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| <h3>Methan<b>E.COLI</b>c : Decreasing the Greenhouse effects and Saving the workers life in one system</h3> | | <h3>Methan<b>E.COLI</b>c : Decreasing the Greenhouse effects and Saving the workers life in one system</h3> |
- | <p>Firedamp explosions are frequently seen cases at all mines over the world. In Turkey every year, 50 miners lose their lives because of firedamp explosions. Firedamp is a flammable gas found in coal mines and it mainly contains methane. Beside its explosive property, methane is also the main contributor to global warming. However recent mine mechanisms release obtained methane into air. By offers of Synthetic biology, we aimed to design a device which will work on E.coli that provides solutions for side effects of methane. Device that we are planning to construct involves the genes of bacteria (Methylococcus capsulatus) and insect (Drosophilia melanogaster) Our compact system in E.coli is fabricated as sensation of methane, the conversion of methane to methanol and then entrapment of methanol to handle for biofuel and death of bacteria at 42 C by kill switch mechanism.</p> | + | <p>Firedamp explosions are frequently seen cases at all mines over the world. In Turkey every year, 50 miners lose their lives because of firedamp explosions. Firedamp is a flammable gas found in coal mines and it mainly contains methane. Beside its explosive property, methane is also the main contributor to global warming. However recent mine mechanisms release obtained methane into air. By offers of Synthetic biology, we aimed to design a device which will work on <i>E.coli</i> that provides solutions for side effects of methane. Device that we are planning to construct involves the genes of bacteria (<i>Methylococcus capsulatus</i>) and insect (<i>Drosophilia melanogaster</i>). Our compact system in <i>E.coli</i> is fabricated as sensation of methane, the conversion of methane to methanol and then entrapment of methanol to handle for biofuel and death of bacteria at 42 C by kill switch mechanism.</p> |
| <p>When project is analyzed in stepwise, there are successive 4 steps of our modelled system in modified organism. As mentioned in subtitles, methane is sensed, then converted to methanol and methanol is entrapped and to elute methanol the cells are dead. </p> | | <p>When project is analyzed in stepwise, there are successive 4 steps of our modelled system in modified organism. As mentioned in subtitles, methane is sensed, then converted to methanol and methanol is entrapped and to elute methanol the cells are dead. </p> |
| </div> | | </div> |
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| <img src="https://static.igem.org/mediawiki/2011/1/1c/Projectheader.png" height="75px" width="890px"> | | <img src="https://static.igem.org/mediawiki/2011/1/1c/Projectheader.png" height="75px" width="890px"> |
| <h2>Introduction</h2> | | <h2>Introduction</h2> |
- | <p>Methan<b>E.COLIc</b> project is designed to solve one of the problems of Turkey on worker security in mines, by constructing the natural parts of organisms.The main reason for us to choose such a project is that in Turkey- and also in many countries- each year, huge numbers of workers in mines lost their life due to deficiencies and conditions in their working areas (mines). The release of Grizu gas leads to subsidence of mines and so death of workers.This project is also designed to solve one of universal problem; global warming. Methane gas is a potential greenhouse gas.This project focuses on sensing the ambient methane gas and converting to one of the bio-fuel sources, methanol. Methanol is entrapped by product of one of the constructs of project, and then cells are dead by kill switch device of project to elute methanosol.</p> | + | <p>Methan<b>E.COLIc</b> project is designed to solve one of the problems on worker security in mines of Turkey , by constructing the natural parts of organisms. The main reason for us to choose such a project is that in Turkey- and also in many countries- each year, huge numbers of workers in mines lost their life due to deficiencies and conditions in their working areas (mines). The release of Grizu gas leads to subsidence of mines and so death of workers.This project is also designed to solve one of universal problem; global warming. Methane gas is a potential greenhouse gas.This project focuses on sensing the ambient methane gas and converting to one of the bio-fuel sources, methanol. Methanol is entrapped by product of one of the constructs of project, and then cells are dead by kill switch device of project to elute methanol.</p> |
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- | <h2><a href="mailto:cihanefe@gmail.com">Cihan Efe KILIC</a></h2>
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- | <img width="130px" height="180px" src="https://static.igem.org/mediawiki/2011/a/a8/Cihan.jpg">
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- | <p>He is a third year student at the Department of Chemistry at Middle East Technical University. This is the first year of his in iGEM team. He faced synthetic biology on his Biochemistry course. He wants to study on the Electrochemistry-Enzyme immobilization. He believes that synthetic biology will give some benefits for his future work. He likes team working and sharing the success. He likes to cool staff with liquid nitrogen. He enjoys playing musical instruments flute and martial arts.</p>
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| <img src="https://static.igem.org/mediawiki/2011/2/28/Wetlabheader.png" height="75px" width="890px"> | | <img src="https://static.igem.org/mediawiki/2011/2/28/Wetlabheader.png" height="75px" width="890px"> |
| <h2>WET LAB</h2> | | <h2>WET LAB</h2> |
- | <p>Whole summer in lab work we aimed to design 7 new E.coli compatible Biobricks and 1 composite part from 2011 kit plate distributions, also we aimed to characterize each part by protein analysis and fluorescence protein measurements.</p> | + | <p>Whole summer in lab work we aimed to design 7 new <i>E.coli</i> compatible Biobricks and 1 composite part from 2011 kit plate distributions, also we aimed to characterize each part by protein analysis and fluorescence protein measurements.</p> |
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- | <p>We achieved design and compatibility of parts in E.coli, however not all parts’ characterization is achieved. Only the genes of designed composite part from kit plate is characterized by GFP measurements.</p> | + | <p>We achieved design and compatibility of parts in <i>E.coli</i>, however not all parts’ characterization is achieved. Only the genes of designed composite part from kit plate is characterized by GFP measurements.</p> |
