Difference between revisions of "Team:Queens Canada/Collaborations"
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<h2>External Collaborations</h2> | <h2>External Collaborations</h2> | ||
<h3><em>The Ontario Genetically Engineered Machine Network (oGEM)</em></h3> | <h3><em>The Ontario Genetically Engineered Machine Network (oGEM)</em></h3> | ||
<p>Queen’s Canada attended the annual oGEM meeting hosted by the McMaster University. We had the pleasure | <p>Queen’s Canada attended the annual oGEM meeting hosted by the McMaster University. We had the pleasure | ||
| − | + | of being in the company of iGEM teams from the Universities of Toronto, Guelph, Waterloo, Brock, | |
| − | + | Ottawa, and Western Ontario. McMaster iGEM Team directed the conversation on the awareness and | |
| − | + | challenges faced by the synthetic biology community in Canada. The lack of self and social awareness | |
| − | + | in the community was thought to be caused by the fact that synthetic biology is indeed an | |
| − | + | interdisciplinary subject and it requires expertise in all branches of science and engineering. | |
| − | + | It is quite difficult for such a large multidisciplinary group to recognize themselves, and other | |
| − | + | members as one of their own, leading to the absence of communication and combined resources. On top | |
| − | + | of that, as a newly emerging field of study, synthetic biology has yet to be clearly defined. The | |
| − | + | general public might have the foggiest idea what this community aims to achieve, and misconceptions | |
| − | + | about genetic engineering continue to cause fear and resistance in the society. The rest of the | |
| − | + | conversation was dedicated to devising solutions to these challenges. Firstly, it is important that | |
| − | + | the synthetic biology community finds a suitable definition for its work which would be agreed by | |
| − | + | all of its members. The second focus shall be improving education at the undergrad level to increase | |
| − | + | student interests in synthetic biology. All the iGEM teams present were very eager to share their | |
| − | + | experiences in recruitment and outreach, members from the University of Western have especially | |
| − | + | shared their path of creating a program for synthetic biology at their university. The discussion | |
| − | + | was concluded with remarks on actions to be taken to gather resources and suggestions for future | |
| − | + | Canada-wide conferences. | |
</p> | </p> | ||
<figure> | <figure> | ||
<img src="https://static.igem.org/mediawiki/2018/a/a7/T--Queens_Canada--oGEM2018.jpg" alt='ogem' width=60% height=60% /> | <img src="https://static.igem.org/mediawiki/2018/a/a7/T--Queens_Canada--oGEM2018.jpg" alt='ogem' width=60% height=60% /> | ||
<figcaption>Members of Ontario, Canada iGEM teams including representation from Queen’s University, The Universities | <figcaption>Members of Ontario, Canada iGEM teams including representation from Queen’s University, The Universities | ||
| − | + | of Toronto, McMaster, Guelph, Waterloo, Brock, Ottawa, and Western Ontario. Hosted at McMaster University, | |
| − | + | Hamilton Ontario, July 28th, 2018.</figcaption> | |
</figure> | </figure> | ||
<h3><em>Team Stony Brook</em></h3> | <h3><em>Team Stony Brook</em></h3> | ||
<p>This project required the use of a directed evolution approach using error-prone PCR methods. While | <p>This project required the use of a directed evolution approach using error-prone PCR methods. While | ||
| − | + | reading about other team’s projects, we came across a fellow iGEM team located at Stony Brook University | |
| − | + | in New York was evaluating the use of directed evolution of <em>Synechococcus elongatus</em> to create | |
| − | + | sustainable sucrose feedstocks for ethanol biofuel production. This discovery created the basis for | |
| − | + | further discussion about which protocols are most efficient when performing directed evolution. Upon | |
| − | + | speaking with our fellow iGEM team, we learned about other directed evolution techniques, such as UV | |
| − | + | mutagenesis and phage display directed evolution. With these ideas in mind, we collectively decided | |
| − | + | that other teams may also be trying to determine the most effective type of directed evolution for | |
| − | + | their project and thought we could combine each of our groups’ knowledge and experiences to aid future | |
| − | + | iGEM teams. We believe that an effective route to convey this information would be in the format of a | |
| − | + | short, detailed video, that both of our teams could collectively contribute to, as well a pamphlet | |
| − | + | highlighting a variety of directed evolution techniques, available resources and current literature. | |
</p> | </p> | ||
| Line 87: | Line 87: | ||
<h3><em>Makerere University</em></h3> | <h3><em>Makerere University</em></h3> | ||
<p>After being graciously awarded an Opentrons OT-2 automatic pipetting robot, we were eager to find other | <p>After being graciously awarded an Opentrons OT-2 automatic pipetting robot, we were eager to find other | ||
| − | + | teams that we could share protocols and tips with. Speaking with iGEM Makerere, we both had a lot of | |
| − | + | questions surrounding wet lab protocols, dry lab modelling, and practical applications of our respective | |
| − | + | projects that could be answered by the other team’s diverse knowledge and unique experiences. For | |
| − | + | example, the Makerere team stated that a metabolic by-product of the degradation of plastics by microbes | |
| − | + | is ethylene glycol, however they couldn’t decide on a practical use for this by-product. As Canadians, | |
