NMDA-Receptors in the central nervous system of the honey bee with kynurenine deficiency

Effects of some drugs on the short-term memory were tested. In kynurenine deficit, mutant snow laranja manifested the same pharmacological profile and 10 to 100-fold enhancement of sensitivity of the NMDA receptors' different sites. The data obtained suggest that the gene controlling the key enzyme activity of the kynurenine pathway of tryptophan metabolism is involved in regulation of the CNS NMDA receptors' functional condition. The kynurenines may be classified as endogenous modulators of the NMDA receptor sensitivity.     

Neuronal activity in a honey bee (Apis mellifera L.) with kynurenine deficiency

Neuronal activity of the antennal lobes, mushroom bodies, and cervical connective in wild-type honey bees and snowlaranija mutants was recorded at different stages of the ontogeny (on the 1st, 3rd, 7th, and 25th days). The mutation snowlaranija affects the structural gene of tryptophane oxygenase, the first key exzyme in the kynurenine pathway of tryptophane metabolism, and leads to a deficit of kynurenines. Changes in neuronal activity in nutant bees were most pronounced in the cervical connective. A significant decrease in the pulse rate was revealed only in homozygous but not in heterozygous individuals. This finding is in accordance with previously reported inhibitory effect of the mutation at the behavioral level. Less pronounced effects were obtained when the neuronal activity was recorded in the antennal lobes or mushroom bodies. This may be related to a complex character of biochemical changes in different parts of mutants brain.     

Changes in functional characteristics of the compound eye of bees caused by mutations disturbing tryptophan metabolism

The compound eye of worker honeybees with an inborn disturbance of intermediate metabolism of tryptophan — the snow (s) and laranja (la) mutations — has increased sensitivity to light, at least 100 times higher than normal in snow and at least 10 times higher in laranja. The maxima of the spectral sensitivity curves for the whole eye in snow are shifted into the 530 nm region and in laranja to 550 nm (comparedwith 545 nm for the wild type). The electroretinograms of s andla homozygotes are unusual in form on account of the presence of a fast additional component of the receptor potential that is absent in wild-type individuals. This may be the result of immaturity of the pigment granules in the mutants, due to the inherited absence of ommochromes. Pigment granules probably play an important role not only in the formation of the light-protective screen of the ommatidium, but also in biochemical processes considered to be responsible for the electrical passivity of the photoreceptor membrane. The possibility likewise cannot be ruled out that inherited changes in the photoreceptor membranes are connected with an imbalance between derivatives of tryptophan metabolism which participate in the generation of the cell receptor potential.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 14, No. 1, pp. 69–75, January–February, 1982.     

Microelectrode analysis of light responses in the brain of the cricket (Gryllus domesticus)

Electrical activity in response to light stimuli was recorded from the brain of the cricket (Gryllus domesticus) using stainless steel microelectrodes. Four basic types of elements were observed as follows: (1) units which registered ambient light intensity by frequency of firing as well as responding with transient changes in rate to stepwise increases or decreases in intensity; (2) units which fired at a higher frequency in dark than in light; (3) units which fired continuously at low level in light and responded with a transient high frequency burst to light off; and (4) units which responded with a brief burst to on and off, but tended to be “on-dominant” or “off-dominant.” Also observed were synchronized spikes in mushroom body responding primarily to light off, but also on occasion to light on, and often accompanied by single unit responses. The units registering intensity are probably homologous with units showing similar properties recorded from the visual systems of several other arthropods and usually referred to as “sustaining units.” On-off, off, and dark units are also known from other forms. The mushroom body light responses were similar to synchronized spikes recorded in cockroach mushroom body following antennal stimulation.     

