Collaborative Research: Scale-dependent processes as the drivers for understanding range- and niche-expansion in a widespread native species

合作研究：规模依赖过程作为理解广泛的本地物种的范围和生态位扩张的驱动因素

• 批准号: 1915913
• 负责人: Sarah Supp
• 金额: $ 5.33万
• 依托单位: Denison University
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2019
• 资助国家: 美国
• 起止时间: 2019-07-15 至 2025-06-30
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1915913&HistoricalAwards=false
• 关键词: Collaborative; Research; Scale; dependent; processes

Eastern Red Cedar (Juniperus virginiana) is native to the eastern United States, where this attractive tree has been a popular choice for landscaping. But out in the Great Plains, Red Cedar is known as the "green glacier", because this slow-growing species is taking over once-productive grasslands. Ranchers face substantial economic costs in removing Red Cedar from grazing lands, and it reduces grassland biodiversity through competition with native species. But how do you stop a "green glacier"? Populations might be expanding because environmental variability has altered frost and drought regimes, or because humans have implemented prairie management practices such as fire suppression, or even because of changes in the migration patterns of seed-dispersing birds. It is more likely, however, that many factors are at work. For example, environmental variability might allow plants to move into a new region, but seed dispersal by birds could promote population expansion within a region. Rather than focus on one factor, this study will determine the relative importance of several causal factors. Data from experiments will be used in a model that predicts the rate and locations where Red Cedar range expansion is likely to occur. Findings will be presented to the public at the Holden Arboretum Scientist Lecture Series and incorporated into Holden Arboretum's "Working with Nature" K-12 Camp and "Tree Corp" adult workforce development program. Uncovering scale-dependent mechanisms controlling range and niche expansion of plants is a key issue in biodiversity research. This work integrates physiological and ecological processes across scales to determine the potential for further range expansion. The central hypothesis is that, at a large spatial scale, changes in prairie management are more important than physiological climate tolerance for promoting range expansion, while at smaller scales, biotic factors such as avian dispersal, competition and facilitation are more important. The spatial scale of variation will be determined using microsatellites in historical, encroaching and niche expanding populations. The effects of fire will be examined using long-term data from the Konza Prairie NSF-LTER, while manipulative and field experiments will determine how the interaction of frost and drought impact Red Cedar performance. Seed dispersal by birds and changes in bird migration over time will be examined to determine how far, and where, birds disseminate Red Cedar. Empirical data will be integrated into a spatially explicit population-level age/stage matrix model, based on inputs from structural equation modeling at all three spatial scales, with spatial resolution determined by the results of microsatellite studies.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

东部红雪松（Juniperus virginiana）原产于美国东部，这种有吸引力的树木一直是景观美化的热门选择。但在大平原，红雪松被称为“绿色冰川”，因为这种生长缓慢的物种正在接管曾经多产的草原。牧场主在将红雪松从牧场上移除时面临着巨大的经济成本，并且通过与本地物种的竞争减少了草原的生物多样性。但如何阻止“绿色冰川”呢？种群的扩大可能是因为环境的变化改变了霜冻和干旱的状况，或者是因为人类实施了草原管理措施，如灭火，甚至是因为传播种子的鸟类的迁徙模式发生了变化。然而，更有可能的是，许多因素在起作用。例如，环境的变化可能会使植物迁移到一个新的地区，但鸟类传播种子可能会促进一个地区内的种群扩张。这项研究将确定几个因果因素的相对重要性，而不是集中在一个因素上。来自实验的数据将被用于一个模型，该模型预测红雪松范围扩张可能发生的速度和位置。研究结果将在霍尔顿植物园科学家系列讲座中向公众展示，并纳入霍尔顿植物园的“与自然合作”K-12营地和“树木公司”成人劳动力发展计划。 揭示植物分布区和生态位扩展的尺度依赖机制是生物多样性研究中的一个关键问题。这项工作整合了跨尺度的生理和生态过程，以确定进一步扩大范围的潜力。核心假设是，在大的空间尺度上，草原管理的变化比生理气候耐受性更重要，以促进范围的扩大，而在较小的尺度上，生物因素，如鸟类的扩散，竞争和促进更重要。变异的空间尺度将使用微卫星在历史上，侵占和生态位扩大人口。火灾的影响将使用来自Konza Prairie NSF-LTER的长期数据进行检查，而操纵和实地实验将确定霜冻和干旱的相互作用如何影响红雪松的表现。鸟类的种子传播和鸟类迁徙随时间的变化将被检查，以确定多远，在哪里，鸟类传播红雪松。经验数据将被集成到一个空间上明确的人口水平的年龄/阶段矩阵模型的基础上，在所有三个空间尺度的结构方程模型的输入，与空间分辨率由微卫星研究的结果确定。这个奖项反映了NSF的法定使命，并已被认为是值得通过使用基金会的智力价值和更广泛的影响审查标准进行评估的支持。