William A. Noftz , Emily E. Echols , Nichole L. Beebe , Jeffrey G. Mellott , Brett R. Schofield
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We then used Cre-dependent labeling of cholinergic neurons in normal-hearing ChAT-Cre mice to selectively label the cholinergic projections to the IC from each of the cholinergic sources. Labeling of cholinergic projections from the PPT and LDT revealed cholinergic axons and boutons terminating throughout the IC, with the ipsilateral projection being denser. Electron microscopic examination showed that these cholinergic axons can form traditional synaptic junctions with IC neurons. In separate experiments, selective labeling of cholinergic projections from the LPGi revealed bilateral projections to the IC. The LPGi axons exhibited relatively equal densities on ipsilateral and contralateral sides, but on both sides the terminations were largely restricted to the non-lemniscal regions of the IC (i.e., the dorsal cortex, lateral cortex and intercollicular tegmentum). We conclude first that cholinergic axons can form traditional synapses in the IC. 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引用次数: 0
摘要
下丘(IC)是整合听觉信息的中脑枢纽,接收密集的胆碱能输入,几乎可以调节听觉的所有方面。了解胆碱能调节的一个关键步骤是确定胆碱能输入的来源和终止模式。小鼠的听觉集成电路是一种日益重要的听力研究模型,但这些问题尚未得到解决。我们研究了成年雄性和雌性小鼠听觉集成电路的胆碱能输入。我们使用逆行追踪和免疫化学方法确定了小鼠 IC 胆碱能神经支配的三个来源:足部被盖核 (PPT)、侧背被盖核 (LDT) 和外侧副神经细胞核 (LPGi)。然后,我们使用 Cre 依赖性标记正常听力 ChAT-Cre 小鼠的胆碱能神经元,选择性标记从每个胆碱能源投射到 IC 的胆碱能投射。对来自 PPT 和 LDT 的胆碱能投射进行标记后发现,胆碱能轴突和突触终止于整个 IC,同侧投射更为密集。电子显微镜检查显示,这些胆碱能轴突可与 IC 神经元形成传统的突触连接。在另一项实验中,对来自 LPGi 的胆碱能投射进行选择性标记,发现了通向 IC 的双侧投射。LPGi 轴突在同侧和对侧表现出相对相等的密度,但两侧轴突的末端都主要局限于 IC 的非软骨区(即背侧皮层、外侧皮层和室间隔膜)。我们首先得出结论,胆碱能轴突可以在集成电路中形成传统的突触。此外,集成电路的半球和非半球区域接受不同模式的胆碱能神经支配。半月板 IC(IC 中央核)受 PPT 和 LDT 中胆碱能神经元的支配,而 IC 的非半月板 "外壳 "区域则受 PPT 和 LDT 以及 LPGi 中胆碱能神经元的支配。数据提供:可应要求提供数据。
Differential cholinergic innervation of lemniscal versus non-lemniscal regions of the inferior colliculus
The inferior colliculus (IC), a midbrain hub for integration of auditory information, receives dense cholinergic input that could modulate nearly all aspects of hearing. A key step in understanding cholinergic modulation is to identify the source(s) and termination patterns of cholinergic input. These issues have not been addressed for the IC in mice, an increasingly important model for study of hearing. We examined cholinergic inputs to the IC in adult male and female mice. We used retrograde tracing and immunochemistry to identify three sources of cholinergic innervation of the mouse IC: the pedunculopontine tegmental nucleus (PPT), the laterodorsal tegmental nucleus (LDT) and the lateral paragigantocellular nucleus (LPGi). We then used Cre-dependent labeling of cholinergic neurons in normal-hearing ChAT-Cre mice to selectively label the cholinergic projections to the IC from each of the cholinergic sources. Labeling of cholinergic projections from the PPT and LDT revealed cholinergic axons and boutons terminating throughout the IC, with the ipsilateral projection being denser. Electron microscopic examination showed that these cholinergic axons can form traditional synaptic junctions with IC neurons. In separate experiments, selective labeling of cholinergic projections from the LPGi revealed bilateral projections to the IC. The LPGi axons exhibited relatively equal densities on ipsilateral and contralateral sides, but on both sides the terminations were largely restricted to the non-lemniscal regions of the IC (i.e., the dorsal cortex, lateral cortex and intercollicular tegmentum). We conclude first that cholinergic axons can form traditional synapses in the IC. In addition, lemniscal and non-lemniscal regions of the IC receive different patterns of cholinergic innervation. The lemniscal IC (IC central nucleus) is innervated by cholinergic neurons in the PPT and the LDT whereas the non-lemniscal “shell” areas of the IC are innervated by the PPT and LDT and by cholinergic neurons in the LPGi.
期刊介绍:
The Journal of Chemical Neuroanatomy publishes scientific reports relating the functional and biochemical aspects of the nervous system with its microanatomical organization. The scope of the journal concentrates on reports which combine microanatomical, biochemical, pharmacological and behavioural approaches.
Papers should offer original data correlating the morphology of the nervous system (the brain and spinal cord in particular) with its biochemistry. The Journal of Chemical Neuroanatomy is particularly interested in publishing important studies performed with up-to-date methodology utilizing sensitive chemical microassays, hybridoma technology, immunocytochemistry, in situ hybridization and receptor radioautography, to name a few examples.
The Journal of Chemical Neuroanatomy is the natural vehicle for integrated studies utilizing these approaches. The articles will be selected by the editorial board and invited reviewers on the basis of their excellence and potential contribution to this field of neurosciences. Both in vivo and in vitro integrated studies in chemical neuroanatomy are appropriate subjects of interest to the journal. These studies should relate only to vertebrate species with particular emphasis on the mammalian and primate nervous systems.
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