Funding:
This grant was funded by the US National Science Foundation under award number #1442280:
Dimensions US-China: Collaborative Research: How historical constraints, local adaptation, and species interactions shape biodiversity across an ancient floristic disjunction.
Abstract:
Biodiversity is multidimensional, composed of genetic, phenotypic, ecological, and geographic variation within and among species. Understanding the sources and patterns of Earth’s biodiversity will lead to a better understanding of our planet’s ecosystems and new strategies on how to conserve them. Within forests, plants grow in association with soil bacteria and fungi, but little is known about how these associations vary within and among forests, or how these interactions maintain or generate biodiversity. The forests of eastern Asia and eastern North America were anciently connected and have a shared evolutionary and ecological history; they therefore offer a unique opportunity to study the drivers of biodiversity across geographical space and through evolutionary time. This collaborative project among researchers at the University of Florida, North Carolina State University, Chicago University and colleagues at the Chinese Academy of Sciences and Zhejiang University investigates how the associations among plant, fungal and soil bacteria shape biodiversity through space and time. The research team has developed an extensive education and training program for undergraduates, graduate students and post-doctoral researchers comprising both field and lab components. Training will also include a cyber-enabled course for Chinese and US participants that will promote international scientific collaborations. This research will also contribute valuable information to improve global climate change models that inform national and international climate and energy policies.
This multidisciplinary project integrates phylogenomics, biogeography, and plant and microbial evolution and ecology to address novel questions on the origins and maintenance of biodiversity. The research team will reconstruct phylogenies using next-generation DNA sequencing methods to provide a robust framework for improved dating and biogeographic analyses. Comparative community phylogenetic analyses at six forest sites in eastern North America and four sites in China will evaluate spatial patterns of phylogenetic diversity within and between continents. Exploration of fungal and soil bacteria taxic and functional diversity will yield new understanding of their biodiversity and interactions with plants. Ecosystem function, inferred from analysis of plant functional traits and remotely sensed canopy properties, will be computed at all sites and linked to analyses of fungal and soil bacteria function. Innovative applications of phylogenetic and comparative methodologies will lead to new discoveries in phylogenetic and functional diversity of plants, soil bacteria and fungi at community and regional scales. Integration of historical connections, current patterns, and future species distribution models will lead to more holistic views of the drivers of biodiversity and will enable future hypothesis-driven research.
Chinese Abstract:
基于分子系统发育,用比较系统发育及功能性状检测法,使人们更深入了解生物多样性在
局域、地区和全球范围的形成和进化。目前利用以上方法对洲际间断分布植物和相关微生
物多样性和功能的整合研究仍未见。本项目选10个东亚(EA)与北美东部(ENA)间断分布中
生混交林群落典型样地,在个体、群落和生态系统三水平上分析植物和微生物功能与多样
性关系,研究群落及重要间断分布类群的系统发育。在植物个体水平,将度量与叶片经济
学及凋落物分解和微生物营养等密切相关的功能性状;在群落水平,比较大陆间及群落间
群落结构、种属分化和功能性状分布;在生态系统水平,调查样地植物生产力、冠层结构
等数据,分析中生混交林在多样性、功能及协同多样化在内的植物和微生物间关系。利用
气候模型和生态位模拟预测植物和微生物分布,揭示植物和微生物群落如何响应气候变化
。最终阐明地史制史制约、局域适应和种间互作在间断分布群落构建及多样性形成中的相
对作用。
Institutions:
For a full list of researchers, please see the people page. Researchers from the following institutions are part of this project.