3D electron microscopy and volume-based bouton sorting reveal the selectivity of inputs onto geniculate relay cell and interneuron dendrite segments.

IF 2.1 4区 医学 Q1 ANATOMY & MORPHOLOGY Frontiers in Neuroanatomy Pub Date : 2023-03-17 eCollection Date: 2023-01-01 DOI:10.3389/fnana.2023.1150747
Erin E Maher, Alex C Briegel, Shahrozia Imtiaz, Michael A Fox, Hudson Golino, Alev Erisir
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引用次数: 1

Abstract

Introduction: The visual signals evoked at the retinal ganglion cells are modified and modulated by various synaptic inputs that impinge on lateral geniculate nucleus cells before they are sent to the cortex. The selectivity of geniculate inputs for clustering or forming microcircuits on discrete dendritic segments of geniculate cell types may provide the structural basis for network properties of the geniculate circuitry and differential signal processing through the parallel pathways of vision. In our study, we aimed to reveal the patterns of input selectivity on morphologically discernable relay cell types and interneurons in the mouse lateral geniculate nucleus.

Methods: We used two sets of Scanning Blockface Electron Microscopy (SBEM) image stacks and Reconstruct software to manually reconstruct of terminal boutons and dendrite segments. First, using an unbiased terminal sampling (UTS) approach and statistical modeling, we identified the criteria for volume-based sorting of geniculate boutons into their putative origins. Geniculate terminal boutons that were sorted in retinal and non-retinal categories based on previously described mitochondrial morphology, could further be sorted into multiple subpopulations based on their bouton volume distributions. Terminals deemed non-retinal based on the morphological criteria consisted of five distinct subpopulations, including small-sized putative corticothalamic and cholinergic boutons, two medium-sized putative GABAergic inputs, and a large-sized bouton type that contains dark mitochondria. Retinal terminals also consisted of four distinct subpopulations. The cutoff criteria for these subpopulations were then applied to datasets of terminals that synapse on reconstructed dendrite segments of relay cells or interneurons.

Results: Using a network analysis approach, we found an almost complete segregation of retinal and cortical terminals on putative X-type cell dendrite segments characterized by grape-like appendages and triads. On these cells, interneuron appendages intermingle with retinal and other medium size terminals to form triads within glomeruli. In contrast, a second, presumed Y-type cell displayed dendrodendritic puncta adherentia and received all terminal types without a selectivity for synapse location; these were not engaged in triads. Furthermore, the contribution of retinal and cortical synapses received by X-, Y- and interneuron dendrites differed such that over 60% of inputs to interneuron dendrites were from the retina, as opposed to 20% and 7% to X- and Y-type cells, respectively.

Conclusion: The results underlie differences in network properties of synaptic inputs from distinct origins on geniculate cell types.

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3D电子显微镜和基于体积的bouton分选揭示了对膝状体中继细胞和中间神经元树突节段的输入的选择性。
引言:在视网膜神经节细胞处诱发的视觉信号在被发送到皮层之前,会受到撞击外侧膝状体核细胞的各种突触输入的修饰和调节。膝状体输入对在膝状体细胞类型的离散树突段上聚集或形成微循环的选择性可以为膝状体电路的网络特性和通过视觉的平行通路的差分信号处理提供结构基础。在我们的研究中,我们旨在揭示小鼠外侧膝状体核中形态学上可辨别的中继细胞类型和中间神经元的输入选择性模式。方法:我们使用两套扫描块面电子显微镜(SBEM)图像堆栈和重建软件手动重建终节和树突段。首先,使用无偏终端抽样(UTS)方法和统计建模,我们确定了基于体积将膝状突起分类为其假定起源的标准。根据先前描述的线粒体形态分为视网膜和非视网膜两类的生殖器末端突,可以根据其突体积分布进一步分为多个亚群。根据形态学标准,被视为非视网膜的终末由五个不同的亚群组成,包括小规模的皮质丘脑和胆碱能发作,两个中等规模的GABA能输入,以及一个包含深色线粒体的大规模发作型。视网膜末梢也由四个不同的亚群组成。然后将这些亚群的截止标准应用于在中继细胞或中间神经元的重建树突段上突触的末端数据集。结果:使用网络分析方法,我们发现在以葡萄状附属物和三联体为特征的假定X型细胞树突节上,视网膜和皮层终末几乎完全分离。在这些细胞上,中间神经元附属物与视网膜和其他中等大小的终末混合,在肾小球内形成三联体。相反,第二个推测的Y型细胞显示出树状点状粘附,并接受所有末端类型,而对突触位置没有选择性;他们没有参与黑社会。此外,X、Y和中间神经元树突接收的视网膜和皮层突触的贡献不同,因此超过60%的中间神经元树突输入来自视网膜,而X和Y型细胞分别为20%和7%。结论:这些结果揭示了不同来源的膝状体细胞类型突触输入网络特性的差异。
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来源期刊
Frontiers in Neuroanatomy
Frontiers in Neuroanatomy ANATOMY & MORPHOLOGY-NEUROSCIENCES
CiteScore
4.70
自引率
3.40%
发文量
122
审稿时长
>12 weeks
期刊介绍: Frontiers in Neuroanatomy publishes rigorously peer-reviewed research revealing important aspects of the anatomical organization of all nervous systems across all species. Specialty Chief Editor Javier DeFelipe at the Cajal Institute (CSIC) is supported by an outstanding Editorial Board of international experts. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, clinicians and the public worldwide.
期刊最新文献
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