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- | <p>In this section you can find out more details on all our wet lab works. You can also find our data under results subtitle and information about design of our parts-biobricks with explanations in literature. It also contains materials and protocols, and finally There is safety questions list on our safety considerations both in the lab and on a wider environmental scale.</p> | + | <p>In this section you can find out more details on all our wet lab works. You can also find our data under results subtitle and information about design of our parts-biobricks with explanations in literature. It also contains materials and protocols, and finally there is safety questions list on our safety considerations both in the lab and on a wider environmental scale.</p> |
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| <img src="https://static.igem.org/mediawiki/2011/1/1b/Humanpractice.png" height="75px" width="890px"> | | <img src="https://static.igem.org/mediawiki/2011/1/1b/Humanpractice.png" height="75px" width="890px"> |
| <h2>Overview</h2> | | <h2>Overview</h2> |
- | <p>Methan<b>E.COLI</b>c project arises from sustainability and conservancy of human health and safety. Therefore while we were constructing the organismic device we also wanted to inform people from all age and we wanted to increase the public awareness on our project; methane gas based (firedamp) explosions and the greenhouse effect of methane gas.</p> | + | <p>Methan<b>E.COLI</b>c projec |
| + | t arises from sustainability and conservancy of human health and safety. Therefore while we were constructing the organismic device we also wanted to inform people from all age and we wanted to increase the public awareness on our project; methane gas based (firedamp) explosions and the greenhouse effect of methane gas.</p> |
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| <p>Our aim is to inform people in each age. After brainstorming and searching, we planned the content of information and activities according to following subtitles.</p> | | <p>Our aim is to inform people in each age. After brainstorming and searching, we planned the content of information and activities according to following subtitles.</p> |
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| <img src="https://static.igem.org/mediawiki/2011/f/f8/Partnershipheader.png" height="75px" width="890px"> | | <img src="https://static.igem.org/mediawiki/2011/f/f8/Partnershipheader.png" height="75px" width="890px"> |
| <h2>PartnerShip</h2> | | <h2>PartnerShip</h2> |
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| + | <li><a href="#partnership2">Collaboration</a></li> |
| + | <li><a href="#partnership3">Sponsors</a></li> |
| + | <li><a href="#partnership4">METU</a></li> |
| + | <li><a href="#partnership5">Acknowledgements</a></li> |
| + | <ul> |
| </div> | | </div> |
| </div> | | </div> |
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| <img src="https://static.igem.org/mediawiki/2011/f/f4/Extraheader.png" height="75px" width="890px"> | | <img src="https://static.igem.org/mediawiki/2011/f/f4/Extraheader.png" height="75px" width="890px"> |
| <h2>Extras</h2> | | <h2>Extras</h2> |
- | <center><div class="extra"><iframe width="646px" height="350px" src="http://www.metu.edu.tr/~e172018/metu-bin/self-evaluation.html"></iframe></div></center> | + | |
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| <div id="slider2"> | | <div id="slider2"> |
| <img src="https://static.igem.org/mediawiki/2011/d/d7/IMG_0788.JPG"> | | <img src="https://static.igem.org/mediawiki/2011/d/d7/IMG_0788.JPG"> |
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| <img src="https://static.igem.org/mediawiki/2011/3/34/DSCN1818.JPG"> | | <img src="https://static.igem.org/mediawiki/2011/3/34/DSCN1818.JPG"> |
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| + | <center><h3>Hands on show!</h3></center> |
| + | <center><iframe width="560" height="315" src="http://www.youtube.com/embed/_b50ti5L1_M" frameborder="0" allowfullscreen></iframe></center> |
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| + | <p><div class="extra"><iframe width="646px" height="350px" src="http://www.metu.edu.tr/~e172018/metu-bin/self-evaluation.html"></iframe></div></p> |
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| + | <center><h3>Photos</h3> |
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| + | <p><img src="https://static.igem.org/mediawiki/2011/2/26/Background.png"></p> |
| + | <p><img src="https://static.igem.org/mediawiki/2011/d/df/Bannergiris2.png"></p> |
| + | <p><img src="https://static.igem.org/mediawiki/2011/d/d1/Bannergiris.png"></p> |
| + | <p><img src="https://static.igem.org/mediawiki/2011/3/3f/Bioguide.png"></p> |
| + | <p><img src="https://static.igem.org/mediawiki/2011/4/4a/Labguardrulez_copy.jpg"></p> |
| + | <p><img src="https://static.igem.org/mediawiki/2011/4/45/Methanecanavar%C4%B1.jpg"></p> |
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| <center><p><img src="https://static.igem.org/mediawiki/2011/1/10/Sensingesas.gif" height="454px" width="640px"></center></p> | | <center><p><img src="https://static.igem.org/mediawiki/2011/1/10/Sensingesas.gif" height="454px" width="640px"></center></p> |
| <h3>i) Introduction </h3> | | <h3>i) Introduction </h3> |
- | <p>In our methane.colic project, the first critical point is to sense the ambient methane gas. While in literature search, we have focused on the methane and DNA or methane and regulator protein interaction which binds to DNA after binding to methane. In structure, methane consists of one carbon atom and four hydrogen atom which means it is smaller in size and weight. Therefore it is hard to find any study based on methane interaction with DNA or protein to regulate transcription. This made us search for carbon hydrogen bond interaction with any oligo or protein to trigger transcription of any metabolite product. So that we also searched the literature for any organism which utilizes any alkane chain and alkane which regulates the transcription of organismal metabolites by interaction with DNA or protein. Since bacteria are environmental adapting organisms, it is possible to find any alkane to regulate the transcription of degradation metabolism. Then we have found the organism, Pseudomonas oleovorans to analyze the alkane degradation of organism for its carbon source.</p> | + | <p>In our methanE.COLIc project, the first critical point is to sense the ambient methane gas. While in literature search, we have focused on the methane and DNA or methane and regulator protein interaction which binds to DNA after binding to methane. In structure, methane consists of one carbon atom and four hydrogen atom which means it is smaller in size and weight. Therefore it is hard to find any study based on methane interaction with DNA or protein to regulate transcription. This made us search for carbon hydrogen bond interaction with any oligo or protein to trigger transcription of any metabolite product. So that we also searched the literature for any organism which utilizes any alkane chain and alkane which regulates the transcription of organismal metabolites by interaction with DNA or protein. Since bacteria are environmental adapting organisms, it is possible to find any alkane to regulate the transcription of degradation metabolism. Then we have found the organism, <i>Pseudomonas oleovorans</i> to analyze the alkane degradation of organism for its carbon source.</p> |