| − | + | we know ethylene glycol well, as it is the major component of antifreeze for windshield frost in the | |
| − | + | winter! We suggested that their by-product could be used in cryopreservatives here in Canada. | |
| − | + | Ultimately, through various Skype calls and email exchanges, members of both our teams were able to | |
| − | + | assist the other with different aspects of the projects. Our dry lab teams were able to collaborate with | |
| − | + | various 3D modelling techniques in PyMOL, as well as wiki formatting. | |
</p> | </p> | ||
<img src="https://static.igem.org/mediawiki/2018/5/54/T--Queens_Canada--MakerereUni.png" width=40% height=40% /> | <img src="https://static.igem.org/mediawiki/2018/5/54/T--Queens_Canada--MakerereUni.png" width=40% height=40% /> | ||
| Line 102: | Line 102: | ||
| − | <div class="column full_size" style="width: | + | <div class="column full_size" style="width:70%;margin-left:15%"> |
<h2>Internal Collaborations</h2> | <h2>Internal Collaborations</h2> | ||
<h3><em>Queen's Biomedical Innovation Team (QBiT)</em></h3> | <h3><em>Queen's Biomedical Innovation Team (QBiT)</em></h3> | ||
<p><img style="float:left; margin-right:15px;" src="https://static.igem.org/mediawiki/2018/6/6a/T--Queens_Canada--QBIT.png" width=20% height=20% /> | <p><img style="float:left; margin-right:15px;" src="https://static.igem.org/mediawiki/2018/6/6a/T--Queens_Canada--QBIT.png" width=20% height=20% /> | ||
| − | + | The Queen’s Biomedical Innovation Team is an undergraduate student-run, interdisciplinary design team | |
| − | + | that focuses on biomedical device design and innovation. This year QGEM has collaborated with QBiT in | |
| − | + | the production of a pacifier devicer which will utilize our engineered protein construct for the | |
| − | + | detection of salivary analytes. Features of the pacifier design include: | |
| − | + | <ul> | |
| − | + | <li>A one-way valve nipple to passively collect saliva from the infants mouth, while preventing any | |
| − | + | backflow of the engineered protein from the internal components towards the infants mouth.</li> | |
| − | + | <li>A circuit board containing a photon-counter chip, a battery, and a Bluetooth Low Energy Beacon. | |
| − | + | These three components allow for the detection of bioluminesce produced by active luciferase, | |
| − | + | the transmission of this data over Bluetooth Low Energy to a smartphone device.</li> | |
| − | + | <li>A 3D printer polylactic acid polymer casing.</li> | |
| − | + | </ul> | |
</p><br> | </p><br> | ||
<h3><em>Queen's Reduced Gravity Experimental Design Team</em></h3> | <h3><em>Queen's Reduced Gravity Experimental Design Team</em></h3> | ||
<p><img style="float:left; margin-right:15px; margin-bottom:30px;" src="https://static.igem.org/mediawiki/2018/6/67/T--Queens_Canada--QRGX.png" width=20% height=20% /> | <p><img style="float:left; margin-right:15px; margin-bottom:30px;" src="https://static.igem.org/mediawiki/2018/6/67/T--Queens_Canada--QRGX.png" width=20% height=20% /> | ||
| − | + | The Queen’s Reduced Gravity Experimental Design Team is an undergraduate student-run team which will be | |
| − | + | participating in an upcoming flight mission in collaboration with the National Research Council, | |
| − | + | Canadian Space Agency, and Students for the Exploration and Development of Space in July. QRGX are | |
| − | + | winners of the Canadian Reduced Gravity Experiment Design Challenge (http://seds.ca/projects) and have | |
| − | + | been selected to conduct an experiment comparing DNA Polymerase I processivity and error rate in | |
| − | + | microgravity vs normal gravity. This year QGEM will be accompanying them on their flight mission and | |
| − | + | providing them with technical expertise and access to our laboratory equipment. | |
</p> | </p> | ||
</div> | </div> | ||
Revision as of 23:14, 18 September 2018
External Collaborations
The Ontario Genetically Engineered Machine Network (oGEM)
Queen’s Canada attended the annual oGEM meeting hosted by the McMaster University. We had the pleasure of being in the company of iGEM teams from the Universities of Toronto, Guelph, Waterloo, Brock, Ottawa, and Western Ontario. McMaster iGEM Team directed the conversation on the awareness and challenges faced by the synthetic biology community in Canada. The lack of self and social awareness in the community was thought to be caused by the fact that synthetic biology is indeed an interdisciplinary subject and it requires expertise in all branches of science and engineering. It is quite difficult for such a large multidisciplinary group to recognize themselves, and other members as one of their own, leading to the absence of communication and combined resources. On top of that, as a newly emerging field of study, synthetic biology has yet to be clearly defined. The general public might have the foggiest idea what this community aims to achieve, and misconceptions about genetic engineering continue to cause fear and resistance in the society. The rest of the conversation was dedicated to devising solutions to these challenges. Firstly, it is important that the synthetic biology community finds a suitable definition for its work which would be agreed by all of its members. The second focus shall be improving education at the undergrad level to increase student interests in synthetic biology. All the iGEM teams present were very eager to share their experiences in recruitment and outreach, members from the University of Western have especially shared their path of creating a program for synthetic biology at their university. The discussion was concluded with remarks on actions to be taken to gather resources and suggestions for future Canada-wide conferences.
