YIA-PGR: Molecular Evolutionary Genetics of Crop and Weed Responses to Crowding

YIA-PGR：作物和杂草对拥挤反应的分子进化遗传学

• 批准号: 0227103
• 负责人: Cynthia Weinig
• 金额: $ 172.53万
• 依托单位: University of Minnesota-Twin Cities
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2002
• 资助国家: 美国
• 起止时间: 2002-12-01 至 2008-01-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0227103&HistoricalAwards=false
• 关键词: YIA; PGR; Molecular; Evolutionary; Genetics

Domestication of wild species is characterized by changes in diverse traits, including plant architecture, fruit and seed morphology, fruit dispersal, and the timing of developmental events. These changes result from human selection to increase yield. Changes in environmental responses are also important in this regard. For instance, higher planting densities could increase yield in many crop species, but densities are limited by developmental responses to crowding, in which time to flowering decreases and relative allocation to structural organs increases at the cost of agronomically desirable traits such as leaf, root, and fruit production. Regardless of the trait selected in a crop species, agricultural weeds exhibit dramatic compensatory evolution that increases weed fitness at the cost of crop productivity. Comparative genetic approaches and genomic tools provide a means to investigate the genetic basis of phenotypic responses to crowding. The research program focuses on crowding responses in Brassica rapa. In addition to domesticated varieties, naturalized populations occur in both agricultural fields and disturbed, weedy sites. Thus, this system is appropriate for investigating both the loci targeted during domestication and those underlying adaptation of weed species to agricultural settings. The research takes advantage of available genomic tools to investigate the genetic basis of competitive responses in agricultural and natural settings. Specific goals include 1) identifying the genetic determinants (known as quantitative trait loci or QTL) for fitness and traits affecting competitive ability in field settings, 2) using controlled light environments to identify QTL important for response to specific environmental cues, 3) quantifying evolutionary responses (measured as allele frequency changes) at QTL determining fitness and phenotypic responses to competition in agricultural and disturbed sites, and 4) cloning QTL for traits important to competitive ability with the aim of determining both genetic targets for crop improvement and loci underlying evolutionary change in agricultural weeds. The experimental research will not only apply current genomic tools to evolutionary studies but also develop and distribute additional genetic resources for dissemination to other researchers. The results will contribute significantly to both crop improvement and an understanding of weed evolution that may aid in management. Finally, the collaborative nature of this work will provide unique, cross-disciplinary training for undergraduates, graduate students, and postdoctoral researchers in the application of genomic tools to evolutionary genetics and the study of both crop species and agricultural weeds. Deliverables: Contact the PI for delivarables

野生种驯化的特点是在不同性状的变化，包括植物结构，果实和种子形态，果实传播，和发育事件的时间。这些变化是人类为了提高产量而进行的选择。在这方面，环境对策的变化也很重要。例如，较高的种植密度可以提高许多作物品种的产量，但密度受到对拥挤的发育反应的限制，开花时间减少，结构器官的相对分配增加，但以牺牲叶、根等农艺学上理想的性状为代价。和水果产量。无论在作物物种中选择的性状如何，农业杂草都表现出戏剧性的补偿性进化，以牺牲作物生产力为代价增加杂草适合度。比较遗传学方法和基因组工具提供了一种手段来调查拥挤的表型反应的遗传基础。该研究计划的重点是在芜菁拥挤反应。除了驯化的品种，归化种群发生在农业领域和干扰，杂草丛生的网站。因此，该系统是适当的调查驯化过程中的目标和那些潜在的适应杂草物种农业环境的位点。该研究利用现有的基因组工具来研究农业和自然环境中竞争反应的遗传基础。具体目标包括：1）确定遗传决定因素（称为数量性状基因座或QTL），2）使用受控的光环境来鉴定对响应特定环境线索重要的QTL，3）量化进化反应（以等位基因频率变化来衡量）在农业和干扰地点决定适合度和对竞争的表型反应的QTL上，（4）克隆对竞争能力重要的性状的QTL，目的是确定作物改良的遗传靶标和农业杂草进化变化的潜在基因座。实验研究不仅将当前的基因组工具应用于进化研究，还将开发和分发额外的遗传资源以传播给其他研究人员。研究结果将有助于作物改良和杂草进化的理解，这可能有助于管理。最后，这项工作的协作性质将为本科生，研究生和博士后研究人员提供独特的跨学科培训，将基因组工具应用于进化遗传学以及作物物种和农业杂草的研究。 可交付物：可交付物联系PI