蜜蜂下行神经元的光谱特性

利用生理细胞外记录方法研究了蜜蜂下行神经元的光谱敏感特性,不同波长的单色光刺激引起的给先反应和撤光反应的相对强度不同．分析了３７例下行神经元的光谱敏感特性,发现下行神经元有的是光谱宽带和多光谱性的,有的是光谱窄带,给光和撤光反应都具有不同的最敏感区。     

刺激大鼠杏仁外侧核对皮层A Ⅰ区ON-OFF神经元反应及调谐曲线的影响

在30只氨基甲酸乙酯麻醉的SD大鼠上记录神经元单位放电,观察短纯音诱发的皮层A Ⅰ区神经元ON-OFF反应的特性及电刺激杏仁外侧核(lateral amygdaloid nucleus,LA)对ON-OFF反应以及调谐曲线的影响.实验证实,A Ⅰ区神经元ON-OFF反应的模式与纯音刺激的强度、频率及作用时程有关;刺激LA可以抑制ON-OFF反应的放电频数,使反应的阈值升高,或使反应放电构型发生变化;此外,刺激LA能使ON-OFF神经元的调谐曲线变窄,Q10数值增大.研究结果不仅表明ON-OFF神经元能对纯音刺激的时程、强度和频率等多种信息进行编码,而且还证明杏仁外侧核可以在皮层水平参与听觉信息的调制,削弱或衰减某些听觉信息,导致整个调谐曲线上移变窄,从而提高A Ⅰ区ON-OFF神经元的频率选择性能,有利于检测外界嘈杂环境中特定的听觉信息.     

刺激大鼠杏仁外侧核对皮层AⅠ区ON-OFF神经元反应及调谐曲线的影响

在30只氨基甲酸乙酯麻醉的SD大鼠上记录神经元单位放电,观察短纯音诱发的皮层AI区神经元ON－OFF反应的特性及电刺激杏仁外侧核（lateral amygdaloid nucleus,LA)对ON－OFF反应以及调谐曲线的影响。实验证实,AI区神经元ON－OFF反应的模式与纯音刺激的强度、频率及作用时程有关;刺激LA可以抑制ON－OFF反应的放电频数,使反应的阈值升高,或使反应放电构型发生变化;此外,刺激LA能使ON－OFF神经元的调谐曲线变窄,Q10数值增大。研究结果不仅表明ON－OFF神经元能对纯音刺激的时程、强度和频率等多种信息进行编码,而且还证明杏仁外侧核可以在皮层水平参与听觉信息的调制,削弱或衰减某些听觉信息,导致整个调谐曲线上移变窄,从而提高AI区ON－OFF神经元的频率选择性能,有利于检测外界嘈杂环境中特定的听觉信息。     

植物向光反应研究进展（综述）

向光反应在植物早期发育过程中具有重要的作用,是植物器官适用环境、向有利方向生长的一种良好生物学特性。本文综述近年来植物向光反应研究方面的进展：（1）植物内部组织感受Pfr梯度引起生长再分布,越来越多的证据支持Bruinsma-Hasagawa假说;（2）光强－反应曲线的研究表明,向光反应存在多种反应类型,其中第一次正向光弯曲和第二次正向光弯曲最为普遍;（3）已鉴定了几种参与向光反应的光受体;（4）通过拟南芥突变体的研究确定了影响向光反应的4个基因。     

华虻小叶神经元运动敏感性的研究

用电生理细胞内记录的方法记录了１０个以上小叶神经元对闪光、运动光斑及运动光栅刺激的电生理反应特点,结果表明：（１）小叶神经元对闪光刺激具有特征性反应,细胞对给光和撤光刺激都会表现出不同程度的去极化和超极化,反应的波形不随闪光时间的改变而改变,两次去极化之间的时间间隔与闪光刺激的时间长度成线性关系;（２）小叶神经元对运动光斑的运动速度非常敏感,而对光斑的运动方向的改变却不敏感,尽管有的细胞存在一个能使反应的变化更快的优势方向,但并没有明显的运动方向选择性;（３）小叶神经元对运动光栅的响应频率受光栅的空间频率和运动速度的双重调制,与光栅的运动方向无关。     