Tissue culture study of unit activity of the rat cerebral cortex

Spontaneous unit activity and morphological characteristics of visual cortical neurons from young rats aged 1 and 2 days were investigated during long-term culture (up to 34 days) of explants in vitro. Three types of spontaneous unit activity were found: single spikes, volleys, and grouped discharges. The types of spontaneous activity were found to depend on the duration of cultivation of the brain tissue. The discharge of single spikes, characteristic of neurons during the first 7–15 days in culture, subsequently was replaced by grouped discharges or volleys of spikes. The changes in unit activity were shown to coincide in time with morphological maturation of the synapses. In experiments in which strychnine (10 µg/ml) was added to the culture medium, a marked increase was observed in the mean frequency of spontaneous unit activity, accompanied by the appearance of discrete series of volley-type discharges. The genesis of spontaneous cortical unit activity is discussed on the basis of these findings.     

Effect of gamma-aminobutyric acid on excitability of tubero-infundibular neurons in rat hypothalamic slices

The effect of gamma-aminobutyric acid (GABA) on antidromically identified tubero-infundibular (TI) neurons was examined in hypothalamic slices of ovariectomized female rats. Twenty antidromically evoked spikes were obtained in the medial basal hypothalamus, including the arcuate and ventromedial nuclei, by electrical stimulation of the median eminence. Sixteen of them had a notch in the rising phase and fractionation of the initial segment (IS)- and somatodendritic (SD)-spikes was elicited by repeated stimulation at frequencies higher than 10 Hz. The application of 0.5-1.5 mM GABA to the incubation medium inhibited SD spikes in 7 of these 16 neurons. The latency, amplitude and threshold of IS spikes were not affected by GABA except for one spike whose latency fluctuated. On the remaining 9 neurons having the notch, no effect of 5-10 mM GABA was discernible. Four of 20 antidromically evoked spikes, which had a smooth rising phase and a shorter duration, were not inhibited by 5-10 mM GABA, but a fluctuation of the latency was observed in one neuron. Fifteen neurons having spontaneous unit activity were also obtained in the arcuate nucleus and its adjacent area and tested with GABA. In 10 of the 15 neurons, spontaneous unit activity disappeared following 0.1-1.5 mM GABA perfusion, while the firing rate in the remaining 5 neurons was not affected by 5-10 mM GABA. These results provide evidence for a direct inhibitory effect of GABA on TI neurons and support the involvement of GABAergic neurons in regulating neuroendocrine functions.     

Pattern and correlation of fast and slow spontaneous unit activity in the visual cortex

Spontaneous unit activity in the visual cortex and its changes during stimulation by continuous light or flashes were investigated in waking rabbits. The study of distributions of adjacent intervals showed that the neurons differ in the ratio of burst (fast, with intervals of up to 15–40 msec) and nonburst (slow) activity and in the character of changes from one type of activity to the other. Of the total number of spikes 63% were outside bursts; the ratio of their number to the number of spikes within bursts consisting of two or of three or more spikes was 27:3:1. The relative stability of the burst structure of spontaneous activity and the limited number of spikes in them (on average 2.4) were demonstrated. Bursts of three or more spikes (mean 3.6) were irregular, and in 79% of them a longer interval (18.6±2.4 msec) was observed before the shortest interval (7.9±0.9 msec). Bursts of spikes of most neurons during photic stimulation contain more spikes with shorter intervals; they also began more frequently with the shortest interval, possibly signifying an increase in the steepness and amplitude of the EPSPs lying at their basis. However, in 20% of neurons spontaneous bursts included more spikes and with shorter intervals than bursts evoked by flash stimulation.Research Institute of Psychiatry, Ministry of Health of the RSFSR, Moscow. Translated from Neirofiziologiya, Vol. 11, No. 4, pp. 311–320, July–August, 1979.     

