Enhancing tiny millets through genome editing: current status and future prospects.

Abstract

This study aims to address the critical need for genetic improvement of small millets, which are vital yet underutilized cereal crops cultivated in semi-arid regions of Africa and Asia. Given their high nutritional value and climate resilience, small millets hold significant potential for food security and sustainable agriculture in arid regions. However, traditional breeding methods have proven to be time-consuming and inefficient in enhancing desirable traits. This study highlights the transformative potential of genome editing technologies, particularly the CRISPR/Cas9 system, in accelerating the development of improved small millet varieties. The findings presented in this paper detail recent advancements in using CRISPR/Cas for enhancing resistance to biotic stresses, including bacterial, viral, and fungal pathogens. Additionally, we explore how genome editing can be applied to improve abiotic stress tolerance, addressing challenges such as drought, cold, heat, and herbicides in small millets. We discuss the existing challenges faced by breeders, including issues related to ploidy levels, off-target effects, and limitations in organelle genome modification. The review also suggests potential strategies for overcoming these bottlenecks, aiming to develop stress-resistant super cultivars. Overall, this paper provides an overview of the current state of genome editing research in small millets while identifying future opportunities to enhance key traits for nutrient enrichment and climate resilience, ultimately paving the way for advancements in these crucial crops.