刺激家兔扣带回前部对丘脑腹后外侧核痛敏神经元放电的作用

131只家兔在三碘季铵酚麻痹下,用玻璃微电极在腹后外侧核(VPL)记录对伤害性刺激有反应的单位。在786个 VPL 单位中,对伤害性刺激有反应的单位共128个,占总数16.3%.其中116今对伤害性刺激呈兴奋效应,占90.6%。其余12个呈抑制效应,占9.4%。静脉注射吗啡可以取消这些神经元对伤害性刺激的放电反应。78次的测试结果表明扣带回前部的刺激可以抑制32%VPL 神经元的自发放电活动。同样,也可以抑制由于伤害性刺激而引起的 VPL 神经元的放电反应。这种抑制程度和扣带回的刺激频率有关;8Hz 的刺激频率所引起的抑制效应最佳。上述实验结果说明,扣带回可以通过其下行纤维的活动;影响伤害性冲动在丘脑 VPL水平上的传递。     

电刺激大鼠扣带前回对血压和心率的影响

电刺激大鼠扣带前回(ACg),血压升高,心率加快,同时缰核(Hb)内20.7％的神经元兴奋,22.4％的神经元抑制,56.9％的神经元无反应。双侧Hb内微量注射盐酸利多卡因,可明显阻断电刺激ACg引起的心血管反应。结果表明,ACg对心血管活动的调节,一部分是通过改变Hb的活动来实现的,Hb是ACg调节心血管活动的下行性通路之一。     

不同光波及光强度下棉铃虫(Helicoverpa armigera)成虫的行为反应

运用室内行为实验方法研究了不同波长单色光和白光刺激的棉铃虫[Helicoverpa armigera (Hübner)]成虫趋光、避光反应及其与光强度之间的相互关系.结果显示:(1)一定时间暗适应的棉铃虫蛾对单色光和白光刺激均具有趋光行为反应,依其趋光反应率大小,其光谱反应曲线在340-605nm波谱范围内,表现为大小较复杂的几个峰,其中两个峰分别在蓝光区483nm、紫外340nm,另在近紫外的400nm、绿黄光区的538nm有峰.(2)一定光强度范围内,棉铃虫蛾的趋光反应率随单色光和白光光强度的增强而增大,至一定光强度时增加变缓,呈现近似S型曲线式样.(3)性别、日龄对棉铃虫蛾的光谱、光强度反应曲线均有一定影响,雌性较雄性的趋光反应率和可适应的光强度高,1、3、5日龄蛾中以3日龄的趋光反应率和可适应的光强度高.(4)棉铃虫蛾的趋光、避光反应行为具有相似的波长及光强度选择机制.     

棉铃虫成虫复眼的光谱敏感性及超极化后电位的研究

采用胞内记录方法研究了雄性棉铃虫小网膜细胞对光刺激的反应特性。结果如下：（１）小网膜细胞对５６２ｎｍ的光最敏感,另外对４００ｎｍ、４８３ｎｍ光也较敏感;（２）对这三种敏感光的光强度反应曲线（Ｖ／ＬｏｇＩｃｕｒｖｅ）与对白光的类似,在一定范围内,随光强度的增加反应增大,呈近似“Ｓ”形曲线;（３）超极化后电位的幅值随闪光刺激强度的增大、刺激时程的延长、对刺激光的敏感程度的增加而增大;（４）感受器的去极化电位与超极化后电位的比值不受刺激强度及光谱的影响,但随闪光刺激时程的延长而逐渐减小。     