Firing properties of substantia nigra dopaminergic neurons in freely moving rats

Single unit recordings were obtained from putative dopaminergic neurons in the substantia nigra of awake, freely moving rats. The cells exhibited waveforms, range of firing rates and types of firing patterns identical to those of identified DA neurons of anesthetized or paralyzed rats. Two firing patterns were observed: single spike activity and a bursting mode with spikes of progressively diminished amplitude and increased duration within each burst. The degree of burst firing varied considerably among the cells and individual cells sometimes switched from one pattern of firing (e.g. predominantly single spike) to another (e.g. bursting), although the determinants of these transitions are, at this time, unclear. Putative DA neurons were inhibited by i.v. apomorphine and excited by i.v. haloperidol. Haloperidol also reversed the apomorphine-induced inhibition of firing. Inhibitions and excitations were associated with a reduction and elevation, respectively, in burst firing. The effects of the two drugs were identical to their effects in immobilized rats. In several cases, a putative DA neuron was observed to fire all of its spikes in near coincidence with at least one other cell with identical electrophysiological characteristics. This form of interaction (i.e. presumed electrical coupling) between DA cells is only rarely observed in anesthetized or paralyzed rats and may play a significant role in the normal functioning of the nigrostriatal DA system.     

Development of ionic conductances in neurons of the inferior olive in the rat: an in vitro study

Neurons of the inferior olive of the rat were studied at different stages of their postnatal (PN) development by using the current clamp technique in slices maintained in vitro. Antidromic and synaptic activation of inferior olivary neurons could be achieved in preparations as young as PN day 2. Neurons at this age already exhibited a variety of ionic conductances which included fast sodium-dependent spikes, high-threshold and low-threshold calcium spikes, potassium-dependent currents, Ca-dependent after-hyperpolarizing potentials (AHPS), and both instantaneous and time-dependent inward rectification at hyperpolarized levels of membrane potential. The two types of Ca-dependent responses recorded in olivary neurons during the first postnatal week were graded with the magnitude of the depolarization imposed on the cells. Furthermore, the high-threshold Ca spikes were only clearly observed during this early period when K conductances were depressed by the injection of caesium into the cells or by bath application of 4-aminopyridine. In contrast, the high-threshold Ca spikes could be obtained without suppression of K currents and were all-or-none in character in some neurons after PN day 8 and in all neurons after PN day 11. The observations suggest that the balance between K and Ca currents changes throughout maturation and is largely in favour of the K current until about the end of the first PN week. At all ages studied, the low-threshold Ca spikes were much less sensitive to the Ca channel blocker cadmium than were the high-threshold Ca spikes. Finally, spontaneous, regular oscillations of the membrane potential were observed for the first time at PN day 16 and were only commonly observed after PN day 19, suggesting a late development of electrotonic coupling between olivary neurons.     

Modulatory action of acetylcholine on the Na-dependent action potentials in Kenyon cells isolated from the mushroom body of the cricket brain

Kenyon cells, intrinsic neurons of the insect mushroom body, have been assumed to be a site of conditioning stimulus (CS) and unconditioned stimulus (US) association in olfactory learning and memory. Acetylcholine (ACh) has been implicated to be a neurotransmitter mediating CS reception in Kenyon cells, causing rapid membrane depolarization via nicotinic ACh receptors. However, the long-term effects of ACh on the membrane excitability of Kenyon cells are not fully understood. In this study, we examined the effects of ACh on Na⁺ dependent action potentials (Na⁺ spikes) elicited by depolarizing current injection and on net membrane currents under the voltage clamp condition in Kenyon cells isolated from the mushroom body of the cricket Gryllus bimaculatus. Current-clamp studies using amphotericin B perforated-patch recordings showed that freshly dispersed cricket Kenyon cells could produce repetitive Na⁺ spikes in response to prolonged depolarizing current injection. Bath application of ACh increased both the instantaneous frequency and the amplitudes of Na⁺ spikes. This excitatory action of ACh on Kenyon cells is attenuated by the pre-treatment of the cells with the muscarinic receptor antagonists, atropine and scopolamine, but not by the nicotinic receptor antagonist mecamylamine. Voltage-clamp studies further showed that bath application of ACh caused an increase in net inward currents that are sensitive to TTX, whereas outward currents were decreased by this treatment. These results indicate that in order to mediate CS, ACh may modulate the firing properties of Na⁺ spikes of Kenyon cells through muscarinic receptor activation, thus increasing Na conductance and decreasing K conductance.     

