Collaborative Research: Dimensions US-Biota Sao Paulo: Chemically mediated multi-trophic interaction diversity across tropical gradients

合作研究：Dimensions US-Biota Sao Paulo：化学介导的跨热带梯度的多营养相互作用多样性

• 批准号: 1442103
• 负责人: Lee Dyer
• 金额: $ 150.24万
• 依托单位: Board of Regents, NSHE, obo University of Nevada, Reno
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-11-01 至 2020-10-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1442103&HistoricalAwards=false
• 关键词: Collaborative; Research; Dimensions; US; Biota

This research will examine the diversity and ecological complexity of plants and associated insects in forests across a variable landscape in Brazil. Plants, insects, and their predators make up over half of all known organisms, and their interactions are essential to ecosystem health. This is especially true for tropical forests, where ecologists are only beginning to understand the nature and complexity of these interactions. In particular, little is known about: 1) the diversity of plant chemicals that deter insect herbivory and affect other plants and animals, 2) how diversity of these plant chemicals varies within and between plant species, and 3) how plant chemistry can affect the diversity and productivity of entire forests. Recent advances in chemistry and molecular biology provide the opportunity to understand the diversity of plant-insect interactions at three different levels (chemical, genetic, and taxonomic) with unprecedented scope and depth. These new methods will be integrated and enhanced by a unique team of U.S. and Brazilian scientists to investigate the diversity of insect-plant food webs, how they are shaped by plant chemical defenses and environmental gradients, and how this diversity affects forest stability and productivity. The research will contribute to understanding how large global changes in biodiversity and climate will affect plant-insect-predator interactions, how plant genetic and chemical diversity influences plant-feeding, and how taxonomic and genetic diversity of insect predators can affect control of harmful insects. The comprehensive sampling and methods used in this project will result in the discovery of new species of plants and insects, new biologically active molecules, and are likely to deliver new tools and approaches that have powerful applications in agriculture and medicine. This international and multi-disciplinary research project will have broad impacts by involving K-12 students, science teachers, and citizen scientists. Discoveries will be widely communicated to the public via websites, and scientific and popular publications. This project is focused on a highly diverse system involving plants in the genus Piper (Piperaceae), associated herbivores, and parasitic wasps and flies. The research will utilize cutting edge approaches to studying biodiversity that link measures of interaction diversity to genetic diversity, population genetic structure, and plant chemical diversity involving the following components: 1) Large scale sampling of herbivores and their parasitoids on diverse Piper species across an array of sites to assess effects of abiotic gradients on community structure and ecosystem processes, and to acquire specimens for taxonomic, genomic, and phytochemical analysis. 2) Field experiments where taxonomic, genetic, and functional diversity will be manipulated along with abiotic factors to strengthen inferences from statistical analysis of field surveys, community genetics, and measures of metabolite diversity. 3) Taxonomic and systematic analysis of plants, herbivores, and parasitoids using traditional and novel methods (genomics) to document and describe new taxa, understand their relationships, and reveal cryptic diversity. 4) Population genomic analyses of plants, herbivores, and parasitoids to understand how geography, plant phylogeny and chemistry influence population structure and genetic differentiation across trophic levels. 5) Characterization of metabolite diversity of Piper species; how metabolite diversity varies with phylogeny, ecology, and herbivore pressure; and the effect of phytochemical diversity on higher trophic levels. The combination of quantitative sampling along elevational gradients, newly developed metabolomics methods, population genomics, and a large scale experiment will make possible tests of emerging hypotheses about relationships between plant chemistry, and different dimensions of diversity, and will represent the first large scale, among-site plant-herbivore-parasitoid food-web comparison in the tropics.

这项研究将研究巴西不同景观中森林中植物和相关昆虫的多样性和生态复杂性。植物、昆虫和它们的捕食者占所有已知生物的一半以上，它们之间的相互作用对生态系统的健康至关重要。对于热带森林来说尤其如此，生态学家才刚刚开始了解这些相互作用的性质和复杂性。特别是，人们对以下方面知之甚少：1）阻止昆虫植食性并影响其他植物和动物的植物化学物质的多样性，2）这些植物化学物质的多样性如何在植物物种内部和之间变化，以及3）植物化学物质如何影响整个森林的多样性和生产力。化学和分子生物学的最新进展提供了一个机会，了解植物-昆虫相互作用的多样性在三个不同的水平（化学，遗传和分类）与前所未有的广度和深度。这些新方法将由美国和巴西科学家组成的独特团队整合和增强，以调查昆虫-植物食物网的多样性，植物化学防御和环境梯度如何塑造它们，以及这种多样性如何影响森林稳定性和生产力。该研究将有助于了解生物多样性和气候的全球变化将如何影响植物-昆虫-捕食者的相互作用，植物遗传和化学多样性如何影响植物饲养，以及昆虫捕食者的分类和遗传多样性如何影响有害昆虫的控制。该项目中使用的全面采样和方法将导致发现新的植物和昆虫物种，新的生物活性分子，并可能提供在农业和医学中具有强大应用的新工具和方法。这个国际性的多学科研究项目将通过涉及K-12学生，科学教师和公民科学家产生广泛的影响。发现将通过网站、科学和大众出版物广泛传播给公众。该项目的重点是一个高度多样化的系统，包括胡椒属（胡椒科）植物，相关的食草动物，寄生蜂和苍蝇。该研究将利用最先进的方法来研究生物多样性，将相互作用多样性的措施与遗传多样性，种群遗传结构和植物化学多样性联系起来，涉及以下组成部分：1）在一系列地点对不同胡椒属物种上的食草动物及其寄生蜂进行大规模取样，以评估非生物梯度对群落结构和生态系统过程的影响，并采集标本进行分类学、基因组学和植物化学分析。2)田间试验，其中分类，遗传和功能多样性将被操纵沿着非生物因素，以加强从田间调查，社区遗传学和代谢物多样性的措施的统计分析的推论。3)植物，食草动物和寄生物的分类和系统分析，使用传统和新的方法（基因组学）来记录和描述新的分类群，了解它们的关系，并揭示隐藏的多样性。4)对植物、食草动物和寄生虫进行种群基因组分析，以了解地理、植物生殖和化学如何影响种群结构和营养水平上的遗传分化。5)胡椒属物种的代谢物多样性的表征;代谢物多样性如何随生长发育、生态和食草动物压力而变化;以及植物化学多样性对更高营养水平的影响。结合定量采样沿着海拔梯度，新开发的代谢组学方法，人口基因组学，和一个大规模的实验，将可能测试新兴的假设植物化学之间的关系，不同维度的多样性，并将代表第一个大规模的，在热带地区的植物-食草动物-寄生虫食物网比较。