噪声和二硫化碳对大鼠外膝体神经元光反应的影响及其联合效应

目的：观察噪声或二硫化碳（CS2）暴露对大鼠外侧膝状体（LGB）神经元光反应的影响及二者的联合效应。方法：脉冲噪声刺激和光栅刺激由计算机控制输出,CS2通过皮下注射,运用电生理学方法记录LGB神经元电活动。结果：噪声暴露后有21％的神经元光反应被抑制,当噪声持续时,抑制程度有增强的趋势,呈现出剂量效应关系。不同剂量的CS2暴露,神经元受到不同程度的抑制,亦呈剂量一效应关系。噪声和CS2同时作用时,呈一定的协同作用。结论：噪声或者CS2的单独作用可明显抑制外膝体神经元的光反应,在共同作用时存在联合效应,主要表现为协同效应。     

Effects of leg movements on the synaptic activity of descending statocyst interneurons in crayfish,Procambarus clarkii

Crustacean postural control is modulated by behavioral condition. In this study, we investigated how the responses of descending statocyst interneurons were affected during leg movements. Intracellular recording was made from an animal whose statoliths had been replaced with ferrite grains so that statocyst receptors could be activated by magnetic field stimulation. We identified 14 morphological types of statocyst-driven descending interneurons. Statocyst-driven descending interneurons always showed an excitatory response to statocyst stimulation on either ipsilateral or contralateral side to the axon. The response of each statocyst-driven descending interneuron to statocyst stimulation was differently modulated by leg movements in different conditions. During active leg movements, six statocyst-driven descending interneurons were activated regardless of whether a substrate was provided or not. In other two statocyst-driven descending interneurons, the excitatory input during leg movements was stronger when a substrate was provided than when it was not. One statocyst-driven descending interneuron received an excitatory input only during leg movements on a substrate, whereas another statocyst-driven descending interneuron did not receive any input during leg movements both on a substrate and in the air. These results suggest that the descending statocyst pathways are organized in parallel, each cell affected differently by behavioral conditions.Abbreviations EMG electromyogram - NGI nonspiking giant interneuron - SDI statocyst-driven descending interneuron     

Physiological and morphological characterization of olfactory descending interneurons of the male silkworm moth, Bombyx mori

In order to understand the neural mechanisms of pheromone-oriented walking in male silkworm moths, Bombyxmori, we have characterized olfactory responses and three-dimensional structure of two clusters (Group-I, Group-II) of descending interneurons in the brain by intracellular recording and staining with lucifer yellow. Neurons were imaged with laser-scanning confocal microscopy. Group-I and Group-II descending interneurons were classified into three morphological types, respectively. In response to the sex pheromone, bombykol, Type-A Group-I descending interneurons showed characteristic flipflopping activity. The Group-I descending interneurons had dendritic arborizations in the lateral accessory lobe and varicose profiles in the posterior-lateral part of the suboesophageal ganglion where the dendritic arborizations of a neck motor neuron (i.e., cv1 NMN) reside. Other types of Group-I descending interneurons exhibited long-lasting suppression of firing. The pheromonal responses of Group-II descending interneurons fell into two classes: brief excitation and brief inhibition. Type-A Group-II descending interneurons showing brief excitation had blebby processes in the posterior-lateral part of the suboesophageal ganglion. Type-B and Type-C Group-II descending interneurons did not have varicose profiles there. Therefore, the neck motor neuron regulating head turning, which accompanies the pheromone-oriented walking, may be controlled by these two types, flipflop and phasic excitation, of descending activity patterns. Accepted: 2 November 1998     

Sensitivity of ocellar interneurons of the honeybee to constant and temporally modulated light