Team Stony Brook
This project required the use of a directed evolution approach using error-prone PCR methods. While reading about other team’s projects, we came across a fellow iGEM team located at Stony Brook University in New York was evaluating the use of directed evolution of Synechococcus elongatus to create sustainable sucrose feedstocks for ethanol biofuel production. This discovery created the basis for further discussion about which protocols are most efficient when performing directed evolution. Upon speaking with our fellow iGEM team, we learned about other directed evolution techniques, such as UV mutagenesis and phage display directed evolution. With these ideas in mind, we collectively decided that other teams may also be trying to determine the most effective type of directed evolution for their project and thought we could combine each of our groups’ knowledge and experiences to aid future iGEM teams. We believe that an effective route to convey this information would be in the format of a short, detailed video, that both of our teams could collectively contribute to, as well a pamphlet highlighting a variety of directed evolution techniques, available resources and current literature.
University of Calgary Collaboration
Members of the University of Calgary iGEM team, and members of the Queens Canada team were selected as winners of the Canadian Reduced Gravity Experiment Design Challenge (CAN-RGX), a Canada-wide competition run by the Students for the Exploration and Development of Space (SEDS), in collaboration with the National Research Council, and Canadian Space Agency. This provided an unpresented opportunity to collaborate, and facilitate discussions on genetic engineering, engaging students in STEM research and competitions, and biomedical sciences education in Canada. Members of the University of Calgary team and Queen’s Canada teams have met up multiple times, and had skype calls to share ideas and troubleshoot problems, including strategies to synthesize complex gene fragments, accessing university funding, STEM research at Canadian universities, laboratory techniques, check-ins on each others progress, the difficulties of performing life sciences research in zero gravity, and plans for helping to share the fantastic learning opportunities that iGEM and CAN-RGX provide for ambitious science students. We have had nothing but great experience working alongside the University of Calgary Team, and we wish them success at the 2018 iGEM Jamboree!
Makerere University
After being graciously awarded an Opentrons OT-2 automatic pipetting robot, we were eager to find other teams that we could share protocols and tips with. Speaking with iGEM Makerere, we both had a lot of questions surrounding wet lab protocols, dry lab modelling, and practical applications of our respective projects that could be answered by the other team’s diverse knowledge and unique experiences. For example, the Makerere team stated that a metabolic by-product of the degradation of plastics by microbes is ethylene glycol, however they couldn’t decide on a practical use for this by-product. As Canadians, we know ethylene glycol well, as it is the major component of antifreeze for windshield frost in the winter! We suggested that their by-product could be used in cryopreservatives here in Canada. Ultimately, through various Skype calls and email exchanges, members of both our teams were able to assist the other with different aspects of the projects. Our dry lab teams were able to collaborate with various 3D modelling techniques in PyMOL, as well as wiki formatting.
Internal Collaborations
Queen's Biomedical Innovation Team (QBiT)
The Queen’s Biomedical Innovation Team is an undergraduate student-run, interdisciplinary design team
that focuses on biomedical device design and innovation. This year QGEM has collaborated with QBiT in
the production of a pacifier devicer which will utilize our engineered protein construct for the
detection of salivary analytes. Features of the pacifier design include:
- A one-way valve nipple to passively collect saliva from the infants mouth, while preventing any backflow of the engineered protein from the internal components towards the infants mouth.
- A circuit board containing a photon-counter chip, a battery, and a Bluetooth Low Energy Beacon. These three components allow for the detection of bioluminesce produced by active luciferase, the transmission of this data over Bluetooth Low Energy to a smartphone device.
- A 3D printer polylactic acid polymer casing.
Queen's Reduced Gravity Experimental Design Team
The Queen’s Reduced Gravity Experimental Design Team is an undergraduate student-run team which will be
participating in an upcoming flight mission in collaboration with the National Research Council,
Canadian Space Agency, and Students for the Exploration and Development of Space in July. QRGX are
winners of the Canadian Reduced Gravity Experiment Design Challenge (http://seds.ca/projects) and have
been selected to conduct an experiment comparing DNA Polymerase I processivity and error rate in
microgravity vs normal gravity. This year QGEM will be accompanying them on their flight mission and
providing them with technical expertise and access to our laboratory equipment.