Neural mechanism generating firing patterns in jaw motoneurons during the food-induced response in Aplysia kurodai

1. In each right and left buccal ganglia of Aplysia kurodai, we identified 4 premotor neurons impinging on the ipsilateral jaw-closing and -opening motoneurons. Three of them (MA1 neurons) had features of multifunctional neurons. Current-induced spikes in the MA1 neurons produced excitatory junction potentials (EJPs) in the buccal muscle fibers. In addition, tactile stimulation of the buccal muscle surface produced a train of spikes in the MA1 neurons without synaptic input. The other neuron (MA2) had only a premotor function. 2. The MA1 and MA2 neurons had similar synaptic effects on the jaw-closing and -opening motoneurons. Current-induced spikes in the premotor neurons gave rise to monosynaptic inhibitory postsynaptic potentials (IPSPs) in the ipsilateral jaw-closing motoneurons. Simultaneously, spikes in one of the MA1 neurons and the MA2 also gave rise to monosynaptic excitatory postsynaptic potentials (EPSPs) in the ipsilateral jaw-opening motoneuron. 3. The IPSPs and the EPSPs induced by spikes in the premotor neurons were reversibly blocked by d-tubocurarine and hexamethonium, respectively, suggesting that the MA1 and MA2 neurons are cholinergic. 4. When depolarizing and hyperpolarizing current pulses were passed into one premotor neuron, attenuated but similar potential changes were produced in another randomly selected premotor neuron in the same ganglion, suggesting that they are electronically coupled.     

Light- and electron-microscopic study of electrophysiologically characterized neurons in the mediolateral part of the lateral septum of the guinea-pig

In slices of guinea-pig brains, 36 neurons located in the mediolateral part of the lateral septum were stained intracellularly with horseradish peroxidase (n=28) or biocytin (n=8) after electrophysiological characterization. These neurons belonged to class A neurons (n=23), which generated pronounced Ca⁺⁺-dependent high-threshold spikes in control medium, or to class C neurons (n=9), which were recognized by the occurrence of small-amplitude sodic spikes followed by slower larger calcic spikes. The present results demonstrate that, despite the variety of individual cell types, the major morphological population (30/36 cells) was composed of a homogeneous class of large-sized neurons that displayed thick primary dendrites and abundant dendritic appendages. The remaining 6 cells were small-sized, poorly-spiny neurons. Somatic spines were observed on 5 out of the 30 large cells and on one out of the six smaller cells. Labeled axons were mainly oriented to the anterior commissure. The axons of nine cells richly collateralized near the perikaryon. Ultrastructural examination of 3 horseradish peroxidase-injected cells showed indented nuclei, classic organelles and somatic spines. Terminal boutons established symmetric synapses with the injected cells. These results describe the morphological features of electrophysiologically identified neurons and indicate that class A and class C neurons are distributed among morphological populations differing in perikaryal size. This suggests that the different electrical properties of class A and class C neurons reflect recordings from different parts of the neuron rather than from neurons of different types. Furthermore, the present findings demonstrate that, in the guinea-pig, electrical and morphological characteristics of somatospiny neurons are comparable with those of non-somatospiny neurons. Somatospiny neurons have a recognized integrative role in the hippocampo-septo-hypothalamic complex.     

