Hierarchical Modular Structure of the Drosophila Connectome

Alex Kunin, Jiahao Guo, K. Bassler, X. Pitkow, K. Josić
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引用次数: 2

Abstract

The structure of neural circuitry plays a crucial role in brain function. Previous studies of brain organization generally had to trade off between coarse descriptions at a large scale and fine descriptions on a small scale. Researchers have now reconstructed tens to hundreds of thousands of neurons at synaptic resolution, enabling investigations into the interplay between global, modular organization, and cell type-specific wiring. Analyzing data of this scale, however, presents unique challenges. To address this problem, we applied novel community detection methods to analyze the synapse-level reconstruction of an adult female Drosophila melanogaster brain containing >20,000 neurons and 10 million synapses. Using a machine-learning algorithm, we find the most densely connected communities of neurons by maximizing a generalized modularity density measure. We resolve the community structure at a range of scales, from large (on the order of thousands of neurons) to small (on the order of tens of neurons). We find that the network is organized hierarchically, and larger-scale communities are composed of smaller-scale structures. Our methods identify well-known features of the fly brain, including its sensory pathways. Moreover, focusing on specific brain regions, we are able to identify subnetworks with distinct connectivity types. For example, manual efforts have identified layered structures in the fan-shaped body. Our methods not only automatically recover this layered structure, but also resolve finer connectivity patterns to downstream and upstream areas. We also find a novel modular organization of the superior neuropil, with distinct clusters of upstream and downstream brain regions dividing the neuropil into several pathways. These methods show that the fine-scale, local network reconstruction made possible by modern experimental methods are sufficiently detailed to identify the organization of the brain across scales, and enable novel predictions about the structure and function of its parts. Significance Statement The Hemibrain is a partial connectome of an adult female Drosophila melanogaster brain containing >20,000 neurons and 10 million synapses. Analyzing the structure of a network of this size requires novel and efficient computational tools. We applied a new community detection method to automatically uncover the modular structure in the Hemibrain dataset by maximizing a generalized modularity measure. This allowed us to resolve the community structure of the fly hemibrain at a range of spatial scales revealing a hierarchical organization of the network, where larger-scale modules are composed of smaller-scale structures. The method also allowed us to identify subnetworks with distinct cell and connectivity structures, such as the layered structures in the fan-shaped body, and the modular organization of the superior neuropil. Thus, network analysis methods can be adopted to the connectomes being reconstructed using modern experimental methods to reveal the organization of the brain across scales. This supports the view that such connectomes will allow us to uncover the organizational structure of the brain, which can ultimately lead to a better understanding of its function.
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果蝇连接体的分层模块结构
神经回路的结构在大脑功能中起着至关重要的作用。以前对大脑组织的研究通常不得不在大范围的粗糙描述和小范围的精细描述之间进行权衡。研究人员现在已经以突触分辨率重建了数万到数十万个神经元,从而能够研究全局、模块化组织和细胞类型特异性布线之间的相互作用。然而,分析这种规模的数据提出了独特的挑战。为了解决这一问题,我们应用新颖的群落检测方法对含有2万个神经元和1000万个突触的成年雌性黑腹果蝇大脑进行了突触水平的重建分析。使用机器学习算法,我们通过最大化广义模块化密度度量来找到最密集连接的神经元社区。我们在一系列尺度上解决社区结构,从大(数千个神经元)到小(数十个神经元)。我们发现网络是分层组织的,较大的社区是由较小的结构组成的。我们的方法确定了众所周知的苍蝇大脑的特征,包括它的感觉通路。此外,专注于特定的大脑区域,我们能够识别具有不同连接类型的子网络。例如,人工努力已经确定了扇形身体中的分层结构。我们的方法不仅可以自动恢复这种分层结构,还可以解析下游和上游区域的更精细的连接模式。我们还发现了一种新颖的模块化组织的上神经pil,与上游和下游脑区域的不同集群划分为几个通路的神经pil。这些方法表明,通过现代实验方法实现的精细尺度的局部网络重建足够详细,可以识别跨尺度的大脑组织,并能够对其各部分的结构和功能进行新颖的预测。半脑是成年雌性黑腹果蝇大脑的部分连接体,包含超过2万个神经元和1000万个突触。分析这种规模的网络结构需要新颖而高效的计算工具。我们应用了一种新的社区检测方法,通过最大化广义模块化度量来自动发现Hemibrain数据集中的模块化结构。这使我们能够在一定的空间尺度上解决苍蝇半脑的群落结构,揭示了网络的分层组织,其中较大的模块由较小的结构组成。该方法还允许我们识别具有不同细胞和连接结构的子网络,例如扇形体中的分层结构和上神经层的模块化组织。因此,利用现代实验方法重构的连接体可以采用网络分析方法来揭示大脑跨尺度的组织。这支持了这样一种观点,即这种连接体将使我们能够揭示大脑的组织结构,从而最终更好地理解其功能。
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