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| <h3>ii) Background </h3> | | <h3>ii) Background </h3> |
- | <p> Many microorganisms live in the environments where the conditions changing frequently and so the evolution is inevitable for mechanisms to withstand unfavorable situations. Therefore microorganisms can use their specific and sensitive mechanisms for sensing the required nutrients for them or any pollution to affect their sustainity. Otherwise they can expose to mutations which change the gene expression and gain new functionalities. In case they have ability to survive in such conditions. </p> | + | <p> Many microorganisms live in the environments where the conditions changing frequently and so the evolution is inevitable for mechanisms to withstand unfavorable situations. Therefore microorganisms can use their specific and sensitive mechanisms for sensing the required nutrients for them or any pollution to affect their sustainability. Otherwise they can expose to mutations which change the gene expression and gain new functionalities. In case they have ability to survive in such conditions. </p> |
| <p>While we were scanning the literature based on methane and alkane degrading organisms we have found some organisms that sensitive to methane presence and have mechanisms to activate transcription of related gene clusters.</p> | | <p>While we were scanning the literature based on methane and alkane degrading organisms we have found some organisms that sensitive to methane presence and have mechanisms to activate transcription of related gene clusters.</p> |
- | <p>We analyzed the soil bacteria, Pseudomonas oleovorans. This strain can assimilate the alkane for its carbon source and one of the microbial whole cell –biosensor. They have a gene cluster which codes for degradative pathway and includes the activator which interacts especially with linear alkanes. This activator protein, AlkS, in the presence of alkanes, induces the transcription from PalkB promoter which initiates the expression of genes code for assimilation of alkanes. We have analyzed the related articles in which the promoter region is studied and showed that it is expressed in E.coli correctly because of the corresponding RNA polymerase binding regions.</p> | + | <p>We analyzed the soil bacteria, <i>Pseudomonas oleovorans</i>. This strain can assimilate the alkane for its carbon source and one of the microbial whole cell –biosensor. They have a gene cluster which codes for degradative pathway and includes the activator which interacts especially with linear alkanes. This activator protein, AlkS, in the presence of alkanes, induces the transcription from PalkB promoter which initiates the expression of genes code for assimilation of alkanes. We have analyzed the related articles in which the promoter region is studied and showed that it is expressed in <i>E.coli</i> correctly because of the corresponding RNA polymerase binding regions.</p> |
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| <b><p>REFERENCE:</p></b> | | <b><p>REFERENCE:</p></b> |
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| <h3>iii) Modelling </h3> | | <h3>iii) Modelling </h3> |
- | <p> Since the parts that we have found belongs to yeast organism, it was hard to us to manipulate it in bacteria E.coli. We designed the tests of this part by characterizing one of the subunits of methane monooxgenase (MMo). For the functional activity of monooxygenase enzyme, there are required 3 subunits as A,B and C. The A subunit of methane monooxygenase is 210 kDa protein that is supposed as the methane binding active site of monoxygenase complex. This protein consists of non-haem iron and contains p-hydroxo bridge structure. We planned the experiments of this step as characterization of protein A by PCR amplification with specific primers of full construct device to obtained the sequence of protein A. The methane gas is applied to cell culture with our modelled device then the cells were centrifuged and the gas concentration is measured from supernatant.</p> | + | <p> Since the parts that we have found belongs to yeast organism, it was hard to us to manipulate it in bacteria <i>E.coli</i>. We designed the tests of this part by characterizing one of the subunits of methane monooxgenase (MMo). For the functional activity of monooxygenase enzyme, there are required 3 subunits as A,B and C. The A subunit of methane monooxygenase is 210 kDa protein that is supposed as the methane binding active site of monoxygenase complex. This protein consists of non-haem iron and contains p-hydroxo bridge structure. We planned the experiments of this step as characterization of protein A by PCR amplification with specific primers of full construct device to obtained the sequence of protein A. The methane gas is applied to cell culture with our modelled device then the cells were centrifuged and the gas concentration is measured from supernatant.</p> |
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| <center><p><iframe width="420" height="315" src="http://www.youtube.com/embed/g6RICJsKQAI" frameborder="0" allowfullscreen></iframe></p></center> | | <center><p><iframe width="420" height="315" src="http://www.youtube.com/embed/g6RICJsKQAI" frameborder="0" allowfullscreen></iframe></p></center> |
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- | <h3>Here is Our Online Lecture, Click the picture to go;</h3> | + | <h3>Here is our Online Lecture, Click the picture to go;</h3> |
| <center><p><a href="http://ocw.metu.edu.tr/course/view.php?id=137" target="_blank" alink="red" vlink="red" ><img src="https://static.igem.org/mediawiki/2011/5/50/Syntheticbiol.png" height="115px" width="632px" alt="Click picture to reach Online Lectures" ></a></center></p> | | <center><p><a href="http://ocw.metu.edu.tr/course/view.php?id=137" target="_blank" alink="red" vlink="red" ><img src="https://static.igem.org/mediawiki/2011/5/50/Syntheticbiol.png" height="115px" width="632px" alt="Click picture to reach Online Lectures" ></a></center></p> |
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| <img src="https://static.igem.org/mediawiki/2011/f/f8/Partnershipheader.png" height="75px" width="890px"> | | <img src="https://static.igem.org/mediawiki/2011/f/f8/Partnershipheader.png" height="75px" width="890px"> |
| <h2>Collaboration</h2> | | <h2>Collaboration</h2> |
- | <h3>Collaboration with Turk teams in iGEM 2011 </h3><br /> | + | <h3>Collaboration with Turkish teams in iGEM 2011 </h3><br /> |
| <br /> | | <br /> |
