2013.igem.org/Team:Cornell/project/wetlab/fungal_toolkit/carotenoids">Carotenoids</a> constructs into fungi. We have thus far been successful in creating several T7-regulated composite parts for both fungal and bacterial expression of the carotenoid genes. We are similarly still working on the characterization of our <a href="https://2013.igem.org/Team:Cornell/project/wetlab/fungal_toolkit/antifungals">Antifungal</a> protein in fungi, as preliminary characterization in bacteria has been inconclusive.
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We hope that our toolkit will help expand the accessibility of fungal genetic engineering to other researchers, companies, and iGEM teams.
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Latest revision as of 03:29, 29 October 2013

Cornell University Genetically Engineered Machines

Wetlab Overview


In order to improve Ecovative’s production efficiency and help standardize future fungal research, we developed a fungal toolkit of useful constructs for building complete genetic circuits. Our toolkit includes regulatory elements, selectable markers, fluorescent reporter characterization systems, as well as biosafety mechanisms. We have also explored different methods of transformation in order to successfully implement our constructs in fungi. We aimed to demonstrate the utility of our genetic circuit in expressing carotenoids and antifungals as potential real world applications. Carotenoid expression could allow affordable coloration of Organofoam without needing to add synthetic dyes. Antifungal expression would specifically inhibit the growth of contaminant molds in production batches, which would greatly enhance Ecovative’s production efficiency without needing to use harsh chemicals that would be nonspecific and toxic to the environment.
We are seeking to genetically engineer the fungus Ganoderma lucidum, a model organism for Agaricomycota, the class of wood-rot fungi that is used in Ecovative’s products. However, as Ganoderma does not have a well-standardized transformation protocol and takes several days to grow to an appropriate density, we are also conducting much of our basic fungal characterization work in Cochliobolus heterostrophus, a simpler fungus. In addition, we are seeking to introduce a novel T7 viral regulation system into fungi. Similar systems have been used successfully in mammalian cells, and this system would greatly expand the accessibility of fungal genetic engineering beyond experienced mycologists. This system also allows us to conduct preliminary characterization within E. coli BL21-AI, an arabinose-inducible expression strain for T7-regulated constructs.
We identified Regulatory Elements as a critical component of our toolkit to allow for expression of novel constructs in our various fungal chassis. Specifically, we included constitutive promoters for strong homologous and heterologous expression and inducible promoters for controlled expression. Thus, with our ultimate applications in mind, constitutive promoters were employed for selection markers and inducible promoters for our biosafety mechanisms.

Selectable Markers were also crucial in determining successful transformants. Specifically, we are using the genes conferring resistance to hygromycin (hph), geneticin (nptII), and bialaphos (bar) because the corresponding antibiotics are reportedly effective against several species of basidiomycetes. Additionally, we have tested the sensitivity of G. lucidum to kanamycin, chloramphenicol, and ampicillin. Our toolkit includes resistance genes behind various promoters, and we have tested the functionality of our T7 promoter and hygromycin resistance construct using zone of inhibition assays.

For Characterization of our constructs, we utilized green fluorescent protein (GFP) and monomeric red fluorescent protein (mRFP). We cloned these behind several promoters to quantitatively determine their strength in bacterial and fungal chassis.
We utilized homologous recombination to insert our Homologous Constructs into fungal genomes. We placed our genes of interest between known regions of homology in order to increase its chances of being incorporated into the genome. The genes inserted into the homology flanking regions include trpc promoter, gpd promoter, T7 promoter, and the resistance genes hph and nptII.

We were able to achieve successful Fungal Transformation of several constructs into Cochliobolus by using homologous recombination though Protoplasting. We are also seeking to successfully transform into Ganoderma lucidum using the Agrobacterium-mediated transformation method.
We are also implementing a number of Biosafety measures within our toolkit, including a site-specific recombination system to target and remove antibiotic resistance genes and antifungal compounds in order to prevent their horizontal transfer into the environment. The strain we are seeking to develop would ensure that our strains would be safe to use in Ecovative’s sustainable biomaterials.

We are still working to introduce our Carotenoids constructs into fungi. We have thus far been successful in creating several T7-regulated composite parts for both fungal and bacterial expression of the carotenoid genes. We are similarly still working on the characterization of our Antifungal protein in fungi, as preliminary characterization in bacteria has been inconclusive.

We hope that our toolkit will help expand the accessibility of fungal genetic engineering to other researchers, companies, and iGEM teams.