Collaborative Research: Evolution of Multicellularity: Fluid Mechanics of Feeding by Unicellular vs. Multicellular Choanoflagellates

合作研究：多细胞性的进化：单细胞与多细胞领鞭毛虫摄食的流体力学

• 批准号: 1146634
• 负责人: Roman Stocker
• 金额: $ 29.76万
• 依托单位: Massachusetts Institute of Technology
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-05-01 至 2015-04-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1146634&HistoricalAwards=false
• 关键词: Collaborative; Research; Evolution; Multicellularity; Fluid

The evolutionary origin of multicellular animals from a single-celled protozoan ancestor represents a pivotal transition in life's history and one of its greatest unsolved mysteries. Recent genetic studies have shown that the most primitive animals (sponges) are very closely related to a group of protozoans called choanoflagellates. A choanoflagellate cell swims by undulating a single flagellum and captures food (bacteria) from the surrounding water on a collar of microvilli (hair-like protrusions of the cell surface) that rings the flagellum. Some single-celled choanoflagellates can be induced to form multicellular colonies via cell division. One such species that lives in estuaries, Salpingoeca rosetta, is used to study the evolution of multicellularity. For multicellularity to evolve, there must have been a selective advantage to being multicellular, but since both unicellular and colonial choanoflagellates still exist today, there may be different environmental conditions under which single-celled or multicellular forms perform better. One important aspect of performance that affects choanoflagellate survival and reproduction is feeding on bacterial prey. Marine habitats can differ in the size, spacing, and richness of patches of bacteria. This study uses S. rosetta to study the consequences of being multicellular vs. unicellular to foraging success, and to discover the mechanisms responsible for differences in performance. The objectives are: 1) to quantify the swimming behavior of unicellular vs. colonial S. rosetta in environments in which bacteria are unevenly distributed, to determine if and how choanoflagellates aggregate in patches of high prey concentration; 2) to determine the feeding rates of unicellular vs. colonial S. rosetta for a range of bacterial prey concentrations; and 3) to study the fluid mechanics of water current production and prey capture by S. rosetta, to elucidate how being part of a colony alters the feeding current, and the mechanisms and effectiveness of prey capture. The diverse expertise of a multidisciplinary team will be focused on these objectives: Koehl (fluid dynamics of organisms), King (molecular evolution of choanoflagellates), Stocker (biophysics and ecology of microscopic aquatic organisms), and Fletcher (advanced optical techniques for imaging microscopic organisms). This study not only explores the role of foraging as a selective factor in the evolution of multicellularity, which set in motion all subsequent animal evolution, but also has ecological significance. Protozoans, both unicellular and colonial, play an important role in aquatic food webs. This project is the first to study, within a single protozoan species, the effects of being uni- vs. multicellular to foraging by these ecologically-important organisms.This project will provide research training for graduate students in a project involving both physics and biology, helping them develop skills for collaboration across disciplines. The microfluidics system developed for this project will be useful for studying other microscopic organisms in patchy environments, and our robotic flagellum is a prototype for future studies of undulatory swimming.

多细胞动物从单细胞原生动物祖先进化而来，代表了生命历史上的一个关键转变，也是其最大的未解之谜之一。 最近的遗传学研究表明，最原始的动物（海绵）与一组称为choanoflagellates的原生动物非常密切相关。 后鼻孔鞭毛虫细胞通过波动单个鞭毛游动，并在环绕鞭毛的微绒毛（细胞表面的毛发状突起）上从周围的水中捕获食物（细菌）。 一些单细胞领鞭毛虫可以通过细胞分裂形成多细胞集落。 其中一种生活在河口的物种，Salpingoeca rosetta，被用来研究多细胞生物的进化。 对于多细胞生物的进化，多细胞生物一定有选择性优势，但由于单细胞和群体领鞭毛虫今天仍然存在，可能存在不同的环境条件，单细胞或多细胞形式表现得更好。影响领鞭藻生存和繁殖的一个重要方面是以细菌猎物为食。海洋栖息地可以在大小，间距和丰富的细菌补丁。本研究采用S. rosetta研究多细胞与单细胞对觅食成功的影响，并发现导致表现差异的机制。 目的是：1）量化单细胞与群体S。罗塞塔在细菌分布不均匀的环境中，以确定领鞭藻是否以及如何在高猎物浓度的斑块中聚集; 2）确定单细胞与群体S的摄食率。rosetta的一系列的细菌猎物浓度;和3）研究水流生产和猎物捕获的流体力学的S。罗塞塔，以阐明如何成为一个殖民地的一部分改变喂养电流，和机制和有效性的猎物捕获。一个多学科小组的各种专门知识将集中在这些目标上：科尔（生物体的流体动力学），国王（choanoflagellates的分子进化），斯托克（微观水生生物的生物物理学和生态学），和弗莱彻（先进的光学技术成像微观生物）。 这项研究不仅探讨了觅食作为一个选择因素在多细胞生物进化中的作用，启动了所有随后的动物进化，而且具有生态学意义。原生动物，无论是单细胞的还是群体的，在水生食物网中扮演着重要的角色。该项目是第一个在单一原生动物物种中研究单细胞与多细胞对这些生态重要生物觅食的影响的项目。该项目将为研究生提供涉及物理学和生物学的项目的研究培训，帮助他们培养跨学科合作的技能。为该项目开发的微流体系统将有助于研究斑块环境中的其他微生物，我们的机器人鞭毛是未来波动游泳研究的原型。