Convergence of olfactory inputs from both antennae in the brain of the honeybee.

Electrical activities of the olfactory neurones in the brain of the honeybee were investigated. Odorous stimuli were given to each antenna separately or to both simultaneously. The inputs from the antennae affected both the impulse frequency and the latency of the olfactory interneurones in the protocerebrum. The predominant response was to the stimulation of the ipsilateral antenna. Input from the contralateral antenna produced mainly excitatory effects, although a few inputs gave inhibitory effects. No particular relationships between the loci of the units in the brain and the types of responses produced were found. Most of the units were located in the protocerebral lobe and in the central commissure. The units in the deutocerebrum responded only to the stimulation of the ipsilateral antenna, and the magnitude of response and the latency were not different with respect to unilateral or bilateral stimulation of the antennae. Differences in latency between unilateral and bilateral stimulation were observed in some of the units in the protocerebrum. Neural models which explain these phenomena are postulated.     

Physiological properties and response modulations of mushroom body feedback neurons during olfactory learning in the honeybee, Apis mellifera

Mushroom bodies are central brain structures and essentially involved in insect olfactory learning. Within the mushroom bodies γ-aminobutyric acid (GABA)-immunoreactive feedback neurons are the most prominent neuron group. The plasticity of inhibitory neural activity within the mushroom body was investigated by analyzing modulations of odor responses of feedback neurons during olfactory learning in vivo. In the honeybee, Apis mellifera, feedback neurons were intracellularly recorded at their neurites. They produced complex patterns of action potentials without experimental stimulation. Summating postsynaptic potentials indicate that their synaptic input region lies within the lobes. Odor and antennal sucrose stimuli evoked excitatory phasic-tonic responses. Individual neurons responded to various odors; responses of different neurons to the same odor were highly variable. Response modulations were determined by comparing odor responses of feedback neurons before and after one-trial olfactory conditioning or sensitisation. Shortly after pairing an odor stimulus with a sucrose reward, odor-induced spike activity of feedback neurons decreased. Repeated odor stimulations alone, equally spaced as in the conditioning experiment, did not affect the odor-induced excitation. A single sensitisation trial also did not alter odor responses. These findings indicate that the level of odor-induced inhibition within the mushroom bodies is specifically modulated by experience. Accepted: 9 September 1999     

Processing of antennal information in extrinsic mushroom body neurons of the bee brain

Summary In the bee brain neural activity of interneurons of the inner antenno-cerebral tract (inputs to the mushroom body) and extrinsic neurons of the-lobe (output cells) was recorded intracellularly. The cells were stained with Lucifer Yellow. The response characteristics of the neurons to light, various antennal stimuli and mechanical stimuli to thorax and abdomen were studied.The cells of the inner antenno-cerebral tract (ACT) have uniglomerular dendritic arborizations in the antennal lobe and send projections into the calyces of the ipsilateral mushroom body and the lateral protocerebral lobe. 93% of the neurons are bi- or multimodal. No responses to light stimuli were found. Tactile stimuli to the antennae are only effective when applied ipsilaterally. Only one neuron showed marked differences in the responses to the qualitative testing of three odors: rose, lavender and isoamyl acetate.The cells can be classified according to their response characteristics; the following response types were found: (1) inhibitory responses to the stimuli, (2) inhibitory responses to olfactory and excitatory responses to mechanical stimuli or vice versa, (3) excitatory responses to mechanical and sugar water stimuli, (4) excitation to olfactory stimuli and to touching the antenna with a drop of water or sugar water, (5) excitation to mechanical stimuli to head, thorax and abdomen and inhibition to sugar water stimuli.The recorded extrinsic-lobe neurons have small dendritic bands perpendicular to the Kenyon cells, their axons project to the contralateral median protocerebrum. These cells have ipsilateral antennal and mostly ipsilateral optic inputs and process information from thoracic and abdominal mechanoreceptors. All responses are excitatory.The recordings suggest that the mushroom bodies are multimodal integration centers, where antennal information is first combined with visual inputs.Abbreviation ACT antenno-cerebral tract     

