Team:Minnesota/Templates

Mercury is a neurotoxic heavy metal with the ability to biomagnify, therefore it is a significant issue in public health and environmental studies worldwide. Its levels are continually on the rise due to copper, nickel, and gold mining activities, the industrial use of mercury catalysts, mercurial fungicides in agriculture, and the burning of fossil fuels. This has resulted in the pollution of many marine ecosystems and water reservoirs worldwide, the cleanup of which using current technology, is either not feasible or incredibly costly. This study describes the use of engineered recombinant bacteria to facilitate the biological remediation of the neurotoxin methylmercury and hazardous mercury ions from an aquatic target site into less toxic form. This synthetic microbe was incorporated in novel encapsulation technology within a cost-effective, scalable water filtering column. The employment of this device could rigorously change the practices used in mercury decontamination efforts as well as pave the way for the switch to biological rather than chemical processes. Furthermore, this technology can be applied towards bioremediation and biosensing of various other heavy metals and organic toxins in the environment.

Mercury is a neurotoxic heavy metal with the ability to biomagnify, therefore it is a significant issue in public health and environmental studies worldwide. Its levels are continually on the rise due to copper, nickel, and gold mining activities, the industrial use of mercury catalysts, mercurial fungicides in agriculture, and the burning of fossil fuels. This has resulted in the pollution of many marine ecosystems and water reservoirs worldwide, the cleanup of which using current technology, is either not feasible or incredibly costly. This study describes the use of engineered recombinant bacteria to facilitate the biological remediation of the neurotoxin methylmercury and hazardous mercury ions from an aquatic target site into less toxic form. This synthetic microbe was incorporated in novel encapsulation technology within a cost-effective, scalable water filtering column. The employment of this device could rigorously change the practices used in mercury decontamination efforts as well as pave the way for the switch to biological rather than chemical processes. Furthermore, this technology can be applied towards bioremediation and biosensing of various other heavy metals and organic toxins in the environment.

Mercury is a neurotoxic heavy metal with the ability to biomagnify, therefore it is a significant issue in public health and environmental studies worldwide. Its levels are continually on the rise due to copper, nickel, and gold mining activities, the industrial use of mercury catalysts, mercurial fungicides in agriculture, and the burning of fossil fuels. This has resulted in the pollution of many marine ecosystems and water reservoirs worldwide, the cleanup of which using current technology, is either not feasible or incredibly costly. This study describes the use of engineered recombinant bacteria to facilitate the biological remediation of the neurotoxin methylmercury and hazardous mercury ions from an aquatic target site into less toxic form. This synthetic microbe was incorporated in novel encapsulation technology within a cost-effective, scalable water filtering column. The employment of this device could rigorously change the practices used in mercury decontamination efforts as well as pave the way for the switch to biological rather than chemical processes. Furthermore, this technology can be applied towards bioremediation and biosensing of various other heavy metals and organic toxins in the environment.

Mercury is a neurotoxic heavy metal with the ability to biomagnify, therefore it is a significant issue in public health and environmental studies worldwide. Its levels are continually on the rise due to copper, nickel, and gold mining activities, the industrial use of mercury catalysts, mercurial fungicides in agriculture, and the burning of fossil fuels. This has resulted in the pollution of many marine ecosystems and water reservoirs worldwide, the cleanup of which using current technology, is either not feasible or incredibly costly. This study describes the use of engineered recombinant bacteria to facilitate the biological remediation of the neurotoxin methylmercury and hazardous mercury ions from an aquatic target site into less toxic form. This synthetic microbe was incorporated in novel encapsulation technology within a cost-effective, scalable water filtering column. The employment of this device could rigorously change the practices used in mercury decontamination efforts as well as pave the way for the switch to biological rather than chemical processes. Furthermore, this technology can be applied towards bioremediation and biosensing of various other heavy metals and organic toxins in the environment.

Mathematical Modeling

Mathematical Modeling

Mathematical Modeling

Dry Lab

Wet Lab

Biobrick Assembly

phsABC

Biobrick Assembly

Biosafety

Results Hg2

Results MethyllHg

Results phsABC

Policies & Practices

Our Policies & Practices team had a holistic approach to addressing the public health concern of methylmercury contamination as it relates to the implementation of our device. Our team actively attempted to address problems associated with the application of our project and device. From early education and societal perception to small-business design and device implementation, UMN iGEM sought new ways to address our project from varying perspectives to better inform the design and launch of our project. To explore some highlights of our policies and practices team, please click on the icons above.

