Comparative Physiology and Morphology of BLA-Projecting NBM/SI Cholinergic Neurons in Mouse and Macaque

IF 2.3 4区 医学 Q3 NEUROSCIENCES Journal of Comparative Neurology Pub Date : 2024-11-22 DOI:10.1002/cne.70001
Feng Luo, Li Jiang, Niraj S. Desai, Li Bai, Gabrielle V. Watkins, Mark A. G. Eldridge, Anya S. Plotnikova, Arya Mohanty, Alex C. Cummins, Bruno B. Averbeck, David A. Talmage, Lorna W. Role
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Abstract

Cholinergic projection neurons of the nucleus basalis and substantia innominata (NBM/SI) densely innervate the basolateral amygdala (BLA) and have been shown to contribute to the encoding of fundamental and life-threatening experiences. Given the vital importance of these circuits in the acquisition and retention of memories that are essential for survival in a changing environment, it is not surprising that the basic anatomical organization of the NBM/SI is well conserved across animal classes as diverse as teleost and mammal. What is not known is the extent to which the physiology and morphology of NBM/SI neurons have also been conserved. To address this issue, we made patch-clamp recordings from NBM/SI neurons in ex vivo slices of two widely divergent mammalian species, mouse and rhesus macaque, focusing our efforts on cholinergic neurons that project to the BLA. We then reconstructed most of these recorded neurons post hoc to characterize neuronal morphology. We found that rhesus macaque BLA-projecting cholinergic neurons were both more intrinsically excitable and less morphologically compact than their mouse homologs. Combining measurements of 18 physiological features and 13 morphological features, we illustrate the extent of the separation. Although macaque and mouse neurons both exhibited considerable within-group diversity and overlapped with each other on multiple individual metrics, a combined morphoelectric analysis demonstrates that they form two distinct neuronal classes. Given the shared purpose of the circuits in which these neurons participate, this finding raises questions about (and offers constraints on) how these distinct classes result in similar behavior.

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小鼠和猕猴 BLA 投射 NBM/SI 胆碱能神经元的生理学和形态学比较
杏仁基底核和内质(NBM/SI)的胆碱能投射神经元密集地支配着杏仁基底外侧(BLA),并被证明有助于对基本的和威胁生命的经历进行编码。鉴于这些回路在获取和保留对在不断变化的环境中生存至关重要的记忆方面的极端重要性,NBM/SI 的基本解剖组织在远足类动物和哺乳类动物等不同动物类别中得到很好的保留也就不足为奇了。我们不知道的是,NBM/SI 神经元的生理和形态在多大程度上也得到了保守。为了解决这个问题,我们在小鼠和猕猴这两种差异很大的哺乳动物的体外切片中进行了NBM/SI神经元的贴片钳记录,重点是投射到BLA的胆碱能神经元。然后,我们对记录到的大部分神经元进行了事后重建,以确定神经元形态的特征。我们发现,与小鼠同源神经元相比,猕猴投射到BLA的胆碱能神经元具有更高的内在兴奋性,而且形态上不那么紧凑。结合 18 种生理特征和 13 种形态特征的测量结果,我们说明了这种分离的程度。虽然猕猴和小鼠神经元在组内都表现出相当大的多样性,并且在多个个体指标上相互重叠,但综合形态电分析表明,它们形成了两个不同的神经元类别。鉴于这些神经元参与的电路具有共同的目的,这一发现提出了关于这些不同类别如何导致相似行为的问题(并提供了限制)。
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来源期刊
CiteScore
5.80
自引率
8.00%
发文量
158
审稿时长
3-6 weeks
期刊介绍: Established in 1891, JCN is the oldest continually published basic neuroscience journal. Historically, as the name suggests, the journal focused on a comparison among species to uncover the intricacies of how the brain functions. In modern times, this research is called systems neuroscience where animal models are used to mimic core cognitive processes with the ultimate goal of understanding neural circuits and connections that give rise to behavioral patterns and different neural states. Research published in JCN covers all species from invertebrates to humans, and the reports inform the readers about the function and organization of nervous systems in species with an emphasis on the way that species adaptations inform about the function or organization of the nervous systems, rather than on their evolution per se. JCN publishes primary research articles and critical commentaries and review-type articles offering expert insight in to cutting edge research in the field of systems neuroscience; a complete list of contribution types is given in the Author Guidelines. For primary research contributions, only full-length investigative reports are desired; the journal does not accept short communications.
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Comparative Physiology and Morphology of BLA-Projecting NBM/SI Cholinergic Neurons in Mouse and Macaque Small Brains: Body Shape Constrains Tissue Allocation to the Central Nervous System in Ant-Mimicking Spiders Stereological Analysis of the Rhesus Monkey Perirhinal and Parahippocampal Cortices Issue Information Harvey's Story
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