Participation of interoceptive afferent impulses in polymodal responses of superior collicular neurons in the cat

Experiments on immobilized, unanesthetized cats showed that interoceptive afferent impulses reaching the brain via the vagus nerves evoke marked responses in, on average, 43% of superior collicular neurons. Both excitatory and inhibitory effects were observed. The latter were found more often during single stimulation of the vagus nerve. In half of the cases the inhibitory responses were characterized by the development of initial inhibition, clearly limited in time to between 180 and 1700 msec. Changes in spike activity of 60% of units were tonic in character. The onset of phasic responses with an initial period of activation was observed in only 9–11% of neurons. The number of these cells and also the total number of responding neurons were greater than when series of stimuli were applied to the vagus nerve. In individual cells during prolonged repetitive stimulation of the nerve gradual weakening of the responses took place. Somatic stimulation evoked mainly the development of phasic responses of excitatory type. Most of the neurons tested were bimodal and often the temporal structure of their responses was determined by the modality of the stimulus applied. The functional role of the changes discovered in spontaneous activity of superior collicular neurons under interoceptive influences and the central mechanisms of realization of such influences on the activity of the neuronal system in this brain structure are discussed.Ivano-Frankovsk Medical Institute, Ministry of Health of the Ukrainian SSR. Translated from Neirofiziologiya, Vol. 10, No. 6, pp. 590–596, November–December, 1978.     

嗅球僧帽细胞具有编码气味空间信息的能力

刺激源的方位是刺激的重要特性之一.行为学的研究发现,动物能够利用气味到达左右鼻腔的时间差和强度差信息对气味方位进行感知,但作为嗅觉系统第一神经中枢的嗅球,是否具有利用两侧鼻间差信息对气味方位进行编码的能力一直受到质疑.为探讨该问题,在本研究中通过比较嗅球中84个僧帽细胞对同侧气味刺激、对侧气味刺激以及对侧气味刺激略先于同侧气味刺激时的反应,发现有29个僧帽细胞可被同侧气味所兴奋,其中18个虽然对对侧气味刺激不反应,但对侧气味的存在却能显著降低其对同侧气味刺激的反应.另外,50个僧帽细胞在只给予同侧或对侧气味刺激时不反应,但其中11个在对侧刺激略先于同侧刺激的方式给出气味时,表现出明显的兴奋性反应.我们的研究结果一方面提示僧帽细胞具有编码气味到达两个鼻腔的时间差,或气味源位置信息的能力;另一方面也表明对侧刺激不仅能对同侧嗅球僧帽细胞产生抑制效应,还可能存在目前还不明确的机制而产生兴奋效应.     

Cerebellar cortical activity during stretch of antagonist muscles

Single unit activity was recorded from the anterior lobe of the cerebellum during ramp and hold stretches of limb muscles in chloralose anesthetized cats. The activity of 95 "phasic" units showed a transient response during dynamic stretch of at least one muscle usually lasting for less than 350 ms following the stimulus onset. The activity of 59 phasic-tonic units was modified not only during dynamic stretch but also during the 1 s of maintained muscle length. All Purkinje cells, identified by their complex spikes, that responded to muscle stretch demonstrated exclusively phasic changes in discharge. Fourteen of 25 Purkinje cells (56%) responded to stretch of both antagonist muscles and these responses were always similar rather than reciprocal. From the 129 units without complex spikes, 70 demonstrated phasic discharge patterns whereas 59 had tonic responses. Seventy-five (59%) of these unidentified units revealed convergent responses to stretch of both antagonists, compared with 54 which responded to stretch of one muscle only. Of the unidentified units receiving convergent afferents from antagonist muscles, 62 (83%) had similar responses and only 13 (17%) had reciprocal reactions. There appeared to be no evidence that muscle afferents alone can induce reciprocal discharge patterns in Purkinje neurons of the cerebellar cortex. The firing frequency of some phasic-tonic units was correlated with both the velocity and amplitude of muscle stretch. No Purkinje cells were found with activity related to either velocity or amplitude of muscle stretch. One phasic and seven phasic-tonic unidentified units were activated at fixed latencies following trains of electrical stimulation applied to the thoracic spinal cord at frequencies exceeding 200 Hz, implying they were terminal portions of mossy fibers originating from direct spinocerebellar tracts. A few recordings of compound potentials were presumed to arise from the cerebellar glomeruli. The changing form of one of these potentials suggested that the glomerulus might be a site at which somatosensory peripheral information is modified by the cerebellar cortex.     

