Effect of serotonin on the activity of the neurons involved in the realization of the avoidance reflex of the snail

Bath application of 10(-5) mol/l of serotonin (5-HT) elicited a 50% increase of summary EPSPs recorded in command neurones for avoidance behaviour. No significant changes of rest potential and input resistance were seen in these cells. 5-HT evoked an increase of spontaneous level of firing in motoneurones involved in the same reflex, as well as an increase in the number of spikes which paralleled increase of EPSPs to the same stimulus in command neurones. In sensory cells, presynaptic to the command neurones, application of 5-HT evoked a significant increase of excitability and of input resistance. Monosynaptic EPSPs recorded in the command neurones showed a 40% increase after serotonin application. It is concluded that the major locus of plastic changes evoked by 5-HT application in the neuronal chain underlying avoidance reflex is the synaptic contact between sensory and command neurones.     

Compensatory processes in the motor cortex of the cerebral hemispheres in partial damage to the ventrolateral thalamic nucleus in the cat]

In cats alimentary instrumental reflex was elaborated of lever transference by the right forepaw in a definite zone--prior to and after the electrolytic damage of the left ventrolateral thalamic nucleus. It was found that even a slight damage led to disturbance of precise movements mostly expressed in the first two weeks; after that gradual normalization of the motor reactions took place. At morphological study of various pyramidal neurones and also satellite and general glia in the zone of presentation of the ventrolateral nucleus in the cerebral cortex a hypertrophy was discovered of the pyramidal cells and their processes in III and V layers, accompanied by active reaction of various glia forms. Morphometric processing and statistic analysis of the obtained data showed the dominance of structural compensatory changes observed in the cortex on the side of VL damage.     

The effect of acetylcholine and atropine on the temporal connection in the neuronal populations of the motor cortex]

On alert non-immobilized rabbits the activity of neurones in the sensorimotor cortex was studied at pair combination of brain structures stimulations. During omission of the reinforcing stimulus at the place of its expected presentation a complicated complex develops of neurones impulses reconstructions, consisting in reproduction of responses and activity changes which by their configuration differ from them and usually appear in later terms. Direct acetylcholine application on the cortex promotes manifestation of both types of neurones activity reconstructions. But atropine application depresses mainly the second type of reconstructions. Besides, acetylcholine increases the general duration of the given conditioned effects, but atropine decreases it.     

Effect of serotonin on the development of tissue cultures of the cerebral cortex in the rat

The paper deals with morpho-functional development of the visual area of newborn rats cerebral cortex in conditions of prolonged (up to 40 days) organotypical cultivation and with the effect of serotonin (5-OT) on these processes. It has been shown that systematic addition of physiological concentrations of 5-OT to the nutrient medium during explantates cultivation, stimulates glia proliferation, neurones differentiation, neuropyl formation, synaptogenesis and axones myelinization. In media with 5-OT, spontaneous activity of neurones develops earlier, the number of active cells increases by 33%, neurones with periodical bursts prevail in all periods studied. Development of neurones in the medium with 5-OT changes their sensitivity to 5-OT, which becomes close to that in situ.     

Dopaminergic neurones in various retinas and the postnatal development of tyrosine-hydroxylase immunoreactivity in the rabbit retina

The localisation of tyrosine-hydroxylase immunoreactive neurones in retinas of a variety of animals were examined. Immunoreactivity was associated with specific populations of amacrine neurones in all species examined, viz; rabbit, guinea pig, monkey, cow, frog, pigeon and goldfish. Only in the goldfish was immunoreactivity also associated with processes situated in the outer plexiform layer showing that in this species catecholamine interplexiform cells exist. The development of tyrosine-hydroxylase immunoreactive neurones in the rabbit retina was also analysed. The first immunoreactive positive cells were observed by the third postnatal day. The immunoreactive positive neurones at this stage are weak and lack processes. The intensity of the immunoreactivity increases with development, but processes are lacking, until the 10th postnatal day. The immunoreactive neurones only appear fully developed by the 22nd to 28th postnatal day. Autoradiographical analysis of 3H-dopamine uptake strongly suggests that neurones containing tyrosine-hydroxylase immunoreactivity in the different retinas have the capacity to take up exogenous dopamine. It is therefore concluded that localisation of either 3H-dopamine uptake or tyrosine-hydroxylase provides a means of locating catecholamine neurones.     

