CAREER: Sensory Innovation and The Ecological Diversification of Snakes

职业：蛇的感官创新和生态多样化

• 批准号: 2141892
• 负责人: Alison Davis Rabosky
• 金额: $ 98.78万
• 依托单位: Regents of the University of Michigan - Ann Arbor
• 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: 2022-02-15 至 2027-01-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2141892&HistoricalAwards=false
• 关键词: CAREER; Sensory; Innovation; Ecological; Diversification

This award is funded in whole or in part under the American Rescue Plan Act of 2021 (Public Law 117-2). Some groups of animals have been spectacularly successful at moving among major habitats during their evolution, while other groups have diversified only within single habitats. However, the causes of these transitions remain poorly known, especially when animals use novel strategies that do not follow expectations that seem logical from their anatomy. By using new 3D technology to nondestructively visualize the bones and sensory systems of preserved specimens in natural history collections, this project will create a unified framework for understanding the relative importance of different anatomical traits that facilitate shifts to new habitats. These insights are especially important when organismal systems work together in a way that is more than the simple sum of their parts. The project then uses a student-centered ambassador model (“Project: MORPH!”) to leverage research products into 3D biodiversity education resources and experiences for the public and students at all levels. These components broaden participation in science through outreach programs and exhibits in a natural history museum that serves the Detroit metropolitan area, facilitating 1) experiential learning opportunities with innovative 3D technology and 2) the role of community scientists in providing foundational biodiversity data (“Story of the Specimen”). Additionally, this work provides advanced training in “big data” analysis and science communication to prepare early-career scientists from diverse backgrounds for future research in biodiversity science. Together, this project provides powerful insight into the drivers of successful invasion of major habitats across an iconic group of vertebrates and leverages emerging technologies towards comprehensive integration of biodiversity research and teaching in the 21st century. This project uses phylogenetic comparative methods to test how sensory systems have integrated with each other, and with trophic and skeletal innovation, to facilitate ecological diversification in snakes. Using non-invasive computed tomography (CT) scanning of soft tissue in museum specimens, this project tests a set of hypotheses for diversification across at least 60 independent invasions of subterranean, arboreal, and aquatic habitats. These tests are particularly important for understanding the processes underlying evolutionary convergence. Furthermore, tests of sensory evolution will fundamentally advance how classic locomotor and trophic traits are contextualized across ecological diversification in a major vertebrate radiation. Additionally, the educational components offer assessment-driven use of digital specimens that will provide innovative pedagogical insights about and uses of natural history collections, especially for future remote or informal learning opportunities.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.

该奖项全部或部分根据2021年美国救援计划法案（公法117-2）资助。一些动物群体在进化过程中在主要栖息地之间移动非常成功，而另一些动物群体只在单一栖息地内多样化。然而，这些转变的原因仍然知之甚少，特别是当动物使用新的策略时，这些策略不遵循从解剖学上看似乎合乎逻辑的期望。通过使用新的3D技术非破坏性地可视化自然历史收藏中保存的标本的骨骼和感觉系统，该项目将创建一个统一的框架，以了解促进向新栖息地转移的不同解剖特征的相对重要性。当有机体系统以一种不仅仅是各部分简单相加的方式协同工作时，这些见解尤为重要。该项目然后使用以学生为中心的大使模型（“项目：MORPH！”）利用研究产品为各级公众和学生提供3D生物多样性教育资源和体验。这些组成部分通过服务于底特律大都市区的自然历史博物馆的推广计划和展览扩大了对科学的参与，促进了1）创新3D技术的体验式学习机会和2）社区科学家在提供基础生物多样性数据方面的作用（“标本的故事”）。此外，这项工作还提供了“大数据”分析和科学交流方面的高级培训，为来自不同背景的早期职业科学家在生物多样性科学方面的未来研究做好准备。总之，这个项目提供了强大的洞察力，成功入侵的主要栖息地的驱动程序在一个标志性的脊椎动物群，并利用新兴技术对生物多样性研究和教学的全面整合在21世纪世纪。该项目使用系统发育比较方法来测试感觉系统如何相互整合，以及营养和骨骼创新，以促进蛇的生态多样化。 使用非侵入性计算机断层扫描（CT）扫描博物馆标本中的软组织，该项目测试了一组假设，在至少60个独立的入侵地下，树木和水生栖息地的多样化。这些测试对于理解进化趋同背后的过程尤其重要。此外，感觉进化的测试将从根本上推进经典的运动和营养特征是如何在一个主要的脊椎动物辐射的生态多样化的背景。此外，教育部分提供评估驱动的数字标本的使用，这将提供有关自然历史收藏的创新教学见解和使用，特别是为未来的远程或非正式学习机会。该奖项反映了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。