As per recent publication in Nature‘s Scientific Reports, it has been highlighted that a transdisciplinary group of scientists has succeeded in increasing iron (Fe) and zinc (Zn) levels in rice through biofortification which is a breakthrough in the global fight against micronutrients deficiency or “hidden hunger.” Further, it has been revealed that according to the World Health Organization (WHO), Fe deficiency is the most pervasive form of malnutrition and a leading cause of anemia in women and children. Moreover, Zn deficiency also causes stunting and has serious consequences for health, particularly during childhood.
In this research project, the researchers, who represent institutions in the Philippines, Colombia, Indonesia, USA, Australia, and Japan, have found proof of concept in confined field trials for increasing Fe and Zn levels in rice without a yield penalty or a change in grain quality. This development is a result of research funded by HarvestPlus, could potentially help several nations to achieve the nutritional targets for Fe and Zn. Further, in this regard, Dr Howarth Bouis, HarvestPlus Director, described the significance of the research by way of its implication on global hunger and mitigating undernutrition. The research results, which have exceeded target levels of both Fe and Zn, speak of the immense potential of using transgenic techniques in pursuing biofortification to improve the nutritional value of food crops. This demonstrates how scientific innovations can expand the range of solutions in curbing the micronutrient deficiencies.
Furthermore, it has also been observed that the polished rice grains generally contain only about 2 micrograms of Fe and 16 micrograms of Zn per gram. With limited variation in grain Fe content across the rice gene pool, conventional breeding efforts have fallen short of reaching 13 micrograms of Fe and 28 micrograms of Zn per gram of polished rice to fulfill 30% of the estimated average requirement (EAR) in humans. The study found that the genetically engineered rice has significantly increasedlevels of Fe (up to 15 micrograms) and Zn (up to 45.7 micrograms) per gram of polished rice that human cells can potentially absorb.
According to the publication, the Scientists used genes nicotianamine synthase from rice and ferritin from soybean that together produce high-micronutrient grains. They introduced the genes to a rice variety, IR64, and bred these into other popular indica varieties, the world’s most widely grown type of rice from South and Southeast Asia where Fe and Zn deficiencies are prevalent. This significant increase in Fe and Zn levels was achieved through rigorous gene optimization, large-scale plant transformation and event selection at the confined facilities of the International Rice Research Institute (IRRI), as informed by Dr Inez Slamet-Loedin, Senior Scientist and Head of IRRI’s Genetic Transformation Laboratory. In addition, it was also narrated that they are now developing backup lines using rice and bean genes. However, yet more work needs to be done to facilitate varietal release and to allow future impact.