Sinusoidally modulated and discrete light pulses, the parameters of which approximated natural light conditions, were used to determine the response characteristics of ocellar first-order interneurons of the worker honeybee (Apis mellifera carnica). Large ocellar interneurons which terminate within the brain (LB neurons) were recorded from intracellularly and were identified visually after dye injection. Absolute sensitivity of LB neurons to light flashes ranges from 4 X 10(9) quanta/cm2s (Q) for MOC1,7 neurons to 1 X 10(12) Q for MOC3,4. The slope of the response-intensity (R/I) functions, which were calculated for intensities between 2 X 10(9) and 4 X 10(13) Q, varies in different types of LB neurons. The strongest response is given by one group of median ocellar neurons. With constant light around 10(13) Q, most LB neurons exhibit oscillatory hyperpolarizations which, upon increasing the stimulus to even higher intensities (10(14)-10(15) Q), gradually evolve to a hyperpolarized plateau. The frequency of these oscillatory voltage fluctuations increases with the rate of modulation of the stimulating light and reaches maximum values at 5-15 Hz modulation frequency. Two groups of MOC neurons follow sinusoidally modulated light up to 32 +/- 8 Hz (n = 5) and 29 +/- 6 Hz (n = 3), respectively, whereas lateral ocellar neurons cut off at 17 +/- 5 Hz (n = 4). The possible role of LB neurons is discussed. They may be inactivated when the bee is flying in bright sunlight.     

Descending pathways connecting the male-specific visual system of flies to the neck and flight motor

Summary During sexual pursuit, male flies Sarcophaga bullata, stabilize the image of a pursued target on the dorso-frontal acute zone of their compound eyes. By retinotopic projection, this region is represented in the upper frontal part of the lobula where it is sampled by ensembles of male-specific motion- and flicker-sensitive interneurons. Intracellular recordings of descending neurons, followed by biocytin injection, demonstrate that male-specific neurons are dye-coupled to specific descending neurons and that the response characteristics of these descending neurons closely resemble those of male-specific lobula neurons. Such descending neurons are biocytin-coupled in the thoracic ganglia, revealing their connections with ipsilateral frontal nerve motor neurons supplying muscles that move the head and with contralateral basalar muscle motor neurons that control wing beat amplitude. Recordings from neck muscle motor neurons demonstrate that although they respond to movement of panoramic motion, they also selectively respond to movement of small targets presented to the male-specific acute zone. The present results are discussed with respect to anatomical and physiological studies of sex-specific interneurons and with respect to sex-specific visual behavior. The present study, and those of the two preceding papers, provide a revision of Land and Collett's hypothetical circuit underlying target localization and motor control in males pursuing females.     

Morphology of descending statocyst interneurons in the crayfish Procambarus clarkii Girard

Summary The morphological features of descending interneurons that responded to the artificial bending of statolith hairs were assessed with intracellular recording and staining techniques. Seven statocyst interneurons were identified on the basis of their structure and response characteristics and designated as interneurons S1 to S7. All seven identified interneurons project to the optic lobe, where the optic nerve also projects, and to the dorsal part of the tritocerebrum, where the eyestalk motoneurons originate. All except interneuron S6 also extend their major branches to other neuropilar regions. S2 projects to the dorsal part of the deutocerebrum, where the statocyst nerve terminates, and S3 to the dorsal part of deutocerebrum and the antennal lobe. Four other interneurons (S1, S4, S5, S7) also extend their branches to the parolfactory lobe to which the statocyst nerve projects as well as to the deutocerebrum and antennal lobe. The extensive dendritic projections of S1–S7 suggest that they are complex multimodal interneurons rather than simple relay interneurons, receiving at least visual and statocyst sensory information. The function of the antennal lobe branches, however, has yet to be determined since the functional role of antennal input in equilibrium control is unknown.     

Response of thoracic interneurons to tactile stimulation in the cockroach,Periplaneta americana