Maxillary palps are broad spectrum odorant detectors in Culex quinquefasciatus

A single type of olfactory sensilla on maxillary palps in many species of mosquitoes houses a very sensitive olfactory receptor neuron (ORN) for carbon dioxide reception. We performed extensive single sensillum recordings from this peg sensillum in Culex quinquefasciatus and have characterized the response threshold and kinetics for CO(2) reception, with a detection threshold less than the CO(2) concentration in the atmosphere. This ORN responded in a tonic mode to lower concentrations of CO(2), whereas higher concentrations generated a phasic-tonic mode of action potential firing. Sensillum potentials accurately represented the response magnitude and kinetics of carbon dioxide-elicited excitatory responses. Stimulation of these ORNs with human breath, a complex mixture of mosquito kairomones and up to 4.5% CO(2), elicited excitatory responses that were reliably detected by CO(2)-sensitive ORNs. Another ORN housed in these sensilla responded to 1-octen-3-ol and to various plant-derived compounds, particularly floral and green leaf volatiles. This ORN showed remarkable sensitivity to the natural enantiomer, (R)-(-)-1-octen-3-ol, rivaling pheromone-detecting ORNs in moths. Maximum neuronal response was elicited with a 10 ng dose. A biological, ecological role of maxillary palps in detection of plant- and nectar-related sources is proposed.     

Active selection of afferent information as the basic principle of peripheral correction of the activity of spinal rhythmic movement generators

This paper summarizes information obtained in the experimental study of the dynamics of polarization of central primary afferent endings and modifications of segmental responses to afferent stimuli during fictitious locomotion and fictitious scratching in immobilized, decorticated, decerebrate, and spinal cats. Fictitious locomotion was accompanied by tonic hyperpolarization, fictitious scratching by tonic depolarization of central primary afferent endings. Against the background of these long-lasting changes in primary afferent depolarization, it exhibited periodic changes in the rhythm of efferent activity. Periodic changes of depolarization were virtually in phase in different ipsilateral segments of the lumbosacral enlargement. Data on groups of afferent fibers in whose central endings tonic and phasic changes of polarization took place. The appearance of fictitious locomotion was accompanied by a tonic increase, and of fictitious scratching by tonic inhibition of several evoked segmental responses. These tonic changes were a background against which segmental responses were modulated in step with the working rhythm of the locomotion and scratching generators. Many of the changes in evoked segmental responses were shown to be based on modulation of polarization of central endings of primary afferents by locomotion and scratching generators. It is concluded that active tonic and phase-dependent selection of incoming afferent information is effected through modulation of presynaptic inhibition of the generator. The role of this selection in peripheral collection of activity of locomotion and scratching generators is discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 16, No. 3, pp. 343–353, May–June, 1984.     

Reaction of neurons of the medial geniculate body to acoustic stimulation

Responses of medial geniculate body (MGB) neurons to pure tones and clicks were studied in acute experiments in immobilized cats, preliminary operations being performed under calypsol anaesthesia. MGB units were identified by their reactions to cortical zone AI and brachium of inferior colliculus stimulations. When tonal stimuli were applied relay neurons of pars principalis of MGB usually demonstrated either unimodal tuning curves with narrow frequency band or fragmental ones with several narrow bands. On-response with subsequent inhibition of the background activity or without such an inhibitory period was most frequent type of the reaction (66.6%) of relay MGB neurons to tonal stimulation. The group of relay neurons with the tonic type of reaction (9.1%) was classified for which the duration of tonic response depends on the duration of tonal stimulus. Change of the excitatory reaction to the inhibitory one when the characteristic tone frequency is changed by non-characteristic++ ones is supposed to be a mechanism supplying sharpness of tuning at relay MGB neurons. It is concluded that responses of acoustic cortical neurons to sound stimulation depend to a great extent on the pattern of impulsation that comes from MGB relay units.     

