Conventional and molecular breeding strategies for improvement of drought tolerance cultivars in rice: Recent approaches and outlooks

Madhu Banoth, Umil Singh Nunavath, Sukrutha Bhimireddy, Deepika Konne, Ananda Lekshmi L, Venkateswarao Govada, Sampath Lavudya
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Abstract

Rice is a vital staple food, especially in Asia, but it is highly susceptible to drought, leading to significant yield losses. To ensure food sustainability, drought-tolerant rice varieties are essential. Conventional breeding methods improve drought tolerance by focusing on biometric traits like root depth, avoidance, escape, and tolerance. This involves screening and crossing drought-tolerant varieties with high-yielding ones, followed by selection and evaluation. Techniques such as pedigree selection, recurrent selection, and backcrossing introduce desirable genes to enhance drought tolerance. Induced mutation through radiation exposure is also used. The molecular basis of drought tolerance involves identifying and manipulating genes responsible for rice's response to water stress. Techniques like QTL analysis, transcriptomics, genomics, and proteomics identify genes and QTLs associated with drought tolerance. Important genes involved in drought response include DREB, LEA, and ROS scavenging genes. Identifying QTLs enables the development of molecular markers for efficient screening of drought-tolerant rice genotypes. In conclusion, conventional breeding and molecular approaches are employed to develop drought-tolerant rice varieties. Conventional breeding improves biometric traits, while molecular techniques identify and manipulate specific genes associated with drought tolerance. This combination holds promise for high-yielding and drought-tolerant rice cultivars, contributing to global food security. However, further research is needed to understand the complex genetic mechanisms underlying drought tolerance in rice and enhance breeding precision and efficiency.
改良水稻耐旱栽培品种的常规和分子育种策略:最新方法与展望
水稻是一种重要的主食,尤其是在亚洲,但它极易受到干旱的影响,导致严重减产。为确保粮食的可持续性,耐旱水稻品种至关重要。传统的育种方法通过关注根深、避旱、逃旱和耐旱等生物特征来提高耐旱性。这包括筛选耐旱品种并与高产品种杂交,然后进行筛选和评估。血统选择、循环选择和回交等技术可引入理想基因以提高耐旱性。通过辐射照射诱导突变的方法也被采用。耐旱性的分子基础包括鉴定和操纵负责水稻对水分胁迫反应的基因。QTL 分析、转录组学、基因组学和蛋白质组学等技术可确定与耐旱性相关的基因和 QTL。参与干旱响应的重要基因包括 DREB、LEA 和清除 ROS 基因。鉴定 QTLs 可以开发分子标记,从而有效筛选耐旱水稻基因型。总之,传统育种和分子方法被用于培育耐旱水稻品种。常规育种可改善生物计量性状,而分子技术则可识别和操纵与耐旱性相关的特定基因。这种组合有望培育出高产耐旱的水稻品种,为全球粮食安全做出贡献。然而,要了解水稻耐旱性背后复杂的遗传机制,提高育种的精度和效率,还需要进一步的研究。
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