- | Since iGEM 2007, there is a team to research and prepare a project for iGEM competition from Middle East Technical University(METU). On behalf, there are advisors and instructors who are familiar with competition and content of it. In this year there are 4 registered teams from Turkey and 3 of them are new participants. Therefore in order to come together and criticize our projects and any deficiencies or ambugity related with project. So we organized and arranged a meeting on Synthetic Biology and iGEM competition which is the first in our country.The participants of this meeting were teams;<b>Fatih Turkey, Bilkent_UNAM, METU-BIN</b> and researchers who related with Synthetic Biology and company owners in Biotechnology field also there was special guests via online talk, Drew Endy, he is an assistant Professor of Bioengineering, Stanford University and Scott Mohr Professor of Biological Chemistry, Boston University This meeting was held in September 10, that was close to Regional Jamboree in order to also check the presentation preparations of teams. The news agencies were also invited and the interviews were done with all teams publicity of teams were enhanced. <br /> | + | Since iGEM 2007, there is a team to research and prepare a project for iGEM competition from Middle East Technical University(METU). On behalf, there are advisors and instructors who are familiar with competition and content of it. In this year there are 4 registered teams from Turkey and 3 of them are new participants. Therefore in order to come together and criticize our projects and any deficiencies or ambugity related with project. So we organized and arranged a meeting on Synthetic Biology and iGEM competition which is the first in our country.The participants of this meeting were teams;<b>Fatih Turkey, Bilkent_UNAM, METU-BIN</b> and researchers who related with Synthetic Biology and company owners in Biotechnology field also there was special guests via online talk, Drew Endy, he is an assistant Professor of Bioengineering, Stanford University and Scott Mohr Professor of Biological Chemistry, Boston University This meeting was held in September 10, that was close to Regional Jamboree in order to also check the presentation preparations of teams. The news agencies were also invited and the interviews were done with all teams publicity of teams were enhanced. <br /> |
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| Except from this, we established a collaboration with <b>METU-BIN Software iGEM 2011</b> team on their software program. This year their project, <a href="http://dayhoff.ii.metu.edu.tr:8080/m4b/" target="_blank">M4B: Mining for BioBricks</a> is on enhancement and simplification of parts registry and gene library usage to ease the wet lab researchers job. They requested us to use and try their software program. One of our parts in this year, kill switch is composite of this year distributions. By the way we tried their program to search and try on this composite. we gave them the following as feedback and also according to our comments on visual of program, we had collaborated this year.<br /> | | Except from this, we established a collaboration with <b>METU-BIN Software iGEM 2011</b> team on their software program. This year their project, <a href="http://dayhoff.ii.metu.edu.tr:8080/m4b/" target="_blank">M4B: Mining for BioBricks</a> is on enhancement and simplification of parts registry and gene library usage to ease the wet lab researchers job. They requested us to use and try their software program. One of our parts in this year, kill switch is composite of this year distributions. By the way we tried their program to search and try on this composite. we gave them the following as feedback and also according to our comments on visual of program, we had collaborated this year.<br /> |
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- | <h3>Helping to other new Turk teams in the future</h3> <br /> | + | <h3>Helping to other new Turkish teams in the future</h3> <br /> |
| <br /> | | <br /> |
| Our university, METU has an online lecture application; METU OpenCourseware to support the open information source not only members of METU and to reach people to inform in all ages. In this online application, For Synthetic Biology field, last year the sessions were loaded and this year it is upgraded. The protocols for Synthetic biology methods were downloaded and supported with tutorials of procedures that taken during experiments. We established this page and enhanced for Synthetic Biology to reach more students to meet with Synthetic Biology in any region of Turkey. We had requested from President of METU made people to reach this webpage from universities with related departments in an official way. By the way, we believe to reach more students or researchers to iGEM competition and Synthetic Biology. <br /> | | Our university, METU has an online lecture application; METU OpenCourseware to support the open information source not only members of METU and to reach people to inform in all ages. In this online application, For Synthetic Biology field, last year the sessions were loaded and this year it is upgraded. The protocols for Synthetic biology methods were downloaded and supported with tutorials of procedures that taken during experiments. We established this page and enhanced for Synthetic Biology to reach more students to meet with Synthetic Biology in any region of Turkey. We had requested from President of METU made people to reach this webpage from universities with related departments in an official way. By the way, we believe to reach more students or researchers to iGEM competition and Synthetic Biology. <br /> |
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| <p>We have completed biological system design part of BioGuide and enabled wet lab teams to use it.</p> | | <p>We have completed biological system design part of BioGuide and enabled wet lab teams to use it.</p> |
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- | <h3>You can watch the how to video of BioGuide to see what and how you can do with it;</h3> | + | <h3>You can watch the "how to" video of BioGuide to see what and how you can do with it;</h3> |
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| <center><iframe width="425" height="349" src="http://www.youtube.com/embed/P4pMri0bAMc?hl=en&fs=1" frameborder="0" allowfullscreen></iframe></center> | | <center><iframe width="425" height="349" src="http://www.youtube.com/embed/P4pMri0bAMc?hl=en&fs=1" frameborder="0" allowfullscreen></iframe></center> |
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| <p><i>This year we are using it while building one of our devices, kill switch composite. Kill switch composite consists of 4 main parts which are in 2011 kit plate distributions; T7 promoter, RNA thermometer, GFP and lysis casette. The upstream part of this composite is T7 promoter (BBa_I712074) which is strong promoter from T7 bacteriophage mostly used expression system and so for strong transcription T7 promoter expression system is chosen.</p> | | <p><i>This year we are using it while building one of our devices, kill switch composite. Kill switch composite consists of 4 main parts which are in 2011 kit plate distributions; T7 promoter, RNA thermometer, GFP and lysis casette. The upstream part of this composite is T7 promoter (BBa_I712074) which is strong promoter from T7 bacteriophage mostly used expression system and so for strong transcription T7 promoter expression system is chosen.</p> |