Structure and physiology of the locust femoral chordotonal organ

The connective chordotonal organs (COs) in the femora of the prothoracic and mesothoracic legs of the locust Schistocerca gregaria are divided into two parts, the proximal and the distal scoloparia. The proximal scoloparium contains about 150 small neurons and is anchored to the femoral cuticle. The distal scoloparium contains about 50 larger neurons and is connected at its proximal end to both the cuticle and the flexor tibiae muscle.Records were made from the distal scoloparium, classifying units by spike size. The tibial position/total activity response curve is ∪-shaped but when a small number of units is selected the responses occur only when the tibia is on one side of its centre position. The tonic responses display considerable hysteresis and a degree of adaptation which varies with the tibial angle. Units with phasic and phasic-tonic responses are common and their responsiveness depends on the range of angles the tibia is moved through. The same units respond strongly to flexor tibiae contraction with the tibia either fixed or free, and so may serve as receptors for tension in that muscle.The CO mediates phasic resistance reflexes in all three extensor tibiae motoneurons and tonic reflexes in the extensor ‘slow’ neuron. It is suggested that the very detailed information furnished by the CO is used in a complex way in the control of the femoral muscles.     

Multisensory convergence in the mushroom bodies of ants and bees

The mushroom bodies, central neuropils in the arthropod brain, are involved in learning and memory and in the control of complex behavior. In most insects, the mushroom bodies receive direct olfactory input in their calyx region. In Hymenoptera, olfactory input is layered in the calyx. In ants, several layers can be discriminated that correspond to different clusters of glomeruli in the antennal lobes, perhaps corresponding to different classes of odors. Only in Hymenoptera, the mushroom body calyx also receives direct visual input from the optic lobes. In bees, six calycal layers receive input from different classes of visual interneurons, probably representing different parts of the visual field and different visual properties. Taken together, the mushroom bodies receive distinct multisensory information in many segregated input layers.     

Response characteristics of single trochanteral campaniform sensilla in the stick insect, Cuniculina impigra

ABSTRACT. The campaniform sensilla on the trochanter of the stick insect, Cuniculina impigra Redtenbacher, were stimulated by slightly bending the leg in the horizontal plane. Single sensory units in the nerve were recorded using glass microelectrodes. These units can be classified into tonic and phasic-tonic receptors. In both cases there were units which increased their discharge frequency during forward movement of the femur, and units which responded to backward movement. No purely phasic receptors were found.     

Information processing in a cricket ganglion: The response of giant fibres to sound pulses

The response of giant fibres in the ventral nerve cord to stimulation of cercal afferents with pulses of sound was studied in the domestic cricket, Acheta domesticus. Pulses at 450 Hz gave the highest frequency response in several classes of units, and were therefore used as stimuli in subsequent experiments. In intact animals the response of the giant fibres to bilateral cercal stimulation showed a characteristic high frequency ‘on’ response followed by steady firing of some units for the duration of the sound pulse. The end of each pulse was followed by a short period of inhibition of the tonic units.Cercal amputation and other experiments showed that input from cercal afferents excites both large and small ipsilateral giants, and excites small and inhibits large contralateral giants. Descending input from higher neural centres in intact animals tends to reduce the responses to the stimuli. It is suggested that a function of the contralateral excitatory and inhibitory effects is to sharpen the ‘on’ response of the giant fibres to sound stimuli in intact animals.     

