Brown planthopper(BPH)is a highly destructive pest that presents a significant challenge to rice production,particularly in the Asia-Pacific region.Numerous BPH-resistant rice varieties have been successfully bred and...Brown planthopper(BPH)is a highly destructive pest that presents a significant challenge to rice production,particularly in the Asia-Pacific region.Numerous BPH-resistant rice varieties have been successfully bred and released for commercial cultivation across diverse rice-growing ecosystems.However,resistance breakdown in several varieties carrying major resistance genes has been reported,highlighting the urgent need for the development of novel,genetically diverse,and broad-spectrum resistant varieties.To date,more than 45 resistance loci have been identified and mapped from both cultivated and wild rice species.Among these,a subset of genes(including Bph1,Bph3,Bph6,Bph7,Bph9,Bph10,Bph14,Bph15,Bph18,Bph21,Bph26/2,bph29,Bph32,Bph37,and Bph30/Bph40)have been positionally cloned.Most of these genes encode coiled-coil nucleotide-binding leucine-rich repeat proteins,which are central to plant immune responses,along with a few signaling molecules playing pivotal roles.In addition to these core resistance genes,various other genetic components,including miRNAs,protein kinases,and transcription factors,have been functionally characterized for their roles in mediating BPH resistance.The advent of post-genomic tools such as RNA sequencing and single-cell sequencing,along with cutting-edge genomic technologies like CRISPR/Cas gene editing,has significantly accelerated resistance breeding programs.In this context,we provide an overview of genetics,mapping,isolation,and functional characterization of BPH resistance,along with strategies for incorporating resistance using advanced genomics-assisted breeding tools.Furthermore,we present a snapshot of how the integration of genomics and novel breeding technologies holds great promise for dissecting the genetic architecture of pest resistance and accelerating crop improvement.展开更多
The sustainability of rice production continues to be a subject of uncertainty and inquiry attributed to shifts in climatic conditions. In light of the impending climate change crisis and the high labor and water cost...The sustainability of rice production continues to be a subject of uncertainty and inquiry attributed to shifts in climatic conditions. In light of the impending climate change crisis and the high labor and water costs accompanying it, direct-seeded rice(DSR) is unquestionably one of the most practical solutions. Despite its resource and climate-friendly advantages, early maturing rice faces weed competitiveness and seedling establishment challenges. Resolving these issues is crucial for promoting its wider adoption among farmers, presenting it as a more effective sustainable rice cultivation method globally. Diverse traditional and contemporary breeding methods are employed to mitigate the limitations of the DSR approach, leveraging advanced techniques such as speed breeding and genome editing. Focusing on key traits like mesocotyl length elongation, early seedling vigor, root system architecture, and weed competitiveness holds promise for transformative improvements in DSR adaptation at a broader scale within farming communities. This review aims to summarize how these features contribute to increased crop production in DSR conditions and explore the research efforts focusing on enhancing DSR adaptation through these traits. Emphasizing the pivotal role of these game-changing traits in DSR adaptation, our analysis sheds light on their potential transformative impact and offers valuable insights for advancing DSR practices.展开更多
文摘Brown planthopper(BPH)is a highly destructive pest that presents a significant challenge to rice production,particularly in the Asia-Pacific region.Numerous BPH-resistant rice varieties have been successfully bred and released for commercial cultivation across diverse rice-growing ecosystems.However,resistance breakdown in several varieties carrying major resistance genes has been reported,highlighting the urgent need for the development of novel,genetically diverse,and broad-spectrum resistant varieties.To date,more than 45 resistance loci have been identified and mapped from both cultivated and wild rice species.Among these,a subset of genes(including Bph1,Bph3,Bph6,Bph7,Bph9,Bph10,Bph14,Bph15,Bph18,Bph21,Bph26/2,bph29,Bph32,Bph37,and Bph30/Bph40)have been positionally cloned.Most of these genes encode coiled-coil nucleotide-binding leucine-rich repeat proteins,which are central to plant immune responses,along with a few signaling molecules playing pivotal roles.In addition to these core resistance genes,various other genetic components,including miRNAs,protein kinases,and transcription factors,have been functionally characterized for their roles in mediating BPH resistance.The advent of post-genomic tools such as RNA sequencing and single-cell sequencing,along with cutting-edge genomic technologies like CRISPR/Cas gene editing,has significantly accelerated resistance breeding programs.In this context,we provide an overview of genetics,mapping,isolation,and functional characterization of BPH resistance,along with strategies for incorporating resistance using advanced genomics-assisted breeding tools.Furthermore,we present a snapshot of how the integration of genomics and novel breeding technologies holds great promise for dissecting the genetic architecture of pest resistance and accelerating crop improvement.
基金supported by the Indian Council of Agricultural Research-International Rice Research Institute Collaborative Project, India (Grant No. OXX4928)。
文摘The sustainability of rice production continues to be a subject of uncertainty and inquiry attributed to shifts in climatic conditions. In light of the impending climate change crisis and the high labor and water costs accompanying it, direct-seeded rice(DSR) is unquestionably one of the most practical solutions. Despite its resource and climate-friendly advantages, early maturing rice faces weed competitiveness and seedling establishment challenges. Resolving these issues is crucial for promoting its wider adoption among farmers, presenting it as a more effective sustainable rice cultivation method globally. Diverse traditional and contemporary breeding methods are employed to mitigate the limitations of the DSR approach, leveraging advanced techniques such as speed breeding and genome editing. Focusing on key traits like mesocotyl length elongation, early seedling vigor, root system architecture, and weed competitiveness holds promise for transformative improvements in DSR adaptation at a broader scale within farming communities. This review aims to summarize how these features contribute to increased crop production in DSR conditions and explore the research efforts focusing on enhancing DSR adaptation through these traits. Emphasizing the pivotal role of these game-changing traits in DSR adaptation, our analysis sheds light on their potential transformative impact and offers valuable insights for advancing DSR practices.