| <p>We also tried the inducible promoters (pLac-IPTG inducer) to design and express the lysis casette. We desired to use a promoter that could be induced and enhance the expression to control and manipulate the translation of device. When we typed IPTG on input box of Bioguide we had reached the possible promoters that could be induced by IPTG. This program gave their standard biobrick codes and finally we got these parts by knowing their location in kit plate.</p> | | <p>We also tried the inducible promoters (pLac-IPTG inducer) to design and express the lysis casette. We desired to use a promoter that could be induced and enhance the expression to control and manipulate the translation of device. When we typed IPTG on input box of Bioguide we had reached the possible promoters that could be induced by IPTG. This program gave their standard biobrick codes and finally we got these parts by knowing their location in kit plate.</p> |
- | <p>In downstream of promoter there is RNA thermometer(ROSE) coding region which determines the transcription of our lysis composite part. We had reached this part by coding the temperature 42 in input box of BioGuide. RNA thermometer (BBa_K115001) is temperature sensitive at which 42C translation initiates. </p> | + | <p>In downstream of promoter there is RNA thermometer(ROSE) coding region which determines the transcription of our lysis composite part. We had reached this part by coding the temperature 42 C in input box of BioGuide. RNA thermometer (BBa_K115001) is temperature sensitive at which 42 C translation initiates. </p> |
| <p>In downstream of RNA thermometer, green fluorescence protein(BBa_E0040) is ligated. This ligation is done to measure expression level and to comment on RNA thermometer efficiency. We typed GFP in output box since we wanted to measure fluorescence.</p> | | <p>In downstream of RNA thermometer, green fluorescence protein(BBa_E0040) is ligated. This ligation is done to measure expression level and to comment on RNA thermometer efficiency. We typed GFP in output box since we wanted to measure fluorescence.</p> |
- | <p>We had designed this composite and it's parts mostly by processing the BioGuide program that made our job easier in intense lab works. We reached the shortest path with our input and output parameters for this device to construct by BioGuide</i></p> | + | <p>We had designed this composite and it's parts mostly by processing the BioGuide program that made our job easier in intense lab works. We reached the shortest path with our input and output parameters for this device to construct by BioGuide.</i></p> |
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| </div> | | </div> |
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| <h3>i) Introduction </h3> | | <h3>i) Introduction </h3> |
| | | |
- | <p>When examined in order, conversion is the second step of device system. While in literature searches, it is found that methanotrophs which live in either extreme conditions or in deep oceans, the process is the same, methane is converted to methanol which is the oxygenated form of hydrocarbon group. The searches directed us to organism Methylococcus capsulatus which is one of the mostly studied organisms among methanotrophs. We designed the conversion part of this organism and modified coding operon according to E.coli strain to enhance the expression. The monoxygenase coding part with protein A, B and C products are designed for conversion step of this project.</p> | + | <p>When examined in order, conversion is the second step of device system. While in literature searches, it is found that methanotrophs which live in either extreme conditions or in deep oceans, the process is the same, methane is converted to methanol which is the oxygenated form of hydrocarbon group. The searches directed us to organism <i>Methylococcus capsulatus</i> which is one of the mostly studied organisms among methanotrophs. We designed the conversion part of this organism and modified coding operon according to <i>E.coli</i> strain to enhance the expression. The monoxygenase coding part with protein A, B and C products are designed for conversion step of this project.</p> |
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| <h3>ii) Background </h3> | | <h3>ii) Background </h3> |
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| <h4>a) Soluble Methane Monooxygenase </h4> | | <h4>a) Soluble Methane Monooxygenase </h4> |
- | <p> In contrast to pMMO, sMMO has extremely broad substrate specificity and can oxidise a wide range of non-growth substrates such as alkanes, alkenes and aromatic compounds thus making it the more attractive enzyme for co-oxidation reactions. sMMO is expressed only under conditions in which the copper-to-biomass ratio is low, i.e. under “low-copper” growth conditions, when copper ions are omitted from the trace elements solution of a standard mineral salts medium or cells are grown in a fermentor to high cell densities.There is also some evidence that copper ions inhibit the activity of sMMO (Jahng and Wood 1996). Like many other multi-component oxygenase systems, sMMO contains a component of approximately 16 kDa, Protein B, which serves an “effector” or regulatory role. The activity of Protein B may be regulated by proteolysis at its amino terminus (Lloyd et al. 1997). At low concentrations, Protein B converts the hydroxylase from an oxidase and stabilizes intermediates necessary for oxygen activation. Saturating amounts of Protein B dramatically increase the rates of formation of intermediates and accelerate catalysis of methane to methanol by sMMO (Lee and Lipscomb 1999). When analyzed, the most extensively characterised sMMO enzymes are those from Methylococcus capsulatus (Bath) and Methylosinus trichosporium OB3b (reviewed in Lipscomb 1994; Deeth and Dalton 1998). Therefore we preferred to study on Methylococcus capsulatus (Bath) for monooxygenase.The sMMO is a non-haem iron-containing enzyme complex consisting of three components. The hydroxylase consists of three subunits of 60, 45 and 20 kDa arranged in an α2 β2 γ2 configuration. sMMO genes are clustered on the chromosome of Methylococcus capsulatus (Bath) and Methylosinus trichosporium OB3b. mmoX, mmoY and mmoZ encode the α-, β- and γ-subunits respectively of the hydroxylase. mmoB and mmoC code for Protein B and the reductase component. Interestingly, mmoB lies between mmoY and mmoZ; an ORF of unknown function, designated orfY, with a coding capacity of 12 kDa, lies between mmoZ and mmoC in all genes clusters analysed to date (McDonald et al. 1997).