Microbiology and Biotechnology Research: An Overview Vol. 7

Wheat (Triticum aestivum L.) serves as a fundamental component of global food security; however, its production faces growing challenges due to frequent droughts intensified by climate change. The unpredictable rainfall, elevated temperatures, and heightened evapotranspiration have substantially undermined yield stability, jeopardising advancements in global food systems. Drought episodes have intensified worldwide due to climate variability, resulting in significant losses in wheat-producing areas. This review consolidates existing knowledge regarding traditional and trait-based methods for improving drought tolerance in wheat, emphasising physiological, morphological, and agronomic traits. The review also examines the intricacies of breeding for drought tolerance, emphasising challenges including genotype-by-environment interactions and the trade-offs between drought resistance and yield potential. Drought stress markedly diminishes wheat yield by adversely affecting plant height, tillering, spikelet count, and grain size, with the most pronounced losses observed during reproductive stages. Essential characteristics that enhance drought resilience encompass strong root architecture, a stay-green phenotype, osmotic adjustment, and increased water-use efficiency. Recent advancements in precision breeding, such as marker-assisted selection, genomic selection, and gene editing techniques like CRISPR/Cas9, are expediting the creation of drought-tolerant cultivars. Additionally, agronomic management practices are equally essential in mitigating drought effects. Integrated agronomic practices, climate-smart agriculture, and international collaborations are essential strategies for maintaining wheat productivity in water-limited environments. The review concludes that a multifaceted approach, integrating conventional breeding, biotechnological innovations, and adaptive management, is essential for ensuring yield stability and food security amid increasing climatic variability. Despite recent advances in scientific studies, numerous gaps persist in understanding genetic, physiological, and morphological determinants of drought tolerance that necessitate coordinated efforts from both scholars and policymakers to resolve.