Speed Breeding for the Development of Salt-Tolerant and Early-Maturing Basmati Rice Genotypes via CRISPR/Cas9-Mediated Genome Editing of Stress-Responsive Regulators
DOI:
https://doi.org/10.63163/jpehss.v4i1.1241Abstract
Basmati rice, a premium aromatic variety central to the export economies of India and Pakistan (valued at US$14.17 billion and US$3.96 billion in 2024, respectively), faces severe productivity threats from soil salinity, which affects 20% of irrigated lands globally and causes annual losses of US$27.2 billion. Traditional breeding's slow cycles (6–10 years) hinder rapid adaptation, necessitating innovative approaches. This review explores the integration of CRISPR/Cas9-mediated genome editing targeting stress-responsive transcription factors (e.g., NAC, MYB, WRKY families) and negative regulators (e.g., OsARR1, OsARM1) to enhance ion homeostasis, osmotic adjustment, and early maturity with speed breeding (SB) protocols that compress generation times to 4–6 cycles per year via extended photoperiods (22h light/2h dark) and controlled environments. Case studies demonstrate successful introgression of Saltol QTL and editing of OsBADH2 for aroma retention, yielding salt-tolerant lines with EC thresholds up to 8–12 dS/m and 10–15% earlier maturity. Socio-economic analyses highlight potential yield gains of 20–30% in salinized regions, while regulatory frameworks in South Asia emphasize biosafety. This synergistic strategy accelerates climate-resilient Basmati development, ensuring food security and economic stability amid escalating environmental pressures.