Excitation by dopamine D-2 receptor agonists, bromocriptine and LY 171555, in caudate nucleus neurons activated by nigral stimulation

Electrophysiological studies using cats anesthetized with alpha-chloralose were carried out to determine whether or not the dopamine D-2 receptor mediates the excitation of the caudate nucleus (CN) neurons activated by stimulation of the substantia nigra (SN). Microiontophoretic application of domperidone (D-2 antagonist) produced a significant inhibition of spikes elicited by SN stimulation in 20 of 27 CN neurons. When bromocriptine and LY 171555 (D-2 agonists) were iontophoretically applied to the CN neurons in which the SN-induced spikes were inhibited by domperidone, an increase in spontaneous firing rate was observed in 18 of 20 neurons and all of 10 neurons tested, respectively. However, no alterations of firing occurred with bromocriptine or LY 171555 in any 7 neurons in which the SN-induced spikes were not affected by domperidone. The increase in firing rate by the D-2 agonists was apparently antagonized during simultaneous application of domperidone and haloperidol, but not affected during application of SCH 23390 (D-1 antagonist). These results strongly suggest that the spike generation of the CN neurons upon SN stimulation is mediated by the dopamine D-2 receptor.     

Stimulating effect of gamma-aminobutyric acid on rat hippocampal neurons in vitro

Effects of GABA on the background and electrically stimulated activity of single neurons and population spikes were investigated in isolated hippocampal slices. Application of relatively large GABA concentrations (10(-3) mol/l and more) depressed an antidromic population spike, field EPSP and neuronal background activity. Low concentrations of GABA (less than 10(-3) mol/l) added to the bath increased the population spikes amplitude and the late component of field EPSP, facilitated single neurone responses, their background activity and epileptiform discharges. GABA-evoked depolarization was observed in the majority of the studied neurons. The duality of the GABA action on central neurons are discussed.     

Dopamine D-2 receptor-mediated excitation of caudate nucleus neurons from the substantia nigra

Microiontophoretic studies using cats anesthetized with alpha-chloralose were performed to elucidate whether the excitatory response of caudate nucleus (CN) neurons upon stimulation of the pars compacta of the substantia nigra (SN) is mediated by the dopamine D-1 or D-2 receptor. There were rare convergent inputs from the SN and motor cortex (MC) in the CN neurons. Iontophoretic application of haloperidol and domperidone (dopamine D-2 receptor antagonist) produced dose-dependent inhibition of spikes elicited by SN stimulation in 25 of 42 and 50 of 82 CN neurons, respectively, however, no alterations of spikes elicited by MC stimulation occurred in any 11 neurons tested. Iontophoretically applied SCH 23390 (D-1 antagonist) did not inhibit the SN-induced spikes in any CN neurons, of which spikes were inhibited by domperidone. These results suggest that the SN-induced spikes are mediated by dopamine, which acts on postsynaptic D-2 receptors.     

Reflex pathways of the crayfish claw

Summary Efferent and sensory axons were monitored near the carpopoditepropodite joint of the crayfish (Procambarus clarkii) cheliped using en passant suction electrodes. Controlled movements were imposed by an electric motor; tactile stimulation was delivered either manually or with electrically controlled mechanical probes. Statistical spike train analysis methods were used to study correlated firing among the observed neurons. We find that individual spikes in proprioceptive afferents have a strong excitatory effect on OI and CE, probably through a monosynaptic connection. These relationships are observed for proprioceptive axons that are active during claw opening or closing, or that are tonically active when the claw is motionless. Conversely, individual OE or OI spikes exert excitatory or inhibitory (respectively) effects on the firing of proprioceptive units sensitive to claw opening. This suggests that individual efferent spikes can produce enough change in claw position to modulate proprioceptive responses. Tactile afferents also excited OI and CE strongly and directly.This work was supported by NIH Grants NH 15767 and NS 05606     

Mechanisms of inhibition of synaptic transmission in the sympathetic ganglia of rats with alloxan diabetes]

In experiments on the isolated superior cervical sympathetic ganglia of rats with alloxan diabetes rhythmic stimulation of preganglionic nerves was effected; summation presynaptic spikes and EPSPs of ganglionic neurons were registered. In rats with moderately severe alloxan diabetes progressive depression of rhythmic ganglion potentials was connected with suppression of the mediator emission to the impulse due to rapid exhaustion of its operational fraction. Rats with severe diabetes displayed also postsynaptic suppression of the ganglionic neurons. Dynamic characteristics of the transmitter turnover assessed on the basis of consideration of the successive patterns of posttetanic potentiation showed insignificant changes in the mediator output and a significant (by 38%) suppression of the mediator reserve per sec in comparison with control.     