</p> | + | <p> In contrast to pMMO, sMMO has extremely broad substrate specificity and can oxidise a wide range of non-growth substrates such as alkanes, alkenes and aromatic compounds thus making it the more attractive enzyme for co-oxidation reactions. sMMO is expressed only under conditions in which the copper-to-biomass ratio is low, i.e. under “low-copper” growth conditions, when copper ions are omitted from the trace elements solution of a standard mineral salts medium or cells are grown in a fermentor to high cell densities.There is also some evidence that copper ions inhibit the activity of sMMO (Jahng and Wood 1996). Like many other multi-component oxygenase systems, sMMO contains a component of approximately 16 kDa, Protein B, which serves an “effector” or regulatory role. The activity of Protein B may be regulated by proteolysis at its amino terminus (Lloyd et al. 1997). At low concentrations, Protein B converts the hydroxylase from an oxidase and stabilizes intermediates necessary for oxygen activation. Saturating amounts of Protein B dramatically increase the rates of formation of intermediates and accelerate catalysis of methane to methanol by sMMO (Lee and Lipscomb 1999). When analyzed, the most extensively characterised sMMO enzymes are those from <i>Methylococcus capsulatus</i> (Bath) and <i>Methylosinus trichosporium</i> OB3b (reviewed in Lipscomb 1994; Deeth and Dalton 1998). Therefore we preferred to study on <i>Methylococcus capsulatus</i> (Bath) for monooxygenase.The sMMO is a non-haem iron-containing enzyme complex consisting of three components. The hydroxylase consists of three subunits of 60, 45 and 20 kDa arranged in an α2 β2 γ2 configuration. sMMO genes are clustered on the chromosome of <i>Methylococcus capsulatus</i> (Bath) and <i>Methylosinus trichosporium</i> OB3b. mmoX, mmoY and mmoZ encode the α-, β- and γ-subunits respectively of the hydroxylase. mmoB and mmoC code for Protein B and the reductase component. Interestingly, mmoB lies between mmoY and mmoZ; an ORF of unknown function, designated orfY, with a coding capacity of 12 kDa, lies between mmoZ and mmoC in all genes clusters analysed to date (McDonald et al. 1997).</p> |
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| <p> <b>REFERENCE:</b></p> | | <p> <b>REFERENCE:</b></p> |
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| <p>This group consists of high school aged children groups.Through out the workshop, we have paired them in doubles. Firstly, we have explained Synthetic Biolgy and what Synthetic Biology is able to do. After these training, we explained them our project and taught them basic molecular biology procedures and what are the requirements of basic synthetic biology based experiments. We have done the experiments (cloning procedures) together and also they did individually. We also encouraged them to join iGEM High School division.</p> | | <p>This group consists of high school aged children groups.Through out the workshop, we have paired them in doubles. Firstly, we have explained Synthetic Biolgy and what Synthetic Biology is able to do. After these training, we explained them our project and taught them basic molecular biology procedures and what are the requirements of basic synthetic biology based experiments. We have done the experiments (cloning procedures) together and also they did individually. We also encouraged them to join iGEM High School division.</p> |
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- |
| + | <h3> Official Announcement To All Universities For Introduction Of Synthetic Biology and iGEM Competetion</h3> |
| + | |
| + | <p>For the last human practice approach, we believed that we should inform especially students from other universities about synthetic biology as students in universities are the ones who can improve this field for further generations. For that purpose, we published an official message from our instructor, Prof. Dr. Mahinur Akkaya, with this message, students from other universities –regardless of their department that they’re studying in- will be aware of the field synthetic biology and may not only consider about learning more but also consider about creating an iGEM team for coming years. Here is the original official message and its brief translation for you to read:<br /> |
| + | Dean Office of Arts and Science Department<br /> |
| + | Synthetic biology is a field where natural sciences and engineering sciences go together hand in hand. It is an emerging science that requires the literature search, knowledge of natural sciences and methods of engineering sciences. Synthetic biology is the engineering of organisms to give them desired properties, except their regular metabolic activities. These desired properties are entegrated into genome of the organism with molecular cloning procedures.<br /> |
| + | There are lots of studies going on to introduce this newly emerging science field to people from all age groups and producing an information repository and improving it at the same time. One of this studies is the iGEM (International Genetically Engineered Machines) competition.<br /> |
| + | We, as METU iGEM teams, are attending this competition for four years. For this newly emerging science field to improve more, we believe that it should be spread out to other universities and more and more people should attend this competiton. We are sending you our study about the videos of lab protocols that are mainly used in synthetic biology and references that you can search for more information. We feel honored to tell that these sources are available for everyone who would like to reach them. Links for the sources are as follows:<br /> |
| + | <a href="http://ocw.metu.edu.tr/course/view.php?id=137">http://ocw.metu.edu.tr/course/view.php?id=137</a> <br /> |
| + | <a href="http://www.youtube.com/user/Metuankara">http://www.youtube.com/user/Metuankara</a> |
| + | <br /> |
| + | <br /> |
| + | <p><img width="900px" src="https://static.igem.org/mediawiki/2011/b/bc/Imagetif.png"></p> |
| + | <br /> |
| + | <br /> |
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| <h3>18-24 year old group</h3> | | <h3>18-24 year old group</h3> |
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| <center><p><img src="https://static.igem.org/mediawiki/2011/c/c2/Entrapment.gif" height="454px" width="640px"></center></p> | | <center><p><img src="https://static.igem.org/mediawiki/2011/c/c2/Entrapment.gif" height="454px" width="640px"></center></p> |
| <h3>i) Introduction</h3> | | <h3>i) Introduction</h3> |
- | <p>After conversion of methane to methanol, the successive step is the entrapment of methanol. Methanol is an alcohol form of hydrocarbon methane and includes hydroxyl group. Hydroxyl radical groups are highly reactive and, and so short-lived; however, they form an important part of radical chemistry. Hydroxyl groups are especially important in biological systems and their chemistry because free radicals tend to form hydrogen bonds both as donor and acceptor. This property is also related to their ability to increase hydrophilicity and water solubility. Therefore hydroxyl free radicals cause damage to oxidative cells and cellular membranes. In order to produce the methanol for further industrial manufacturing in cellular organism, the organismic conditions should be adjusted. In the light of this, for our bacterial system we transferred the protein coding sequence(named as LUSH) of Drosophilia melanogaster to attack to free methanols and hydroxyl group. Here is some structural information about protein LUSH.</p> | + | <p>After conversion of methane to methanol, the successive step is the entrapment of methanol. Methanol is an alcohol form of hydrocarbon methane and includes hydroxyl group. Hydroxyl radical groups are highly reactive and, and so short-lived; however, they form an important part of radical chemistry. Hydroxyl groups are especially important in biological systems and their chemistry because free radicals tend to form hydrogen bonds both as donor and acceptor. This property is also related to their ability to increase hydrophilicity and water solubility. Therefore hydroxyl free radicals cause damage to oxidative cells and cellular membranes. In order to produce the methanol for further industrial manufacturing in cellular organism, the organismic conditions should be adjusted. In the light of this, for our bacterial system we transferred the protein coding sequence(named as LUSH) of <i>Drosophilia melanogaster</i> to attack to free methanols and hydroxyl group. Here is some structural information about protein LUSH.</p> |