Receåfindings indicate that cockroaches escape in response to tactile stimulation as well as they do in response to the classic wind puff stimulus. The thoracic interneurons that receive inputs from ventral giant interneurons also respond to tactile stimulation and therefore, represent a potential site of convergence between wind and tactile stimulation as well as other sensory modalities. In this article, we characterize the tactile response of these interneurons, which are referred to as type-A thoracic interneurons (TI_As). In response to tactile stimulation of the body cuticle, TI_As typically respond with a short latency biphasic depolarization which often passes threshold for action potentials. The biphasic response is not typical of responses to wind stimulation nor of tactile stimulation of the antennae. It is also not seen in tactile responses of thoracic interneurons that are not part of the TI_A group. The responses of individual TI_As to stimulation of various body locations were mapped. The left-right directional properties of TI_As are consistent with their responses to wind puffs from various different directions. Cells that respond equally well to wind from the left and right side also respond equally well to tactile stimuli on the left and right side of the animal's body. In contrast, cells that are biased to wind on one side are also biased to tactile stimulation on the same side. In general, tactile responses directed at body cuticle are phasic rather than tonic, occurring both when the tactile stimulator is depressed and released. The response reflects stimulus strength and follows repeated stimulation quite well. However, the first phase of the biphasic response is more robust during high-frequency stimulation than the second phase. TI_As also respond to antennal stimulation. However, here the response characteristics are complicated by the fact that movement of either antenna evokes descending activity in both left and right thoracic connectives. The data suggest that the TI_As make up a multimodal site of sensory convergence that is capable of generating an oriental escape turn in response to any one of several sensory cues. 1994 John Wiley & Sons, Inc.     

Quantitative analysis of inputs to somatostatin-immunoreactive descending interneurons in the myenteric plexus of the guinea-pig small intestine

Somatostatin immunoreactivity occurs in a specific subgroup of cholinergic descending interneurons in the myenteric plexus of the guinea-pig small intestine. In the present work, we made light- and electron-microscopic investigations of chemically defined inputs to these neurons, in order that the origins of the connections of other neurons with them could be deduced. Somatostatin-immunoreactive synapses and close contacts were found on the cell bodies and filamentous processes of somatostatin neurons; these were 84% of all inputs. It is thus confirmed that this class of interneuron forms chains that project anally. Descending interneurons with immunoreactivity for nitric oxide synthase provided 14% of inputs to somatostatin-immunoreactive descending interneurons. An antiserum against a calcium-binding protein, calbindin, was used as marker for the majority of intrinsic primary afferent neurons, AH/Dogiel type II neurons; this class of neurons provided only 2.5% of the inputs to somatostatin-immunoreactive descending interneurons. We conclude that somatostatin-immunoreactive descending interneurons are involved in the conduction of impulses distally along the full length of the small intestine, but receive only a minor input from calbindin-immunoreactive primary afferent neurons.     

Constancies in the neuronal architecture of the suboesophageal ganglion at metamorphosis in the beetleTenebrio molitor L.

Summary Topological organization of identified neurons has been characterized for the larval, pupal and imaginal suboeosphageal neuropil of the meal-worm beetleTenebrio molitor. Neuronal fate mapping allows identification of individually persisting neurons in the metamorphosing suboesophageal ganglion ofTenebrio. Analysis was performed on interneurons characterized by serotonin and CCAP (crustacean cardioactive peptide) immunohistochemistry, on motoneurons that innervate the dorsal and ventral longitudinal muscles, and on suboesophageal descending neurons. All these different populations of neurons show topologically invariant features throughout metamorphosis. Motoneurons, interneurons, and descending suboesophageal neurons of the imaginal suboeosphageal ganglion embody individually persisting larval interneurons. Impacts for a functional interpretation of the neuronal architecture of the suboesophageal ganglion are discussed.     

Transmission of descending activity evoked by prolonged stimulation of the pyramids and red nucleus by groups of spinal interneurons

Responses of two groups of spinal interneurons to prolonged stimulation of the medullary pyramids and the red nucleus by repetitive and random sequences of stimuli were investigated in cats anesthetized with pentobarbital. Interneurons specialized for transmission of descending, but not peripheral, effects were excited by impulses from both higher structures; the evoked activity was stable and stationary in character in response to stimulation within the range from 20–30 to 75–100/sec. The response of interneurons activated by flexor reflex afferents was more complex and, as a rule, it was not stationary. Prolonged pyramidal stimulation led to an increase in the mean spontaneous firing rate, while stimulation of the red nucleus inhibited spontaneous activity. Statistical analysis of the records of unit activity on the "Dnepr'-1" computer was used to study some possible mechanisms of the transformation of activity in the lateral descending systems by these groups of interneurons.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 5, No. 6, pp. 644–653, November–December, 1973.