Immunohistochemical characterization of nodose cough receptor neurons projecting to the trachea of guinea pigs.

Stuart B Mazzone, Alice E McGovern
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引用次数: 43

Abstract

Background: Cough in guinea pigs is mediated in part by capsaicin-insensitive low threshold mechanoreceptors (cough receptors). Functional studies suggest that cough receptors represent a homogeneous population of nodose ganglia-derived sensory neurons. In the present study we set out to characterize the neurochemical profile of cough receptor neurons in the nodose ganglia.

Methods: Nodose neurons projecting to the guinea pig trachea were retrogradely labeled with fluorogold and processed immunohistochemically for the expression of a variety of transporters (Na+/K+/2C1- co-transporter (NKCC1), alpha1 and alpha3 Na+/K+ ATPase, vesicular glutamate transporters (vGlut)1 and vGlut2), neurotransmitters (substance P, calcitonin gene-related peptide (CGRP), somatostatin, neuronal nitric oxide synthase (nNOS)) and cytosolic proteins (neurofilament, calretinin, calbindin, parvalbumin).

Results: Fluorogold labeled ~3 per cent of neurons in the nodose ganglia with an average somal perimeter of 137 +/- 6.2 mum (range 90-200 microm). All traced neurons (and seemingly all nodose neurons) were immunoreactive for NKCC1. Many (> 90 per cent) were also immunoreactive for vGlut2 and neurofilament and between 50 and 85 per cent expressed alpha1 ATPase, alpha3 ATPase or vGlut1. Cough receptor neurons that did not express the above markers could not be differentiated based on somal size, with the exception of neurofilament negative neurons which were significantly smaller (P < 0.05). Less than 10 per cent of fluorogold labeled neurons expressed substance P or CGRP (and these had somal perimeters less than 110 microm) and none expressed somatostatin, calretinin, calbindin or parvalbumin. Two distinct patterns of nNOS labeling was observed in the general population of nodose neurons: most neurons contained cytosolic clusters of moderately intense immunoreactivity whereas less than 10 per cent of neurons displayed uniform intensely fluorescent somal labeling. Less than 3 per cent of the retrogradely traced neurons were intensely fluorescent for nNOS (most showed clusters of nNOS immunoreactivity) and nNOS immunoreactivity was not expressed by cough receptor nerve terminals in the tracheal wall.

Conclusion: These data provide further insights into the neurochemistry of nodose cough receptors and suggest that despite their high degree of functional homogeneity, nodose cough receptors subtypes may eventually be distinguished based on neurochemical profile.

Abstract Image

Abstract Image

Abstract Image

豚鼠气管结节性咳嗽受体神经元的免疫组织化学特征。
背景:豚鼠的咳嗽在一定程度上是由辣椒素不敏感的低阈机械受体(咳嗽受体)介导的。功能研究表明,咳嗽受体代表了结节神经节来源的感觉神经元的同质群体。在目前的研究中,我们开始表征结节神经节中咳嗽受体神经元的神经化学特征。方法:用荧光金逆行标记豚鼠气管上的结状神经元,免疫组织化学处理多种转运蛋白(Na+/K+/2C1-共转运蛋白(NKCC1)、α 1和α 3、Na+/K+ atp酶、泡状谷氨酸转运蛋白(vGlut)1和vGlut2)、神经递质(P物质、降钙素基因相关肽(CGRP)、生长抑素、神经元一氧化氮合酶(nNOS))和胞质蛋白(神经丝、calretinin、calbindin、calbindin、nNOS)的表达。小清蛋白)。结果:结节神经节中约3%的神经元被氟金标记,平均染色体周长为137 +/- 6.2 μ m(范围90-200 μ m)。所有追踪到的神经元(似乎所有结节神经元)对NKCC1都有免疫反应。许多人(> 90%)对vGlut2和神经丝也有免疫反应,50%至85%的人表达alpha1 atp酶、alpha3 atp酶或vGlut1。不表达上述标记的咳嗽受体神经元不能根据染色体大小进行区分,但神经丝阴性神经元明显较小(P < 0.05)。不到10%的荧光金标记的神经元表达P物质或CGRP(这些神经元的染色体周长小于110微米),没有表达生长抑素、calretinin、calbindin或小白蛋白。在一般结节性神经元群体中观察到两种不同的nNOS标记模式:大多数神经元含有中等强度免疫反应性的胞浆簇,而不到10%的神经元显示均匀的强烈荧光染色体标记。不到3%的逆行追踪的神经元对nNOS有强烈的荧光反应(大多数显示nNOS的免疫反应性簇),并且气管壁的咳嗽受体神经末梢不表达nNOS的免疫反应性。结论:这些数据为结节性咳嗽受体的神经化学提供了进一步的见解,并表明尽管结节性咳嗽受体的功能高度同质,但最终可能根据神经化学特征来区分结节性咳嗽受体亚型。
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