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| <h3>ii) Background</h3> | | <h3>ii) Background</h3> |
- | <p>LUSH is an alcohol-sensitive odorant binding protein expressed in the olfactory organs of Drosophila melanogaster, and it is used as a model system to investigate the biophysical nature of | + | <p>LUSH is an alcohol-sensitive odorant binding protein expressed in the olfactory organs of <i>Drosophila melanogaster</i>, and it is used as a model system to investigate the biophysical nature of |
| alcohol-protein interactions at alcohol concentrations that produce intoxication in humans. In this study, by using NMR spectroscopy, they have identified the regions of LUSH that show increased conformational stability on binding alcohols. These residues primarily line the alcohol-binding pocket. A direct measure of the degree of stability that alcohol imparts on LUSH has been provided. LUSH was originally identified as responsible for mediating an avoidance response to short-chain n-alcohols.</p> | | alcohol-protein interactions at alcohol concentrations that produce intoxication in humans. In this study, by using NMR spectroscopy, they have identified the regions of LUSH that show increased conformational stability on binding alcohols. These residues primarily line the alcohol-binding pocket. A direct measure of the degree of stability that alcohol imparts on LUSH has been provided. LUSH was originally identified as responsible for mediating an avoidance response to short-chain n-alcohols.</p> |
| <p>The general structure of odorant binding proteins consists of six α-helices surrounding a hydrophobic ligand- binding pocket which differs in size and shape between each protein. All these odorant binding proteins have a set of six cysteines that form three conserved disulfide bonds. In the study, by observing the X-ray crystal structures of LUSH-alcohol complexes, it was found that alcohol binds to a single site in the protein formed by a network of concerted hydrogen-binding residues located at one end of hyrophobic pocket. This binding site has some sequence and/or structural similarities to regions of several ligand gated ion channels (LGICs) that have previously been implicated in inferring sensitivity to alcohol. It is hypothesized in the study that the alcohol-binding site in LUSH may represent a more general structural motif for functionally relevant alcohol-binding sites in proteins. The characterization of the effects of n-alcohols on the structure and stability of LUSH is presented. Also, in the absence of ligand, LUSH exists in vitro in a partially unstructured state and binding of alcohols shifts the solution conformation to a more compact folded state which is accompanied by an increase in the overall protein stability. Those regions of the protein that show the largest changes in local dynamics on binding alcohol have been identified and it have been shown that these are predominantly associated with the residues that line the alcohol-binding pocket. The results provide a quantitative measure of the ability of short-chain alcohols to stabilize protein structure at physiological relevant concentrations. </p> | | <p>The general structure of odorant binding proteins consists of six α-helices surrounding a hydrophobic ligand- binding pocket which differs in size and shape between each protein. All these odorant binding proteins have a set of six cysteines that form three conserved disulfide bonds. In the study, by observing the X-ray crystal structures of LUSH-alcohol complexes, it was found that alcohol binds to a single site in the protein formed by a network of concerted hydrogen-binding residues located at one end of hyrophobic pocket. This binding site has some sequence and/or structural similarities to regions of several ligand gated ion channels (LGICs) that have previously been implicated in inferring sensitivity to alcohol. It is hypothesized in the study that the alcohol-binding site in LUSH may represent a more general structural motif for functionally relevant alcohol-binding sites in proteins. The characterization of the effects of n-alcohols on the structure and stability of LUSH is presented. Also, in the absence of ligand, LUSH exists in vitro in a partially unstructured state and binding of alcohols shifts the solution conformation to a more compact folded state which is accompanied by an increase in the overall protein stability. Those regions of the protein that show the largest changes in local dynamics on binding alcohol have been identified and it have been shown that these are predominantly associated with the residues that line the alcohol-binding pocket. The results provide a quantitative measure of the ability of short-chain alcohols to stabilize protein structure at physiological relevant concentrations. </p> |
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| <img src="https://static.igem.org/mediawiki/2011/2/28/Wetlabheader.png" height="75px" width="890px"> | | <img src="https://static.igem.org/mediawiki/2011/2/28/Wetlabheader.png" height="75px" width="890px"> |
| <h2>Contact</h2> | | <h2>Contact</h2> |
| + | <strong>Device Experiment Results</strong><br /> |
| + | <br /> |
| + | -<strong>Flask experiments</strong><br /> |
| + | <br /> |
| + | In characterization experiments, we choosed temperature sensitive RNA thermometer (BBa_K115001) and modelled the experiments on GFP measurements. RNA thermometer is a temperature sensitive DNA part that up to 42 C it forms a dimer. This dimer formation prevents polymerase readings that the translation is obstructed. At 42 C the linear form of part forms and translation initiates. This part is submitted to parts registry by iGEM 2008 TUDelft team and the experience of part is represented as none. We modelled the characterization of this part by planing two apart control groups.<br /> |
| + | <br /> |
| + | One pair group for characterization was T7 promoter,RNA thermometer and GFP from upstream to downstream at 37C and the same device at 42C. The aim of this control group was to control any expression of green fluorescence protein at 37 C to check RNA thermometer dimer formation. We prepared a flask experiments and from protein formation to folding range we measured the spectrophotometer and fluoresence spectrometer readings. It is showed the dimer formation of RNA thermometer at lower than 42 C caused inefficient binding of RBS to DNA. That means we measured the GFP readings at two temperatures however at 42 C the expression was observed in higher level. As seen at OD:0.6 reading there is a dramatic difference in expressions.<br /> |
