Neural responses to bitter compounds in rats

IF 2.6 4区医学 Q3 NEUROSCIENCES Brain Research Pub Date : 1997-05-09 DOI:10.1016/S0006-8993(97)00131-5

M Dahl , R.P Erickson , S.A Simon

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引用次数: 124

Abstract

To determine whether the idiosyncratic distribution of transduction mechanisms for bitter tastants in rat taste receptor cells (TRCs) could be inferred from the neural activity they evoke, single neuron responses to ten bitter-tasting compounds were recorded from rat glossopharyngeal (n=30) and chorda tympani (n=22) neurons. Responses to several `bitter' alkaloids were obtained: 10 mM quinine-HCl, 50 mM caffeine, and 1 mM each nicotine, yohimbine, and strychnine, plus a number of non-alkaloid bitter-tasting compounds: 0.1 M KCl, 0.01 M MgCl₂, and 1 mM each phenylthiocarbamide (PTC), l-tyrosine, and denatonium benzoate. To obtain some distinctions with other stimuli NaCl (0.1 M), HCl (pH 2.0), and capsaicin (10 μM) were also tested. It was found that individual neurons in both glossopharyngeal and chorda tympani nerves differed in their relative sensitivities to the various bitter stimuli. To determine relationships among these stimuli, the differences in the evoked responses between each stimulus pair were summarized in a multi-dimensional scaling space. In these analyses neither nerve showed any obvious similarity between the placements of quinine and the other bitter stimuli. Such data suggest that first-order gustatory neurons can discriminate among the above bitter stimuli. For glossopharyngeal neurons, some similarity to quinine was found only for nicotine and denatonium, and for chorda tympani neurons, some similarity to quinine was found only for KCl and MgCl₂. Of the bitter compounds tested, quinine evoked the greatest response from glossopharyngeal neurons. We propose this arises because quinine can activate TRCs by more transduction mechanisms than other bitter stimuli. The results from these studies were summarized in a qualitative model for the coding of bitter tastants where the variety of transduction mechanisms for bitters are distributed among various TRCs to account for the heterogeneous responses among the neurons. © 1997 Elsevier Science B.V. All rights reserved.

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老鼠对苦味化合物的神经反应

为了确定苦味物质在大鼠味觉受体细胞(TRCs)中传导机制的特异性分布是否可以从它们所引起的神经活动中推断出来，我们从大鼠舌咽部(n=30)和鼓室索(n=22)神经元中记录了10种苦味物质的单个神经元反应。对几种“苦味”生物碱的反应是:奎宁hcl 10毫米，咖啡因50毫米，尼古丁、育亨宾和士的宁各1毫米，加上一些非生物碱苦味化合物:KCl 0.1毫米，MgCl2 0.01毫米，苯硫胺(PTC)、l-酪氨酸和苯甲酸地那铵各1毫米。为了获得与其他刺激物的区别，还测试了NaCl (0.1 M)、HCl (pH 2.0)和辣椒素(10 μM)。研究发现，舌咽神经和鼓室索神经的单个神经元对各种苦味刺激的相对敏感性不同。为了确定这些刺激之间的关系，在多维尺度空间中总结了每个刺激对之间的诱发反应差异。在这些分析中，没有神经显示出奎宁和其他苦味刺激的位置有任何明显的相似性。这些数据表明，一级味觉神经元可以区分上述苦味刺激。对于舌咽部神经元，只有尼古丁和地那铵与奎宁有一定的相似性;对于鼓室索神经元，只有KCl和MgCl2与奎宁有一定的相似性。在测试的苦味化合物中，奎宁引起舌咽部神经元的最大反应。我们认为这是因为奎宁可以通过比其他苦味刺激更多的转导机制激活TRCs。这些研究结果总结为苦味物质编码的定性模型，其中苦味的各种转导机制分布在不同的TRCs中，以解释神经元之间的异质性反应。©1997 Elsevier Science B.V.版权所有

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来源期刊

Brain Research 医学-神经科学

CiteScore

5.90

自引率

3.40%

发文量

268

审稿时长

47 days

期刊介绍： An international multidisciplinary journal devoted to fundamental research in the brain sciences. Brain Research publishes papers reporting interdisciplinary investigations of nervous system structure and function that are of general interest to the international community of neuroscientists. As is evident from the journals name, its scope is broad, ranging from cellular and molecular studies through systems neuroscience, cognition and disease. Invited reviews are also published; suggestions for and inquiries about potential reviews are welcomed. With the appearance of the final issue of the 2011 subscription, Vol. 67/1-2 (24 June 2011), Brain Research Reviews has ceased publication as a distinct journal separate from Brain Research. Review articles accepted for Brain Research are now published in that journal.