Friedrich Miescher Institute for Biomedical Research, Maulbeerstr. 66, CH-4058 Basel, Switzerland.
Curr Biol. 2010 Apr 27;20(8):R371-81. doi: 10.1016/j.cub.2010.02.039.
A central goal of modern neuroscience is to obtain a mechanistic understanding of higher brain functions under healthy and diseased conditions. Addressing this challenge requires rigorous experimental and theoretical analysis of neuronal circuits. Recent advances in optogenetics, high-resolution in vivo imaging, and reconstructions of synaptic wiring diagrams have created new opportunities to achieve this goal. To fully harness these methods, model organisms should allow for a combination of genetic and neurophysiological approaches in vivo. Moreover, the brain should be small in terms of neuron numbers and physical size. A promising vertebrate organism is the zebrafish because it is small, it is transparent at larval stages and it offers a wide range of genetic tools and advantages for neurophysiological approaches. Recent studies have highlighted the potential of zebrafish for exhaustive measurements of neuronal activity patterns, for manipulations of defined cell types in vivo and for studies of causal relationships between circuit function and behavior. In this article, we summarize background information on the zebrafish as a model in modern systems neuroscience and discuss recent results.
现代神经科学的一个核心目标是在健康和患病条件下,获得对大脑高级功能的机械理解。为了应对这一挑战,需要对神经元回路进行严格的实验和理论分析。光遗传学、高分辨率体内成像和突触连接图重建的最新进展为实现这一目标创造了新的机会。为了充分利用这些方法,模式生物应该允许在体内结合遗传和神经生理学方法。此外,大脑在神经元数量和物理尺寸方面应该较小。斑马鱼是一种很有前途的脊椎动物,因为它体型小,在幼虫阶段是透明的,并且提供了广泛的遗传工具和神经生理学方法的优势。最近的研究强调了斑马鱼在对神经元活动模式进行详尽测量、在体内对特定细胞类型进行操作以及研究回路功能与行为之间因果关系方面的潜力。在本文中,我们总结了作为现代系统神经科学模型的斑马鱼的背景信息,并讨论了最近的研究结果。
