Archives for August 2018

New applied genomics projects to spur innovative technologies and job creation in agri-food, health and the environment

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August 16, 2018, Lincoln, Ontario – The application of genomics-based research and development is strengthening Ontario’s economy. It is leading to much needed advancements in farming practices, health care, and environmental stewardship. Bringing together academic researchers with companies to accelerate technology development lays the foundation for increased competitiveness, economic growth and job creation.

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Today, the Minister of Science and Minister of Sport and Persons with Disabilities, the Honourable Kirsty Duncan, announced federal funding for seven new projects under Genome Canada’s Genomic Applications Partnership Program (GAPP).  Three of these projects are based in Ontario – driving $2.9 million of federal funding into the province, and an additional $5.9 million in investments by industry, the Ontario government and other funding partners, for a total of $8.8 million to support the application of genomics innovations in Ontario.  These projects are designed for significant economic and social impacts in the near-term, spurring innovation and commercialization and creating jobs in Ontario.

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The Minister made the announcement at Vineland Research and Innovation Centre. Vineland is partnering with a team of University of Toronto researchers to develop genomics-based technologies that will induce broad-spectrum disease resistance in greenhouse vegetables, allowing new varieties of vegetables to thrive and reducing waste. This will give growers across Ontario and Canada a competitive advantage in a national industry that already generates more than $1 billion annually from retail sales and exports.

In another GAPP project, researchers at McMaster University are partnered with Hamilton-based start-up Adapsyn Bioscience Inc. to use its proprietary technology platform that combines genomic and metabolomic data with artificial intelligence and machine learning to redefine and accelerate drug discovery for novel treatments of a wide spectrum of diseases.  This partnership secured significant foreign and domestic investment and is creating new high-tech jobs in Ontario.

The third Ontario-based GAPP project announced today brings together researchers at the Sunnybrook Research Institute and University of Toronto with Canadian start-up Fusion Genomics to further develop novel infectious disease surveillance tools. Their technology is unique in its ability to detect and genetically characterize infectious viral pathogens through bioaerosols to serve as early warning for disease outbreaks in both humans and agricultural animals. The development of this pre-emergence environmental detection technology will drive a paradigm shift in public health and animal welfare by offering complete genomic data to anticipate outbreaks, inform disease transmission dynamics and enable vaccine design and production.

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Quick facts

  • GAPP is a program that partners researchers with companies and other end-users who will apply their innovations with the goal of increasing and accelerating the positive social and economic impact of Ontario’s and Canada’s genomics R&D capacity.
  • Genome Canada launched GAPP in 2013. To date, approximately $86.1 million, including co-funding has been invested in 23 Ontario-based GAPP projects, fuelling innovations, spurring job creation and attracting foreign investment in Ontario’s health, agriculture & agri-food, fisheries, environment and natural resource sectors.
  • A Genome Canada partnership with Mitacs provides placements and funding for graduate students and post-doctoral fellows to work on GAPP projects within industry partners’ operations. Three post-doctoral fellows will be working with the Ontario-based McMaster/Adapsyn team. The partnership prepares Canada’s next generation of innovators to advance the field of genomics by allowing candidates to apply their knowledge and skills in a real-world setting. Companies, meanwhile, benefit from the high-quality research expertise.

Quote

“Through these collaborative investments, we are enabling the development of real-world genomics-based solutions that will positively impact the health and well-being of Ontarians, the strength of our province, and the growth of our economy.”
– Dr. Bettina Hamelin, President and CEO, Ontario Genomics

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Cracking the code

As published on the July/August 2018 Water Canada Magazine
By Britney Hess

Ontario unlocks genomic information to propel the circular economy.

