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弱电鱼Apteronotus行为调节过程中起搏器控制的动力学和刺激依赖性

Dynamics and stimulus-dependence of pacemaker control during behavioral modulations in the weakly electric fish, Apteronotus.

作者信息

Dye J

出版信息

J Comp Physiol A. 1987 Aug;161(2):175-85. doi: 10.1007/BF00615239.

DOI:10.1007/BF00615239
PMID:3625571
Abstract
  1. Weakly electric fish generate around their bodies low-amplitude, AC electric fields which are used both for the detection of objects and intraspecific communication. The types of modulation in this signal of which the high-frequency wave-type gymnotiform, Apteronotus, is capable are relatively few and stereotyped. Chief among these is the chirp, a signal used in courtship and agonistic displays. Chirps are brief and rapid accelerations in the normally highly regular electric organ discharge (EOD) frequency. 2. Chirping can be elicited artificially in these animals by the use of a stimulus regime identical to that typically used to elicit another behavior, the jamming avoidance response (JAR). The neuronal basis for the JAR, a much slower and lesser alteration in EOD frequency, is well understood. Examination of the stimulus features which induce chirping show that, like the JAR, there is a region of frequency differences between the fish's EOD and the interfering signal that maximally elicits the response. Moreover, the response is sex-specific with regard to the sign of the frequency difference, with females chirping preferentially on the positive and most males on the negative Df. These features imply that the sensory mechanisms involved in the triggering of these communicatory behaviors are fundamentally similar to those explicated for the JAR. 3. Additionally, two other modulatory behaviors of unknown significance are described. The first is a non-selective rise in EOD frequency associated with a JAR stimulus, occurring regardless of the sign of the Df. This modulation shares many characteristics with the JAR. The second behavior, which we have termed a 'yodel', is distinct from and kinetically intermediate to chirping and the JAR. Moreover, unlike the other studied electromotor behaviors it is generally produced only after the termination of the eliciting stimulus.
摘要
  1. 弱电鱼在其身体周围产生低振幅的交流电场,这些电场用于探测物体和种内通讯。高频波形裸背电鳗科的线翎电鳗能够产生的这种信号的调制类型相对较少且较为刻板。其中主要的是啁啾声,这是一种用于求偶和争斗展示的信号。啁啾声是在通常高度规则的电器官放电(EOD)频率中短暂而快速的加速。2. 通过使用与通常用于引发另一种行为——干扰回避反应(JAR)相同的刺激方案,可以在这些动物中人工诱发啁啾声。JAR的神经元基础,即EOD频率中慢得多且较小的变化,已得到充分理解。对诱发啁啾声的刺激特征的研究表明,与JAR一样,在鱼的EOD和干扰信号之间存在一个频率差异区域,该区域能最大程度地引发反应。此外,就频率差异的符号而言,该反应具有性别特异性,雌性在正的频率差异时优先发出啁啾声,而大多数雄性在负的频率差异时发出。这些特征表明,引发这些通讯行为所涉及 的感觉机制与为JAR所阐述的机制基本相似。3. 此外,还描述了另外两种意义不明的调制行为。第一种是与JAR刺激相关的EOD频率的非选择性升高,无论频率差异的符号如何都会发生。这种调制与JAR有许多共同特征。第二种行为,我们称之为“约德尔唱法”,与啁啾声和JAR不同,在动力学上介于两者之间。此外,与其他研究的电运动行为不同,它通常只在引发刺激终止后才产生。

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