计算生物学
生物
RNA剪接
选择性拼接
转录组
非生物胁迫
生物技术
系统生物学
转化式学习
基因组工程
基因组编辑
非生物成分
基因
农业
遗传学
生物信息学
基因组学
生物逆境
RNA序列
功能多样性
核糖核酸
拟南芥
功能基因组学
计算机科学
基因组
战斗或逃跑反应
作者
Zhi-Yao Wang,Wei Zhang,N. Zhang,Pei-Min Wu,Qihang Su,Chuang Ma,Wei Wang,Min Chen
摘要
Alternative splicing (AS) represents a pivotal post-transcriptional regulatory mechanism, profoundly expanding proteomic diversity and functional complexity by enabling single genes to generate multiple mRNA isoforms. In plants, AS serves as a survival toolkit, dynamically modulating stress-responsive signaling pathways, transcriptional networks, and protein functional specialization to optimize environmental fitness. Recent advances in high-throughput sequencing technologies and computational tools have significantly deepened our understanding of AS regulation in plants. Notably, breakthroughs such as long-read transcriptome sequencing and single-cell RNA analysis have revolutionized the resolution at which we can characterize AS landscapes. These developments have collectively illuminated the critical role of AS in mediating plant responses to diverse abiotic stresses, including drought, salinity, and extreme temperatures. The resulting discoveries have opened transformative avenues for crop improvement through precision manipulation of splicing patterns. Innovative strategies such as CRISPR-Cas9-based splice editing and engineered SFs now provide powerful platforms for developing climate-resilient, high-yielding crop varieties with enhanced stress tolerance and nutritional quality. This review systematically examines the molecular mechanisms underlying AS-mediated plant stress responses, and cutting-edge applications of AS engineering in precision agriculture. By synthesizing fundamental insights with biotechnological innovations, we highlight the transformative potential of AS manipulation in addressing the pressing global agricultural challenges.
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