单个嗅球模块神经元的气味反应特性。
Odorant response properties of individual neurons in an olfactory glomerular module.
机构信息
Department of Neurobiology and Anatomy, University of Texas Medical School at Houston, Houston, TX 77030, USA.
出版信息
Neuron. 2013 Mar 20;77(6):1122-35. doi: 10.1016/j.neuron.2013.01.022.
Abstract
Neuronal networks that are directly associated with glomeruli in the olfactory bulb are thought to comprise functional modules. However, this has not yet been experimentally proven. In this study, we explored the anatomical and functional architecture of glomerular modules using in vivo two-photon calcium imaging. Surprisingly, the deep portions of the glomerular modules showed considerable spatial overlap with other modules. Juxtaglomerular cells showed similar excitatory odorant response profiles to presynaptic olfactory sensory neuron inputs. Mitral cells exhibited a more sharply tuned molecular receptive range compared to juxtaglomerular cells, and their odorant response profiles varied depending on their interneuronal horizontal distances. These data suggest that glomerular modules are composed of functionally distinct neurons, and that homogenous odor inputs to each glomerulus may be parsed and processed in different fashions within the modules before being sent to higher olfactory centers.
摘要
被认为与嗅球中的肾小球直接相关的神经网络可能包含功能模块。然而,这尚未通过实验证明。在这项研究中,我们使用体内双光子钙成像技术探索了肾小球模块的解剖和功能结构。令人惊讶的是,肾小球模块的深部区域与其他模块有相当大的空间重叠。球旁细胞表现出与突触前嗅觉感觉神经元输入相似的兴奋性气味反应特征。与球旁细胞相比,僧帽细胞表现出更尖锐的分子感受范围,并且它们的气味反应特征取决于它们的中间神经元水平距离。这些数据表明,肾小球模块由功能不同的神经元组成,并且每个肾小球的同质气味输入可能在被发送到更高的嗅觉中心之前,以不同的方式在模块内进行解析和处理。
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