Team:Calgary Ethics/Collaboration
From 2008.igem.org
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Collaborating with the Guelph iGEM team 2008
Part 1
Introduction
Micronutrient deficiency is a major cause of life threatening diseases and mortality through-out the world (1; 2). The UN World Summit on Children Micronutrient goal was:"Achieve sustainable elimination of iodine deficiency disorders by 2005 and vitamin A deficiency by 2010 (3). In poor, developing countries, micronutrient deficiency has been the major cause of impaired mental and physical functioning, mainly among children (1; 2). The four major micronutrients of concern in the developing world are iron, vitamin A, zinc and iodine(2). Our focus will be on Vitamin A deficiency. Roughly 400 million people worldwide are at risk of vitamin A deficiency. Of those 400 million affected, 100-200 million are children (1; 4). It can lead to progressive damage to the eye and eventually causes blindness. The WHO reports that 2/3 of deficient children die within two months of becoming blind(4).
Vitamin A deficiency is most prevalent among children located in Southeast Asia and Africa(5; 6), where staple foods are low in vitamin A (i.e. wheat, rice, maize…etc) and the poor cannot afford foods that would fulfill their Vitamin A requirements . Mammals must ingest provitamin-A Carotenoids from dark green vegetables, or yellow or orange fruits(7) and vegetables or fat soluble Vitamin A from animal products like eggs, butter and fish liver oils in order to synthesize Vitamin A in the body. Vitamin A is essential for protein metabolism, maintenance of epithelial cells, proper functioning of the immune system and retina, and for growth and reproduction (8). In order to reduce Vitamin A deficiency in developing countries, Beta-Carotene, the pro-vitamin A precursor, or Retinol, the animal version of Vitamin A, must be provided by some means to those who are deficient. There are currently 3 delivery systems for combating micronutrient deficiency; supplementation, increasing or diversifying dietary in-take and food fortification, which includes commercial or industrial fortification, as well as biofortification, microbial biofortification and home fortification(1; 9; 10). There is also a fourth and more recent delivery system, which can be labeled the synthetic biology approach (the approach the Guelph iGEM team takes). This paper will explore and highlight the major E3LS implications of the current and possible future delivery systems, for Beta-Carotene, a Provitamin A carotenoid. The goal of addressing the E3LS implications is to help advance towards realistic applications. These implications must be considered and weighed in an effort to make the best choices for fighting deficiencies all over the world.
Part 2
Overview of the different approaches
Food fortification (11) is a food based strategy and includes commerical and industrial fortification, home fortification, biofortification and if implemented crops or animals; microbial biofortification and synthetic biology. In this context, fortification in general means to improve or strengthen the levels of nutrients in a target product. The several types of food fortification are distinct because different techniques and procedures are used to fortify the target foods.
Biofortification involves creating micronutrient-dense staple crops using traditional breeding techniques(7) and/or biotechnology. Cross breeding has been around for decades and has been used to fortify numerous crops. Using biotechnology to biofortify staple crops is more modern. The most popular example of this approach is the transgenic 'Golden Rice'(12; 13), which has been fortified with Beta-Carotene with the purpose to try to improve Vitamin A levels in people with deficiencies.
Microbial Biofortification involves using probiotic bacteria, which ferment to produce Beta-carotene, in the foods we eat or directly in the human intestine. The probiotic bacteria that are often selected for addition to food are lactic acid bacteria (LAB) because they are presumed to have beneficial effects on the host(14). An example of this would be mixing lactic acid bacteria (LAB) with animal feed so that animal meats and bi-products such as milk are enriched in Vitamin A.
Commercial and Industrial fortification This approach involves fortifying commercially available products such as flour, cooking oils and butter with Beta-carotene or Retinol. This fortification process occurs during manufacturing.
Home Fortification This approach consists of supplying deficient populations with home mixed vitamins and minerals in packages or tablets that can be added when cooking meals. This approach is basically a merger of supplements and fortification.
Supplementation This has been the most widely used approach so far in fighting Vitamin A deficiency. There have been many successful campaigns using supplementation. Vitamin A supplements come in the form of tablets, syrup and capsules and can be provided in biannual large doses (micronutriets: dietary intake V supplement use). In most campaigns, the supplements have been handed out during national immunization days, like those dedicated to polio. However, National Micronutrient Days (NMDs), like those started in Africa in 1999, are becoming a more popular way to ensure supplements are received biannually(15).
Increasing and diversifying dietary intake This approach involves creating larger and more diverse diets for the target population. This may require the population to increase their production of food which may be paired with educational campaigns to provide the information about which foods promote higher levels of vitamin A in the body. Another possibility is increasing the distribution of food to the region from another area.
Synthetic Biology Approach
Although techniques of synthetic biology are used in aspects of biofortification and microbial fortification, it is also an individual approach. This approach involves engineering a synthetic operon of beta-carotene metabolic genes in a plasmid, which may then be transferred to a diverse set of bacterial hosts. The biofortified probiotic hosts may be implemented in many ways to produce Beta-Carotene for humans. The probiotics may be place directly in the human intestine or they may be associated with our foods. One possibility may be mixing the probiotics with animal feed so that animal meats and animal bi-products are enriched with vitamin A. (Guelph iGEM team)
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2) Collaboration with the Calgary Wetlab iGEM team 2008
We provide also E3LS feedback to the wetlab team from Calgary.
3) Collaboration with a presenter at Synbio 4.0 where we provide feedback on synbio regulation ideas.