| + | <br /> |
| + | Other pair group for characterization was T7 promoter with GFP at 37 C and T7 promoter,RNA thermometer and GFP from upstream to downstream at 42C. This control group was modelled in order to check and compare the expression levels of two devices. The expected result was to observe the similar readings. Because without RNA thermometer temperature switch off device express similar readings at 37C with RNA thermometer device at 42 C. In the data analysis we observed that there is deviation in readings between control T7 with GFP at 37C and to construct, T7 RNA thermometer and GFP at 42 C.<br /> |
| + | <br /> |
| + | <br /> |
| + | <center><h3>GFP Reading Data</h3> |
| + | <p><img src="https://static.igem.org/mediawiki/2011/d/db/Datapage.png"></p> |
| + | <br /> |
| + | <br/> |
| + | <p><img width="900px" src="https://static.igem.org/mediawiki/2011/3/34/Ans_paper.jpg"></center></p> |
| + | <br /> |
| + | <br /> |
| + | <p><strong>Assembly Results</strong><br /> |
| + | <br /> |
| + | According our clonning plan, we planned to ligate the coding sequences of methane monooxygenase as subunits and to express the functional monooxygenase enzyme. Since we synthesized the long coding sequence we did PCR experiments with specific primers we extracted the parts in each the gel electrophoresis results gave validation for successfully synthesied DNA fragments, then we digested and ligated each part with related promoters and vector (pSB1C3) again gel electrophoresis data gave us validation to correctly digest and ligated form. <br /> |
| + | <br /> |
| + | <br /> |
| + | <br /> |
| + | <center><p><img src="https://static.igem.org/mediawiki/2011/2/28/1KB-Ladder-X-Lush.png"> |
| + | <br /> |
| + | <br /> |
| + | <br /> |
| + | <img src="https://static.igem.org/mediawiki/2011/e/ec/09%2C16-1kb-control-mmoB-D-Z-C.png"> |
| + | <br /> |
| + | <br /> |
| + | <br /> |
| + | <img src="https://static.igem.org/mediawiki/2011/6/6c/Z-B-c3-c.png"> |
| + | <br /> |
| + | <br /> |
| + | <br /> |
| + | <img src="https://static.igem.org/mediawiki/2011/a/a5/09%2C19-a3-d-lush.png"> |
| + | <br /> |
| + | <br /> |
| + | <br /> |
| + | <img src="https://static.igem.org/mediawiki/2011/e/e4/09%2C18-1k%C4%B1b-D-control-C-Z.png"></p></center> |
| + | <br /> |
| + | <br /> |
| + | <br /> |
| + | |
| + | <br /> |
| + | <br /> |
| + | <strong>-The device parts control experiments</strong></p> |
| + | <p>The synthesized methane monoxygenase construct was so long part that we had problems in synthesizing that we got genes so late. By the way the long sequence was divided into two sequences that one of the regions were splitted into two parts therefore we could not ligated the two parts of coding sequence due to unidentified restriction sites, and full construct unfortunately did not reach to us. The main methane interacting region of monooxygenase could not be expressed functionally. |
| + | We expressed the protein B and C of methane monoxygenase encoeded from mmo B and mmo C genes in protein expression host E.coli BL21 strain. We planned to characterize the proteins in their theoretical molecular weights by SDS-PAGE analysis. However due to technical problems in gel formation we lost samples that we could not reached the data. |
| + | We planned another part on kit plate distributions to check works or not. The bacteriophage 21 lysis casette S, R, and Rz (PVJ4) (BBa_K124003). This part was designed by 2008 iGEM Brown team which induces lysis in E.coli bacteria. We ligated this part with ROSE regulated GFP generator to induce the lysis of bacteria at 42C. Apart from this ligate, we ligated lysis casette with plac promoter and lacZ expressing gene to observe the blue colonies on plates. However we could not observe any blue colony on plates. |
| + | |
| + | </p> |
| + | |
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| </div> | | </div> |
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- | | + | <center><p><iframe width="560" height="315" src="http://www.youtube.com/embed/gdRz8IICg5E" frameborder="0" allowfullscreen></iframe></p></center> |
| <br /> | | <br /> |
| <p>In order to reach more people from several age groups, we have organized a flashmob activity which is related with our project -in molecular level-. (A flashmob is an activity done by a group of people who assemble suddenly in a public <a href="http://en.wikipedia.org/wiki/Public_place " target="_blank">place</a>, perform an unusual and sometimes seemingly pointless act for a brief time, then disperse, often for the purposes of entertainment, satire, artistic expression. Flashmob activities are organized via <a href="http://en.wikipedia.org/wiki/Telecommunications" target="_blank">telecommunications</a>, <a href="http://en.wikipedia.org/wiki/Social_media" target="_blank">social media</a>, or <a href="http://en.wikipedia.org/wiki/Viral_email " target="_blank">viral emails</a> ).One of our group member who is also a member of Flashmob society in Ankara helped us for arrangements. We use flashmob activity in order to explain what our project is and to increase the public awareness about Synthetic Biology and especially about our project. Flashmob event took place at one of the biggest shopping malls in Ankara where people often strolled around. Afterwards, we had interviewed with people who watched our sketch and informed people about nearly limitless capabilities of synthetic biology. Indeed we prepared handouts that contains interesting statistical data about methane and its side effects, also information about iGEM and about our project.</p> | | <p>In order to reach more people from several age groups, we have organized a flashmob activity which is related with our project -in molecular level-. (A flashmob is an activity done by a group of people who assemble suddenly in a public <a href="http://en.wikipedia.org/wiki/Public_place " target="_blank">place</a>, perform an unusual and sometimes seemingly pointless act for a brief time, then disperse, often for the purposes of entertainment, satire, artistic expression. Flashmob activities are organized via <a href="http://en.wikipedia.org/wiki/Telecommunications" target="_blank">telecommunications</a>, <a href="http://en.wikipedia.org/wiki/Social_media" target="_blank">social media</a>, or <a href="http://en.wikipedia.org/wiki/Viral_email " target="_blank">viral emails</a> ).One of our group member who is also a member of Flashmob society in Ankara helped us for arrangements. We use flashmob activity in order to explain what our project is and to increase the public awareness about Synthetic Biology and especially about our project. Flashmob event took place at one of the biggest shopping malls in Ankara where people often strolled around. Afterwards, we had interviewed with people who watched our sketch and informed people about nearly limitless capabilities of synthetic biology. Indeed we prepared handouts that contains interesting statistical data about methane and its side effects, also information about iGEM and about our project.</p> |