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Collaborative Research: ORCC: Trophic phenotypes as eco-evolutionary mediators of resilience to climate change

合作研究：ORCC：营养表型作为适应气候变化的生态进化中介

基本信息

批准号：
2222339
负责人：
Michael Kinnison
金额：
$ 73.29万
依托单位：
University of Maine
依托单位国家：
美国
项目类别：
Continuing Grant
财政年份：
2022
资助国家：
美国
起止时间：
2022-08-01 至 2026-07-31
项目状态：
未结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=2222339&HistoricalAwards=false
关键词：
Collaborative Research ORCC Trophic phenotypes

项目摘要

As lakes and other habitats continue to change in response to a warming climate, it is important to identify which ecosystems and organisms will be most vulnerable or able to persist. The thirteen populations of Arctic charr in Maine, USA, are the most southern remaining populations of this cold-adapted species and are expected to face challenges from climate warming and species invasions. We hypothesize that the ability of such populations to shift their diets and feeding traits may be especially important to their future persistence. This study investigates four of these charr-bearing lakes to determine how their habitat and food webs differ, and how this relates to specific Arctic charr behaviors and feeding traits. Electronic tags that emit sound will be used to track the movements of individual charr at fine scales. Twenty years of genetic samples will help determine how charr traits might change from adaptation or other processes. Quantitative models will be used to predict how differences in diet and habitat affect growth and population productivity, and subsequently the resilience of Arctic charr populations to continued warming and changes in habitats. Studying Arctic charr in Maine will help the conservation and management of not only this species, but also assess theory relevant to other species at the southern edge of their ranges. The project scientists will work closely with conservation groups and management agencies to ensure knowledge gained is quickly and effectively communicated for benefit. Many trailing-edge populations of fishes and other taxa inhabit small refuge habitats that are isolated and thus presumed vulnerable to interacting abiotic and biotic factors that could compress their niche to the point of collapse. This project tests an organismal-eco-evolutionary framework for assessing the role of trophic trait diversity and change in resilience to climate change, linking the genetic and plastic components of trophic trait variation to population demography, habitat and community contexts, and ultimately eco-evolutionary potential for persistence. Landlocked Arctic charr in Maine, USA, are the most southern populations of this species in North America. Moreover, there is evidence among Maine Arctic charr populations that populations are trophically divergent and that trophic trait variation can change in response to changes in resources. This project will integrate information on Arctic charr genotypes, phenotypes (morphology), diet, and movements (acoustic telemetry) with limnology and food web structure information to generate potential mechanistic links among variation in genotype, phenotype, and communities. Genetically inferred pedigrees and whole genome sequencing approaches will be integrated with phenotypic data and long-term (20 year) mark-recapture analysis of charr to estimate genetic and genomic parameters affecting trait lability and population dynamics in contemporary time. Individual-based models will simulate the bioenergetics and persistence of charr across trophic traits under a variety of temperatures, fish community compositions, and lake ecosystem types. Collectively, this research will improve the ability to predict the fate of trailing-edge populations through the lens of complex ecological feedbacks among climate change, intra- and interspecific interactions, and phenotypes.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.

由于湖泊和其他栖息地继续变化，以应对气候变暖，重要的是要确定哪些生态系统和生物将最脆弱或能够持续下去。美国缅因州的13个北极红点鲑种群是这种适应寒冷的物种最南部的剩余种群，预计将面临气候变暖和物种入侵的挑战。我们推测，这些人口的能力，改变他们的饮食和喂养性状可能是特别重要的，他们未来的持久性。这项研究调查了四个这些木炭承载湖泊，以确定它们的栖息地和食物网如何不同，以及这与特定的北极红点鲑行为和摄食特征的关系。会发出声音的电子标签将被用来在精细的尺度上跟踪单个字符的移动。20年的遗传样本将有助于确定红点鲑的性状如何从适应或其他过程中发生变化。定量模型将用于预测饮食和栖息地的差异如何影响生长和种群生产力，以及北极红点鲑种群对持续变暖和栖息地变化的适应能力。研究缅因州的北极红点鲑不仅有助于该物种的保护和管理，还有助于评估与其分布区南部边缘其他物种相关的理论。项目科学家将与保护团体和管理机构密切合作，确保获得的知识得到快速有效的传播。许多鱼类和其他类群的后缘种群栖息在孤立的小型避难所生境中，因此被认为容易受到相互作用的非生物和生物因素的影响，这些因素可能会将其生态位压缩到崩溃的地步。该项目测试了一个生物生态进化框架，用于评估营养性状多样性和气候变化适应能力变化的作用，将营养性状变异的遗传和可塑性成分与人口统计学，栖息地和社区环境联系起来，并最终确定生态进化的持久性潜力。位于美国缅因州的内陆北极红点鲑是该物种在北美最南部的种群。此外，有证据表明，在缅因州北极红点鲑种群的营养分化和营养性状的变化可以改变资源的变化。该项目将整合北极红点鲑基因型，表型（形态学），饮食和运动（声学遥测）与湖沼学和食物网结构信息的信息，以产生潜在的机制之间的联系，基因型，表型和社区的变化。遗传推断的系谱和全基因组测序方法将与表型数据和长期（20年）的标记-重捕获分析的charr估计遗传和基因组参数影响性状不稳定性和当代人口动态。基于个人的模型将模拟生物能量学和持久性的charr在各种温度下的营养性状，鱼类群落组成，湖泊生态系统类型。总的来说，这项研究将提高通过气候变化、种内和种间相互作用以及表型之间复杂的生态反馈的透镜来预测后缘种群命运的能力。该奖项反映了NSF的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。