Project 4: Neuronal Interactions

项目 4：神经元相互作用

基本信息

批准号：
9983182
负责人：
Hyunjune SEBASTIAN SEUNG
金额：
$ 37.34万
依托单位：
PRINCETON UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2017
资助国家：
美国
起止时间：
2017-09-28 至 2022-07-31
项目状态：
已结题

项目摘要

Project Summary: Project 4, Anatomical and Physiological Assays of Neuronal Interactions Working memory, the ability to temporarily hold multiple pieces of information in mind for manipulation, is central to virtually all cognitive abilities. This multi-component research project aims to comprehensively dissect the neural circuit mechanisms of this ability across multiple brain areas. The overall goal is to construct a neural circuit model of working memory and decisionmaking across multiple brain regions, constrained by neural activity, inactivation results, and connectivity. The model is already constrained by preliminary data showing choice-specific activity sequences in posterior cortical neurons in an evidence-accumulation task. This modeling will generate predictions, which will be tested by several techniques. The first approach will compare neural coding properties with anatomical connectivity by combining calcium imaging with serial-section electron microscopy. This aim will benefit from the Seung laboratory’s dramatic recent progress in automation by artificial intelligence, which will make it feasible to find connectomes of millimeterscale cortical volumes. The second approach will compare neural coding with physiological connectivity by combining calcium imaging with optogenetic perturbation at cellular resolution. This aim will leverage the Tank laboratory’s recent work on alloptical assays of connectivity. The third approach will be to study the role of interactions between cortical areas by performing calcium imaging in one area during optogenetic inactivation of another area. Much of this project focuses on retrosplenial cortex, which is of special interest because choicespecific activity sequences are more linear in this part of cortex than in other cortical areas. Furthermore, temporally specific inactivation of retrosplenial cortex causes behavior that mimics the response to deletion of incoming evidence. The first two approaches will test the example prediction that the local circuitry underlying activity sequences will exhibit sequential connectivity, that is, that connections from earlier to later neurons will be stronger or more frequent than those from later to earlier neurons. The third approach will test a second example prediction, that inactivation of the anterior M2 region of cortex will lead to reduction in nonspecific excitation in posterior cortices and alter sequence timing. Importantly, these example predictions are not intended to be comprehensive. Instead the generality of these techniques will enable researchers to test a wide variety of predictions that emerge from the neural circuit models that will be generated and refined based on data from these experiments and other components of the project.

项目摘要：项目 4，神经元相互作用的解剖学和生理学分析工作记忆，即暂时记住多条信息以进行操作的能力，几乎是所有认知能力的核心，这个多组成部分的研究项目旨在全面剖析这种能力在多个大脑区域的神经回路机制。是构建一个跨多个大脑区域的工作记忆和决策的神经回路模型，该模型受到神经活动、失活结果和连接性的限制，该模型已经受到初步数据的限制，这些数据显示了后皮质神经元中特定选择的活动序列。积累任务。建模将生成预测，并通过多种技术进行测试。第一种方法将通过结合钙成像和连续切片电子显微镜来比较神经编码特性和解剖连接性，这一目标将受益于 Seung 实验室最近在人工自动化方面取得的巨大进展。第二种方法将通过将钙成像与细胞分辨率的光遗传学扰动相结合来比较神经编码与生理连接。这一目标将利用 Tank 实验室最近的工作。第三种方法是通过在一个区域的光遗传学失活期间对另一个区域进行钙成像来研究皮质区域之间相互作用的作用，该项目的大部分重点是压后皮层，因为选择特定的活动，该区域特别令人感兴趣。此外，压后皮质的时间特异性失活会导致模仿对传入证据删除的反应的行为，前两种方法将测试局部的示例预测。活动序列下的电路将表现出顺序连接，即从较早的神经元到较晚的神经元的连接将比从较晚的神经元到较早的神经元的连接更强或更频繁。第三种方法将测试第二个示例预测，即前 M2 区域的失活。重要的是，这些示例预测并不全面，相反，这些技术的通用性将使研究人员能够测试来自神经网络的各种预测。将生成的电路模型并根据这些实验和项目其他组成部分的数据进行完善。