Organization of the telencephalon in lungfish

肺鱼端脑的组织

• 批准号: 1120844
• 负责人: R. Glenn Northcutt
• 金额: $ 42万
• 依托单位: University of California-San Diego
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-08-15 至 2015-03-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1120844&HistoricalAwards=false
• 关键词: Organization; telencephalon; lungfish

The applicant proposes to perform experiments on the brains of lungfishes that will determine if they are the closest living relative to the ancestor of all land vertebrates, including humans. Brain organization, particularly the organization of the forebrain, provides valuable clues to the biology of an animal and to taxonomic relationships among animals. Further data on brain organization in lobe-finned fishes is critical, as some early member of the lobe-finned fishes gave rise to the first land vertebrates. Living lobe-finned fishes include the coelacanth and the lungfishes; most are relatively rare, almost all are threatened; and coelacanths are impossible to obtain on demand. Experimental studies comparing coelacanth brains are therefore not feasible. Current opinion holds that lungfish brains are highly aberrant, but the applicant has generated a new model of forebrain organization in the African lungfish. This model suggests that forebrain organization in lungfishes is far more similar to that in land vertebrates than has been recognized. He now proposes to test three hypotheses inherent in this model by using biological tracers to reveal certain features of lungfish brains. He will compare these features with those in amphibians (the first land vertebrates). If his hypotheses are valid, then lungfishes are the living lobe-finned fishes most closely related to the ancestor of all land vertebrates, and their forebrain organization can be used to infer forebrain organization in the common ancestor of lungfishes and land vertebrates. This work will provide insights into how vertebrate nervous systems have subserved new mechanisms of behavior and change. Data from the project are expected to reveal a robust adaptive strategy for the central nervous system, extending back to the earliest land vertebrates. The data will also provide valuable new information about the first land animals for neurobiologists, evolutionary biologists, paleontologists and general vertebrate biologists.

申请人提议对肺鱼的大脑进行实验，以确定它们是否是与包括人类在内的所有陆地脊椎动物的祖先最近的活体亲属。大脑的组织，特别是前脑的组织，为动物的生物学和动物之间的分类关系提供了有价值的线索。 进一步的数据对脑组织的叶状鳍鱼类是至关重要的，因为一些早期成员的叶状鳍鱼类产生了第一个陆地脊椎动物。 现存的圆鳍鱼包括腔棘鱼和肺鱼;大多数相对罕见，几乎所有都受到威胁;腔棘鱼是不可能按需获得的。 因此，比较腔棘鱼大脑的实验研究是不可行的。 目前的观点认为，肺鱼的大脑是高度异常的，但申请人已经在非洲肺鱼中产生了一个新的前脑组织模型。这个模型表明，肺鱼的前脑组织与陆地脊椎动物的前脑组织比人们所认识的要相似得多。他现在提出，通过使用生物示踪剂来揭示肺鱼大脑的某些特征，来测试这个模型中固有的三个假设。他将把这些特征与两栖动物（第一种陆地脊椎动物）的特征进行比较。 如果他的假设成立，那么肺鱼是现存的与所有陆地脊椎动物的祖先关系最密切的叶鳍鱼类，它们的前脑组织可以用来推断肺鱼和陆地脊椎动物共同祖先的前脑组织。这项工作将提供深入了解脊椎动物神经系统如何使行为和变化的新机制。 该项目的数据有望揭示中枢神经系统的强大适应策略，可追溯到最早的陆地脊椎动物。 这些数据还将为神经生物学家、进化生物学家、古生物学家和普通脊椎动物生物学家提供有关第一批陆地动物的有价值的新信息。