Abstract
Barley (Hordeum vulgare L.) plays a crucial role in global agriculture and food security, being the fourth most important cereal worldwide. Despite its significance, barley production faces threats, particularly from rust diseases, which can cause substantial yield losses, reaching 50-70% in susceptible varieties during epidemics. Additionally, changing climate patterns, including temperature fluctuations and unseasonal rainfall, contribute to the evolution of more virulent rust pathotypes, negatively impacting barley production. In response to these challenges, the development and deployment of rust-resistant barley cultivars have become imperative. The quest for rust resistance in barley has been a dynamic research area, initially relying on conventional breeding methods focused on phenotypic performance. Over time, various breeding methods such as pedigree breeding, backcrossing, single seed descent, recurrent selection, and doubled haploidy have been employed. However, the advent of molecular technologies has revolutionized the field, providing new avenues for discovering rust-resistant genes and developing improved barley varieties. Techniques like marker-assisted selection, quantitative trait loci (QTL) identification, cloning, etc. opened new avenues for discovering rust-resistant genes and developing improved barley varieties. These molecular approaches provide more precise and efficient means for identifying and introducing desirable traits. This review aims to provide a comprehensive understanding of these advanced breeding strategies, offering insights that can contribute for effective management of barley leaf rust management and ensure the sustained success of barley production in the face of evolving challenges.