Dopaminergic neurones in various retinas and the postnatal development of tyrosine-hydroxylase immunoreactivity in the rabbit retina

Summary The localisation of tyrosine-hydroxylase immunoreactive neurones in retinas of a variety of animals were examined. Immunoreactivity was associated with specific populations of amacrine neurones in all species examined, viz; rabbit, guinea pig, monkey, cow, frog, pigeon and goldfish. Only in the goldfish was immunoreactivity also associated with processes situated in the outer plexiform layer showing that in this species catecholamine interplexiform cells exist.The development of tyrosine-hydroxylase immunoreactive neurones in the rabbit retina was also analysed. The first immunoreactive positive cells were observed by the third postnatal day. The immunoreactive positive neurones at this stage are weak and lack processes. The intensity of the immunoreactivity increases with development, but processes are lacking, until the 10th postnatal day. The immunoreactive neurones only appear fully developed by the 22nd to 28th postnatal day.Autoradiographical analysis of ³H-dopamine uptake strongly suggests that neurones containing tyrosine-hydroxylase immunoreactivity in the different retinas have the capacity to take up exogenous dopamine. It is therefore concluded that localisation of either ³H-dopamine uptake or tyrosine-hydroxylase provides a means of locating catecholamine neurones.     

Distribution of the LPa3 and PPa3 neuronal processes in the pedal ganglia of the edible snail

By means of intracellular injection of the dye Lucifer yellow processes were revealed of the snail command neurones of escape behaviour LPa3 and RPa3 in pedal nerves ipsilateral to these neurones. A process of the neurone LPa3 was also found in the contralateral Nervus cutaneus pedalis secundus. Blockade of central chemical synapses by cadmium chloride did not lead to disappearance of motor reactions evoked by electrical stimulation of LPa3 and RPa3 neurones both on ipsi- and contralateral sides of the animal foot; this allowed to suggest a presence in the contralateral muscular pedal nerves of these neurones processes unrevealed by the used dyeing method.     

Cholinergic transmission at mechanosensory afferents in the crayfish terminal abdominal ganglion

Electrical stimulation of mechanosensory afferents innervating hairs on the surface of the exopodite in crayfish Procambarus clarkii (Girard) elicited reciprocal activation of the antagonistic set of uropod motor neurones. The closer motor neurones were excited while the opener motor neurones were inhibited. This reciprocal pattern of activity in the uropod motor neurones was also produced by bath application of acetylcholine (ACh) and the cholinergic agonist, carbamylcholine (carbachol). The closing pattern of activity in the uropod motor neurones produced by sensory stimulation was completely eliminated by bath application of the ACh blocker, d-tubocurarine, though the spontaneous activity of the motor neurones was not affected significantly. Bath application of the acetylcholinesterase inhibitor, neostigmine, increased the amplitude and extended the time course of excitatory postsynaptic potentials (EPSPs) of ascending interneurones elicited by sensory stimulation. These results strongly suggest that synaptic transmission from mechanosensory afferents innervating hairs on the surface of the tailfan is cholinergic.Bath application of the cholinergic antagonists, dtubocurarine (vertebrate nicotinic antagonist) and atropine (muscarinic antagonist) reversibly reduced the amplitude of EPSPs in many identified ascending and spiking local interneurones during sensory stimulation. Bath application of the cholinergic agonists, nicotine (nicotinic agonist) and oxotremorine (muscarinic agonist) also reduced EPSP amplitude. Nicotine caused a rapid depolarization of membrane potential with, in some cases, spikes in the interneurones. In the presence of nicotine, interneurones showed almost no response to the sensory stimulation, probably owing to desensitization of postsynaptic receptors. On the other hand, no remarkable changes in membrane potential of interneurones were observed after oxotremorine application. These results suggest that ACh released from the mechanosensory afferents depolarizes interneurones by acting on receptors similar to vertebrate nicotinic receptors.Abbreviations ACh cetylcholine - mns motor neurones - asc int ascending interneurone     

Several mechanisms of acetylcholine participation in the processes of formation and fixation of temporary connections

Microphoretic application of acetylcholine (ACH) to the neurones of the rabbit sensorimotor cortex elicits changes of spontaneous and evoked activity which do not correlate with one another and which persist up to two minutes after the end of ACH application. Following the formation of a defensive conditioned reflex to sound, the reactions to ACH in units involved in the formation of the temporary connection are intensified as compared with their reactions before conditioning and with reactions of those neurones which did not elaborate a temporary connection. The possible mechanisms of ACH participation in the processes of elaboration and fixation of temporary connections are discussed.     