Higher order visual input to the mushroom bodies in the bee, Bombus impatiens

To produce appropriate behaviors based on biologically relevant associations, sensory pathways conveying different modalities are integrated by higher-order central brain structures, such as insect mushroom bodies. To address this function of sensory integration, we characterized the structure and response of optic lobe (OL) neurons projecting to the calyces of the mushroom bodies in bees. Bees are well known for their visual learning and memory capabilities and their brains possess major direct visual input from the optic lobes to the mushroom bodies. To functionally characterize these visual inputs to the mushroom bodies, we recorded intracellularly from neurons in bumblebees (Apidae: Bombus impatiens) and a single neuron in a honeybee (Apidae: Apis mellifera) while presenting color and motion stimuli. All of the mushroom body input neurons were color sensitive while a subset was motion sensitive. Additionally, most of the mushroom body input neurons would respond to the first, but not to subsequent, presentations of repeated stimuli. In general, the medulla or lobula neurons projecting to the calyx signaled specific chromatic, temporal, and motion features of the visual world to the mushroom bodies, which included sensory information required for the biologically relevant associations bees form during foraging tasks.     

Mathematical analysis of the possibility of detecting correlation between spike trains of weakly interacting neurons

The number of spikes which must be recorded in order to detect significant correlation between spike trains of two synaptically connected neurons was estimated by a mathematical model. Dependence of this number of spikes on importance of interneuronal connection (measured as the amplitude of the EPSP evoked by a single spike of the input neuron in the output cell) and on the intensity of total spontaneous excitatory influences on the output neuron and on its own parameters was studied. For cells which corresponded in the weight of connections between them, their intrinsic parameters, and characteristics of spontaneous activity to real spinal neurons, the necessary number of spikes was 10⁷–10⁸. An increase in amplitude of the single EPSP and also a decrease in the intensity of the input spontaneous spike train and parameters of after-hyperpolarization of the postsynaptic neuron led to a decrease in the number of spikes necessary for the detection of significant correlation. On the basis of the results of this and previous investigations the possible principles for construction of a spinal locomotor generator are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 12, No. 3, pp. 290–296, May–June, 1980.     

Physiology and morphology of olfactory neurons associating with the protocerebral lobe of the honeybee brain

Physiology and morphology of olfactory neurons associated with the protocerebral lobe around the alpha-lobe of the mushroom body were studied in the brain of the honeybee Apis mellifera using intracellular recording and staining techniques. The responses of neurons to behaviorally relevant odorants (a blend, and components of the Nasonov pheromone, and some other non-pheromonal odors) were recorded. Different response patterns were observed within different neurons, and often within the same neuron, in response to different stimuli. All the neurons stained had innervations in the protocerebral lobe. The cell profiles varied from cells connecting the antennal lobe with both the protocerebral and lateral protocerebral lobes (projection neurons), cells linking the pedunculus of the mushroom body with both the protocerebral and lateral protocerebral lobes (PE1 neurons), cells linking the alpha-lobe and protocerebral lobe with the calyces of the mushroom body (feedback neurons), and cells linking the alpha-lobe and protocerebral lobe with the antennal lobe (recurrent neurons), to cells connecting the protocerebral lobe with the contralateral protocerebrum (bilateral neurons). These findings suggest that the protocerebral lobe acts as an olfactory center associating with other centers, and provides multi-layered recurrent networks within the protocerebrum and between the deutocerebrum and the protocerebrum in honeybee olfactory pathways.