Genetic Enhancement Perspectives and Prospects for Grain Nutrients Density

Diet-induced micronutrient malnutrition continues to be a major challenge globally, especially in the developing world. With the ever-increasing population, it becomes a daunting task to feed millions of mouths with nutritious food. It is time to reorient agricultural systems to produce quality food to supply the calorie and nutrient requirements needed by the human body. Biofortification is the process of improving micronutrients density by genetic means. It is cheaper and sustainable and complements well with the nutrient supplementation and fortification— the short-term strategies that are currently deployed to address the micronutrient malnutrition. Sorghum is one of the important food crops globally, adapted to semi-arid tropics, and there is increased awareness on its nutritional importance. Further, there is great opportunity to improve sorghum for nutritional quality. This chapter deals about the genetic enhancement perspectives and prospects for improving the nutritional quality with main emphasis on grain micronutrient density in sorghum

Genomic Interventions for Biofortification of Food Crops

Micronutrient deficiencies are reported to affect more than two billion people worldwide. Importantly, people inhabiting rural and semi-urban areas are more vulnerable to these nutritional disorders. In view of the inadequacy of nutrition-specific approaches that rely on changing the food-consumption behaviour, nutrition-sensitive interventions like crop biofortification offer sustainable means to address the problem of malnutrition worldwide. Biofortification enhances nutrient density in crop plants during plant growth through genetic or agronomic practices. Traditional plant breeding techniques and genetic engineering approaches are key to crop biofortification. Here, we summarize recent advances in genomics that have contributed towards the progress of crop biofortification. Rapidly evolving technologies like high-density genotyping assays have accelerated harnessing gains associated with natural variation of mineral contents available in crop wild relatives and landraces. The genetic nature of the mineral composition is being resolved, thus furthering the understanding of trait architecture. Conventional QTL mapping techniques have made significant contribution towards this end. New molecular breeding techniques like genome-wide association study (GWAS) and genomic selection (GS) are opening new avenues for capturing the maximum variation for elemental content, majorly explained by small-effect QTL. The potential of GS in this respect is enhanced several fold with the increasing availability of rapid generation advancement systems and high-throughput elemental profiling platforms. Evidences from latest research involving cutting-edge omics techniques including metabolomics help better elucidate nutrient metabolism in plants. Increasing the efficiency of biofortification breeding could enhance the rate of delivery of nutritionally rich cultivars of food crops, which will be easily accessible to a larger segment of nutrient-deficient people in the most cost-efficient way