Educational Outreach

Building on past successes, our team was devoted to volunteering our services to the community in a number of educational venues. The team took our curriculum, first developed in 2013, and improved the structure and delivery of our lesson plans in hopes to encourage awareness and education on topics in synthetic biology. Since its inception, our educational outreach group ECORI (Educating Communities On Research Innovation) has taught our original, interactive curriculum to over 200 students (K-12) and their teachers. We also created an exhibit-form of our curriculum and layman’s introduction of our project that we displayed over ?? weekends to visitors and their families of all ages at the Science Museum of Minnesota, to employees and their families at 3M where we received feedback and advice on our filter; and has been represented at several STEM fairs within the metropolitan community (Biodiversity Fair, Family Fun Fair, Association of multicultural students, CSE. To top it off, the team designed a Synthetic Biology Game Show that was presented on stage with 30 participants at the Minnesota State Fair to assess the general public’s knowledge of the subject and teach hundreds of passers-by in a way that was both engaging and interactive. Winners were rewarded with sustainable reusable bags, magnets, and gift cards donated by our sponsors. In the spirit of science, our curriculum has been ever evolving to constantly address salient topics and educational materials and is flexible in nature to be taught in a variety of settings.

Public Perception

our team sought to inform the majority stakeholders in our community concerning the scope of our project. This year, our team chose to have an exhibit catered towards adult residents at the Minnesota State Fair (the largest MN gathering with over 1.8 million visitors annually) to learn the ways we can best design our technology to meet the needs and concerns of the people whose waters we hope to help remediate.. We delivered a short synopsis of our device, the synthetic biology involved, and safety precautions we have insured. We then presented visitors with a five question survey (Likert Scale) to gauge public perception of both our device, and the synthetic biology methods used. The survey was a huge success with over 320 participants. The survey delivery captured a great cross-section of the MN community that would be most impacted by the implementation of our device. The results of our survey, illustrated below, informed how and where the public would be most comfortable with implementing our device, and illustrated the need for catered education addressing the public’s major concerns prior to applying our device in the environment. Our model for gauging public perception allowed for a wide, diverse crowd to be accessed. This model can be used upon request.

Intellectual Property

Documentary

The University of Minnesota 2014 iGEM team proudly presents our documentary film discussing the background of our project and the bioethics relating to our device. The main purposes of this documentary film are to familiarize the audience with the global mercury contamination problem, to discuss the bioethical questions of synthetic biology and biotechnological products, and to evaluate the bioethical concerns of our device implementation. To address the above missions, we have conducted interview with specialists from environmental toxicology, biotechnology, and philosophy at the University of Minnesota. We explore the past incident of methylmercury contamination in Minamata, Japan, as well as the ongoing methylmercury contamination in the state of Minnesota. Through our collaboration with the 2014 Colombia iGEM Team, we further examine the current methylmercury contamination in Colombia because of illegal and informal gold mining using mercury as a reagent. While GMOs are prevalent in today’s society in forms of food, products, and biotechnology, the public perception of GMOs still diverges. We pace through many different discussions in our video, including why GMOs are perceived differently in the public, why research on the effect of GMOs is usually time- and fund-intensive, and how policy-making corresponds with scientific findings to ensure the biosafety of GMOs. So is it safe to implement our device that contains GMOs into the local, polluted water? How do we assess the benefits of implementing our device and how do we know if the benefits out-weight the potential risk of introducing a biohazard into the local water stream? What kinds of precautions should we bear in mind when designing the device? While our documentary addresses all these issues, what is even more thought-provoking is the question of can we reduce the usage of GMOs for bioremediation by reducing the production of pollution? Please sit back and enjoy as the University of Minnesota 2014 iGEM Team presents our full thought processes regarding the above matters in a documentary film.

Safety in the Lab

1. Your Training a) Safety trainings DEHS Introduction: Research Safety DEHS Chemical Safety DEHS Waste Management

Safety in the Lab

2. Our Local Rules and Regulations Who is responsible for biological safety at our institution? The project was discussed with the Department of Environmental Health and Safety at our university, and a plan was devised for mercury waste disposal based on their input. General biosafety guidelines found at https://www.dehs.umn.edu/bio.htm, http://www.dehs.umn.edu/bio_pracprin.htm and http://www.cdc.gov/biosafety/publications/bmbl5/bmbl.pdf were followed.

Safety in the Lab

3. Risks of Your Project Now To mitigate risks to the safety and health of team members, or other people working in the lab: Gloves are used in any protocol that utilizes Ethidium Bromide, including gel electrophoresis. Lab coat, gloves, and full face shields are used when cutting gel fragments in proximity of ultraviolet light. For handling mercury, a lab coat, inner and outer (long cuffed) nitrile gloves, lab goggles and face shields will be used, and used materials will be disposed of by the University of Minnesota Department of Environmental Health and Safety. There are assigned incubators, hoods, and disposal containers for hazardous materials like mercury chloride. Design features to minimize risk kill switch proposal that would not allow the bacteria to survive outside of the encapsulation or even device holding the cells Air tight? non pathogenic lab strains