Excitatory and inhibitory responses of the ongoing sympathetic discharge in single renal neurons to liminal stimulation of aortic C-fibres in the rabbit

Excitatory and inhibitory responses of sympathetic discharge were recorded in single renal postganglionic neurons of rabbits anaesthetized with urethane and chloralose. The animals were vagotomized and had transected aortic nerves. Responses were elicited by single volleys in the aortic C-fibres. Excitatory responses consisted in short-lasting increase in the rate of ongoing sympathetic discharge and were followed by inhibitory responses. Excitatory effects together with inhibitory responses were seen in 68% of units (19/28). Only excitatory effects appeared in 2 neurons (7.1%) and only inhibitory effects in 7 neurons (25%). In renal neurons exhibiting both effects, the excitatory responses appeared after latency of 172 +/- 8 ms (x +/- S.D.) and had duration of 64 +/- 11 ms. Inhibitory effects had latency o f 257 +/- 10 ms and their duration amounted to 265 +/- 22 ms. In more than half of recordings the excitatory responses were separated from the inhibitory effects by discharge lasting 33 +/- 4 ms. Significant correlations between latencies of excitatory and inhibitory responses and between duration of excitatory and latency of inhibitory responses suggest interaction between both effects. Increase in the number of afferent volleys (1 through 5) evoked relatively small changes in duration of the excitatory effect indicating that temporal facilitation is of minor importance in generating this response. Temporal facilitation was found to play an important role in determining duration of the inhibitory response. Comparison of effects of unilateral and bilateral stimulation of the aortic C-fibres showed larger occlusion of durations of the excitatory than inhibitory responses.     

Interaction between neurons displaying tonic response to sound and other cells of the feline auditory cortex

Interaction between neurons with a tonic response pattern and either nearby or further removed (by about 400–500 µm) cortical neurons was investigated during acute experiments on 15 immobilized cats using cross-correlation analysis techniques. Synchronizing excitatory input common to the nerve cells was found in cross-correlation histograms (CCH) in 26 out of 36 test pairs of neurons (72%). Both positive and negative cross-correlation (five pairs in each case) were discovered, pointing to mono- or polysynaptic excitatory and inhibitory effects of the tonic neuron on spike activity in the other cell from CCH of 10 pairs of neurons. The functional diversity of neurons f distinguished by a tonic pattern of response to sound was deduced on the basis of findings from this research. The theory that some tonic type cells act as excitatory neurons and others fulfil the function of inhibitory interneurons is examined.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 21, No. 5, pp. 613–620, September–October, 1989.     

Sensitivity of the neurons in the auditory inferior colliculus of mice to the direction of the shift of broadband spectral notch noise

Series of a notch noise with regular shifts of the notch center frequency: one--from low frequencies to high frequencies and the other--from high frequencies to the low, were synthesized. The notch noise series imitated sound source vertical moving. Single neuron's responses of inferior colliculus of the house mouse (Mus musculus) to the notch-noises altered with notch central frequency varying through excitatory and inhibitory frequency response areas in neurones' receptive fields. The neural responses alteration to the notch noise varying depended on the bandwidth of notch. Disinhibition in inhibitory side band could be higher if the notch overlying the inhibitory areas followed the notch overlying the excitatory areas. The data obtained make it possible to consider the excitatory and inhibitory interaction as a mechanism of neural sensitivity to the notch moving direction. Neurones' response set could provide information about sound source moving over auditory space.     

Medullary taste responses are modulated by the bed nucleus of the stria terminalis

Previous studies have shown a modulatory influence of limbic forebrain areas, such as the central nucleus of the amygdala and lateral hypothalamus, on the activity of taste-responsive cells in the nucleus of the solitary tract (NST). The bed nucleus of the stria terminalis (BST), which receives gustatory afferent information, also sends descending axons to the NST. The present studies were designed to investigate the role of the BST in the modulation of NST gustatory activity. Extracellular action potentials were recorded from 101 taste-responsive cells in the NST of urethane-anesthetized hamsters and analyzed for a change in excitability following bilateral electrical stimulation of the BST. The response of NST taste cells to stimulation of the BST was predominately inhibitory. Orthodromic inhibitory responses were observed in 29 of 101 (28.7%) NST taste-responsive cells, with four cells inhibited bilaterally. An increase in excitability was observed in seven of the 101 (6.9%) NST taste cells. Of the 34 cells showing these responses, 25 were modulated by the ipsilateral BST and 15 by the contralateral; four were inhibited bilaterally and two inhibited ipsilaterally and excited contralaterally. The duration of inhibitory responses (mean = 177.9 ms) was significantly longer than that of excitatory responses (35.4 ms). Application of subthreshold electrical stimulation to the BST during taste trials inhibited or excited the taste responses of every BST-responsive NST cell tested with this protocol. NST neurons that were most responsive to sucrose, NaCl, citric acid or quinine hydrochloride were all affected by BST stimulation, although citric acid-best cells were significantly more often modulated and NaCl-best less often modulated than expected by chance. These results combine with excitatory and inhibitory modulation of NST neurons by the insular cortex, lateral hypothalamus and central nucleus of the amygdala to demonstrate extensive centrifugal modulation of brainstem gustatory neurons.     