News_20180808_01Understanding the genomics of our biological planet is key to addressing the grand challenges facing our world today, from climate change and global population growth to increasing food and energy demands, health issues, and protection of our natural resources.
Every living organism has DNA—a code that directs its biological functions and influences how it grows and interacts with the environment. Genomics is the science of understanding, interpreting, and harnessing this genetic code. In addition to innovations in healthcare, agriculture, and advanced manufacturing, the insights gleaned from genomics are resulting in the creation of environmentally-friendly solutions that are allowing us to improve the water we drink, the air we breathe, and the way we extract minerals and energy from the earth.
Ontario Genomics is a not-for-profit organization focused entirely on stimulating, enabling, and nurturing genomics innovations across all sectors of the bio-economy. Connecting scientists, ideas, and partner organizations from across the province and around the world, Ontario Genomics works with project teams to develop plans and secure funding to enable the development and application of solutions for our circular economy. Several of these projects are developing innovative genomics-based techniques for water monitoring, treatment, and re-use—three of which are highlighted here.

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Harmful algal blooms (HABs) are a major environmental problem and a growing concern in Canadian waters. Harmful bloom events are caused by cyanobacteria, which has negative impacts on other organisms through production of toxins and oxygen deprivation and severe impacts on human health, aquatic ecosystems, and the economy. Climate change, nutrient imbalances from phosphorus, and warming water temperatures provide optimal conditions for growth of harmful bacteria.
Environmental Bio-Detection Products Inc. (EBPI) is an Ontariobased biotechnology company working with researchers at the University of Guelph and the University of Waterloo to develop a rapid on-site detection platform for water contaminants produced by bacteria found in HABs. The most prevalent of these toxins is Microcystin-LR (MC-LR). The team developed a portable hand-held detector that employs DNA aptamers, which are short DNA strands, to detect and signal the presence of MC-LR contaminants in real-time with sufficient sensitivity to meet World Health Organization drinking water guidelines. The platform has also shown promise for detection of other small molecule contaminants in water samples.

Responsible solutions for wastewater treatment


With recurring droughts and increasing water shortages, wastewater is becoming an ever-more valuable resource. The main objectives of wastewater treatment are to protect the planet from harmful toxins and to restore our water supply.
Based in Renfrew, Ontario, Bishop Water Technologies (BWT) has partnered with Dr. Chris Weisener at the University of Windsor to understand and improve their environmentally-friendly treatment solution for wastewater. By characterizing the microbial ecosystem through genomic sampling, the team is working together to identify and quantify the microbes and to determine their activities in relation to nutrient removal from wastewater. BWT manufactures a novel microbe-based solution called BioCord which is a man-made, inert, polymer scaffold. It provides more surface area for nutrient cycling biofilm to develop, enabling the removal of nitrates and phosphates from wastewater, and reducing point source nutrient loads to the Great Lakes at a fraction of the cost and without any chemicals.

Reducing sulphur contamination in mining wastewaters


Sulfur-contaminated wastewater is a large global mining-related environmental liability. Bacteria drive the key sulfur compound transformations responsible for water contamination, however little is known about how these bacteria affect the sulfur geochemistry in mining wastewater impoundments.
Consequently, these impoundments are viewed as a “black box.” With mines in every province and territory, and as pressures on Canada’s freshwater water supplies grow, there is an urgent need to gain greater understanding and develop sustainable approaches to the treatment of mining wastewaters.
An international team led by Dr. Lesley Warren at the University of Toronto and Dr. Jillian Banfield at the University of California, Berkeley is working to apply genomics, geochemistry, and modelling to mining wastewaters with the objective of developing innovative biological monitoring, management, and treatment tools for sulphur compounds in their wastewaters, as well as support science-informed, cost-benefit decision-making for the mining sector. This project, the first of its kind in Canada and possibly the world, involves three mining and two environmental consulting companies, as well as provincial and national sector industry associations and government.

Genomics is the most transformative technology of the 21st century. Recent advancements are accelerating our knowledge and the opportunity to develop sustainable solutions to protect and treat our waters, as well as innovative applications across all sectors of our bioeconomy to help move Canada towards a circular economy.