渗入
生物
混合的
抗性(生态学)
植物抗病性
林木育种
基因分型
植物遗传学
接种
生物技术
微卫星
等位基因
高电阻
枯萎病
殖民地化
基因流
群体遗传学
真菌病
遗传变异
基因库
遗传多样性
基因
寄主电阻
遗传学
植物育种
遗传建筑学
病理系统
基因组学
进化生物学
遗传资源
基因组
植物
作者
Jared W. Westbrook,Joanna Malukiewicz,Qian Zhang,Avinash Sreedasyam,Jerry Jenkins,Vasiliy Lakoba,Sara F. Fitzsimmons,Jamie Van Clief,Kendra Collins,Stephen Hoy,Cassie Stark,Lake E. Graboski,Eric V. Jenkins,Thomas M. Saielli,Jarrett BJ,Lucinda Wigfield,Lauren M. Kerwien,Ciera Wilbur,Alexander M. Sandercock,J. Hill Craddock
出处
期刊:Science
[American Association for the Advancement of Science]
日期:2026-02-12
卷期号:391 (6786): 730-735
被引量:1
标识
DOI:10.1126/science.adw3225
摘要
More than a century after two introduced pathogens killed billions of American chestnut trees, introgression of resistance alleles from Chinese chestnuts has contributed to the recovery of self-sustaining populations. However, progress has been slow because of the complex genetic architecture of resistance. To better understand blight resistance, we compared reference genomes, gene expression responses, and stem metabolite profiles of the resistant Chinese and susceptible American chestnut species. To accelerate resistance breeding, we conducted large-scale phenotyping and genotyping in hybrids of these species. Simulation and inoculation experiments suggest that significant resistance gains are possible through selectively breeding trees with an average of 70 to 85% American chestnut ancestry. The resources developed in this work are foundational for breeding to create diverse restoration populations with sufficient disease resistance and competitive growth.
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