OVERVIEW
Optimizing Nutrient Absorption Through Anthelmintics
Mass-supplementation of Vitamin A to deficient regions have been ongoing for decades.However, even with biannual vitamin A supplementation for children and biofortified crops such as golden rice exist, intestinal parasites still play the villain in preventing the vitamin’s assimilation by perforating the intestines. Organizations such as the UN, WHO, and the Bill Gates Foundation couple biannual vitamin supplementation with deworming, but lack of clean water and proper footwear allow these parasites to return and thrive in the intestines. The Oviita system sustainably supplements the consumer with vitamin A and thymol, an anthelmintic agent which is proven to work against worms and their larvae. By doing so, the intestines can recover and maximize absorption of vitamin A in the body.
In order to provide a sustainable, community-based solution, we plan to genetically modify Rhodosporidium toruloides, an oleaginous yeast that naturally produces beta-carotene and lipids, to be more robust and resource-efficient. By modifying the yeast to produce cellulase, it can then use common agricultural waste products as an energy source for synthesizing its oil. It can then be eaten as a vitamin A supplement. The yeast strain, while naturally safe and non-pathogenic, will also be genetically modified to include a kill switch for bio-containment, and optimized for oil production.
UNDERSTANDING THE PROBLEM
Who we talked to
To understand the extent of the problem, we talked to people who work directly with the problem.
- Dr. Sanou Dia - Even with VA supplies, intestinal parasites are a big problem. Lack of footwear and clean water cause them to return, and hinder vitamin absorption.
- Dr. Paul E. Mains - There is merit to producing thymol as worms and intestinal parasites may also develop resistance to anthelmintic drugs.
- Lourlin Ugdimay - Something about nutrition deficiencies and how they are distributed, maybe even purga.
- Dr. John Gileard - Parasites are not only problematic in humans, but also livestock. It is important to address this because people from vulnerable areas rely on their livestock for food and income, and there are only 2 main anthelmintic drugs used in the industry, and snps can easily happen.
PART DESIGN
Thoughtful design of genetic constructs
In order to provide a sustainable, community-based solution, we plan to genetically modify Rhodosporidium toruloides, an oleaginous yeast that naturally produces beta-carotene and lipids, to be more robust and resource-efficient. By modifying the yeast to produce cellulase, it can then use common agricultural waste products as an energy source for synthesizing its oil. It can then be eaten as a vitamin A supplement. The yeast strain, while naturally safe and non-pathogenic, will also be genetically modified to include a kill switch for bio-containment, and optimized for oil production.
EXPERIMENTAL DESIGN
Thoughtful design of experiments
In order to provide a sustainable, community-based solution, we plan to genetically modify Rhodosporidium toruloides, an oleaginous yeast that naturally produces beta-carotene and lipids, to be more robust and resource-efficient. By modifying the yeast to produce cellulase, it can then use common agricultural waste products as an energy source for synthesizing its oil. It can then be eaten as a vitamin A supplement. The yeast strain, while naturally safe and non-pathogenic, will also be genetically modified to include a kill switch for bio-containment, and optimized for oil production.
Expected Results
For when we get back to the lab
In order to provide a sustainable, community-based solution, we plan to genetically modify Rhodosporidium toruloides, an oleaginous yeast that naturally produces beta-carotene and lipids, to be more robust and resource-efficient. By modifying the yeast to produce cellulase, it can then use common agricultural waste products as an energy source for synthesizing its oil. It can then be eaten as a vitamin A supplement. The yeast strain, while naturally safe and non-pathogenic, will also be genetically modified to include a kill switch for bio-containment, and optimized for oil production.
FUTURE DIRECTIONS
Next Steps
In order to provide a sustainable, community-based solution, we plan to genetically modify Rhodosporidium toruloides, an oleaginous yeast that naturally produces beta-carotene and lipids, to be more robust and resource-efficient. By modifying the yeast to produce cellulase, it can then use common agricultural waste products as an energy source for synthesizing its oil. It can then be eaten as a vitamin A supplement. The yeast strain, while naturally safe and non-pathogenic, will also be genetically modified to include a kill switch for bio-containment, and optimized for oil production.
References
Paper 1