Local spiking interneurons controlling the equilibrium response in the crayfish Procambarus clarkii

1. In the crayfish brain, the responses of local spiking interneurons to body roll simulated by bending of statocyst hairs, were investigated with intracellular recording and staining techniques. The neurons had two separate branching portions in the protocerebrum and the deutocerebrum. They were named as type-I local neurons and further classified into 5 types (ac-U, vplc-U, vplc-B, vupc-U, vupc-B). 2. Vupc-U neurons showed excitatory responses and vplc-U neurons showed inhibitory responses to inward hair deflection of the statocyst ipsilateral to their deutocerebral branches. The other 3 types were of mixed populations of the interneurons showing either excitatory or inhibitory responses to the stimulation. 3. Of 10 type-I local neurons showing excitatory responses to inward hair deflection, 6 interneurons had output effects on oculomotor and/or descending neurons. All these 6 interneurons showed large EPSPs and much higher frequency of spikes to the hair stimulation than those of the other 4. All 8 type-I local neurons that showed inhibitory responses had no output effects. 4. Type-I local neurons controlled two equilibrium responses, compensatory eye movement and righting reflex, either simultaneously or independently.     

Response of Cat Ventrolateral Spinal Axons to an Itch-Producing Stimulus (Cowhage)

A comparison was made between different categories of mechanically sensitive, ventrolateral spinal axons to assess their sensitivity to the itch-producing substance cowhage. Of 52 wide-dynamic-range (WDR) units, 17 had contralateral, 22 had ipsilateral, and 13 had bilateral receptive fields. Of the 5 low-threshold units, 1 had an ipsilateral receptive field and the remainder were bilateral. Among the high-threshold units, 10 were contralateral, 6 ipsilateral, and 5 bilateral. Although there was no evidence of cowhage sensitivity in either low- or high-threshold spinal axons, neurons with WDR properties were reactive to cowhage. WDR neurons were subclassified on the basis of their resting discharge pattern as having intermittent, continuous, or no resting discharge. WDR units with an intermittent pattern of resting discharge demonstrated a significant sensitivity to active cowhage and hence might be regarded as pruritogen-responsive spinal axons. Inactive cowhage was used as a control stimulus. In some WDR units with large receptive fields, there were observations suggesting convergence of chemoreceptive and mechanoreceptive inputs, which produced inhibitory as well as excitatory effects.     

Response of cat ventrolateral spinal axons to an itch-producing stimulus (cowhage).

A comparison was made between different categories of mechanically sensitive, ventrolateral spinal axons to assess their sensitivity to the itch-producing substance cowhage. Of 52 wide-dynamic-range (WDR) units, 17 had contralateral, 22 had ipsilateral, and 13 had bilateral receptive fields. Of the 5 low-threshold units, 1 had an ipsilateral receptive field and the remainder were bilateral. Among the high-threshold units, 10 were contralateral, 6 ipsilateral, and 5 bilateral. Although there was no evidence of cowhage sensitivity in either low- or high-threshold spinal axons, neurons with WDR properties were reactive to cowhage. WDR neurons were subclassified on the basis of their resting discharge pattern as having intermittent, continuous, or no resting discharge. WDR units with an intermittent pattern of resting discharge demonstrated a significant sensitivity to active cowhage and hence might be regarded as pruritogen-responsive spinal axons. Inactive cowhage was used as a control stimulus. In some WDR units with large receptive fields, there were observations suggesting convergence of chemoreceptive and mechanoreceptive inputs, which produced inhibitory as well as excitatory effects.