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蟋蟀大脑中的超声敏感神经元。

Ultrasound sensitive neurons in the cricket brain.

作者信息

Brodfuehrer P D, Hoy R R

机构信息

Section of Neurobiology and Behavior, Cornell University, Ithaca, NY 14853.

出版信息

J Comp Physiol A. 1990 Mar;166(5):651-62. doi: 10.1007/BF00240015.

DOI:10.1007/BF00240015
PMID:2341990
Abstract
  1. The aim of this study was to identify neurons in the brain of the cricket, Teleogryllus oceanicus, that are tuned to high frequencies and to determine if these neurons are involved in the pathway controlling negative phonotaxis. In this paper we describe, both morphologically and physiologically, 20 neurons in the cricket brain which are preferentially tuned to high frequencies. 2. These neurons can be divided into two morphological classes: descending brain interneurons (DBINs) which have a posteriorly projecting axon in the circumesophageal connective and local brain neurons (LBNs) whose processes reside entirely within the brain. All the DBINs and LBNs have processes which project into one common area of the brain, the ventral brain region at the border of the protocerebrum and deutocerebrum. Some of the terminal arborizations of Int-1, an ascending ultrasound sensitive interneuron which initiates negative phonotaxis, also extend into this region. 3. Physiologically, ultrasonic sound pulses produce 3 types of responses in the DBINs and LBNs. (1) Seven DBINs and 6 LBNs are excited by ultrasound. (2) Ongoing activity in one DBIN and 5 LBNs is inhibited by ultrasound, and (3) one cell, (LBN-ei), is either excited or inhibited by ultrasound depending on the direction of the stimulus. 4. Many of the response properties of both the DBINs and LBNs to auditory stimuli are similar to those of Int-1. Specifically, the strength of the response, either excitation or inhibition, to 20 kHz sound pulses increases with increasing stimulus intensity, while the response latency generally decreases. Moreover, the thresholds to high frequencies are much lower than to low frequencies. These observations suggest that the DBINs and LBNs receive a majority of their auditory input from Int-1. However, the response latencies and directional sensitivity of only LBN-ei suggest that it is directly connected to Int-1. 5. The response of only one identified brain neuron, DBIN8, which is inhibited by 20 kHz sound pulses, is facilitated during flight compared to its response at rest. This suggests that suppression of activity in DBIN8 may be associated with ultrasound-induced negative phonotactic steering responses in flying crickets. The other DBINs and LBNs identified in this paper may also play a role in negative phonotaxis, and possibly in other cricket auditory behaviors influenced by ultrasonic frequencies.
摘要
  1. 本研究的目的是在大洋洲黑蟋蟀的大脑中识别出对高频有调谐作用的神经元,并确定这些神经元是否参与控制负趋声性的通路。在本文中,我们从形态学和生理学角度描述了蟋蟀大脑中20个优先调谐到高频的神经元。2. 这些神经元可分为两种形态类型:下行脑中间神经元(DBINs),其轴突在围食管神经索中向后投射;以及局部脑神经元(LBNs),其突起完全位于脑内。所有的DBINs和LBNs都有突起投射到大脑的一个共同区域,即原脑和中脑边界处的腹侧脑区。启动负趋声性的上行超声敏感中间神经元Int-1的一些终末分支也延伸到这个区域。3. 在生理学上,超声脉冲在DBINs和LBNs中产生3种类型的反应。(1)7个DBINs和6个LBNs被超声兴奋。(2)一个DBIN和5个LBNs的持续活动被超声抑制,并且(3)一个细胞(LBN-ei)根据刺激方向被超声兴奋或抑制。4. DBINs和LBNs对听觉刺激的许多反应特性与Int-1相似。具体而言,对20kHz声脉冲的反应强度(兴奋或抑制)随刺激强度增加而增加,而反应潜伏期通常缩短。此外,对高频的阈值远低于对低频的阈值。这些观察结果表明,DBINs和LBNs的大部分听觉输入来自Int-1。然而,只有LBN-ei的反应潜伏期和方向敏感性表明它直接与Int-1相连。5. 与静息时的反应相比,在飞行过程中,仅一个已识别的脑神经元DBIN8(被20kHz声脉冲抑制)的反应得到促进。这表明DBIN8活性的抑制可能与飞行蟋蟀中超声诱导的负趋声性转向反应有关。本文中识别出的其他DBINs和LBNs也可能在负趋声性中发挥作用,并且可能在受超声频率影响的其他蟋蟀听觉行为中发挥作用。

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Proc Natl Acad Sci U S A. 1978 Aug;75(8):4052-6. doi: 10.1073/pnas.75.8.4052.
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Initiation of behavior by single neurons: the role of behavioral context.单个神经元引发行为:行为背景的作用。
Science. 1984 Nov 23;226(4677):992-4. doi: 10.1126/science.6505681.
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Brain interneurons in noctuid moths: differential suppression by high sound intensities.夜蛾的脑中间神经元:高声强的差异性抑制
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Neurobiology of acoustically mediated predator detection.声学介导的捕食者检测的神经生物学
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