Chemical sensitivity of neurons to immobilization emotional stress in the rat

Chemical sensitivity of the neurones of the medial thalamus (MT) and ventromedial hypothalamus (VMH) to noradrenaline (NA) was studied microionophoretically in conditions of 30-hour immobilization of rats. Chemical sensitivity of single neurons of MT as well as VMH during immobilization is characterized by a certain instability, showed in changes of their reactions at repeated NA applications. These changes were observed significantly more frequently in MT neurones especially at the initial stage of immobilization. At the final stage as well as in unrestrained control animals, changes of the sensitivity were seen significantly more seldom. At the initial stage of rats' immobilization a significant increase of the number of MT and VMH cells responding to NA application by the excitative type of reactions was also observed.     

The characteristics of trace rhythm reproduction by the neurons of the rabbit sensorimotor cortex in the aftereffect of periodic stimulation]

Trace rhythm recruitment (TRR)--CR analogue to time was studied appearing in response to prolonged electrocutaneous stimulation of the forelimb of the alert rabbit with the frequency 0.5-1-2 Hz. The activity was recorded of 180 cells of the sensorimotor cortex before (80) and after (100) periodical stimulation during 10-20 min. The first series of rhythmic stimulation led to a short-term TRR of the stimulation frequency, the following series formed a clear TRR, preserved for several days. The possibility was revealed of "relearning" of neurones at stimulation rhythm change. The ability of TRR phenomenon of extinguishment, prolonged preservation and reproduction of traces, "relearning" brings it nearer to the processes, analogous to the temporal connection. The ability to reveal distinctly and to quantitatively estimate the characteristics of the applied stimulus fixated by the neurones, makes this model perspective for comparable study of the memory traces at the neuronal level in the animals of various ages.     

Axonal degeneration within the tympanal nerve of Schistocerca gregaria

This study describes time course and ultrastructural changes during axonal degeneration of different neurones within the tympanal nerve of the locust Schistocerca gregaria. The tympanal nerve innervates the tergit and pleurit of the first abdominal segment and contains the axons of both sensory and motor neurones. The majority of axons (approx. 97%) belong to several types of sensory neurones: mechano- and chemosensitive hair sensilla, multipolar neurones, campaniform sensilla and sensory cells of a scolopidial organ, the auditory organ. Axons of campaniform sensilla, of auditory sensory cells and of motor neurones are wrapped by glial cell processes. In contrast, the very small and numerous axons (diameter <1 microm) of multipolar neurones and hair sensilla are not separated individually by glia sheets. Distal parts of sensory and motor axons show different reactions to axotomy: 1 week after separation from their somata, distal parts of motor axons are invaded by glial cell processes. This results in fascicles of small axon bundles. In contrast, distal parts of most sensory axons degenerate rapidly after being lesioned. The time to onset of degeneration depends on distance from the lesion site and on the type of sensory neurone. In axons of auditory sensory neurones, ultrastructural signs of degeneration can be found as soon as 2 days after lesion. After complete lysis of distal parts of axons, glial cell processes invade the space formerly occupied by sensory axons. The rapid degeneration of distal auditory axon parts allows it to be excluded that they provide a structure that leads regenerating axons to their targets. Proximal parts of severed axons do not degenerate.     

Changes in nucleolar dry mass of neurones of the paraventricular and supraoptic nuclei in the rat during pregnancy and lactation

Summary Interference microscopy was used to measure the dry mass of nucleoli in unfixed nuclei isolated from neurones of the paraventricular (PV) and supraoptic (SO) nuclei of female rats. Changes in nucleolar dry mass during pregnancy and lactation have been interpreted as reflecting changes in rates of synthesis of ribosomes and protein in these neurones. Measurements were made on a total of 6580 nucleoli from 135 rats. At the end of pregnancy nucleolar dry mass of both PV and SO neurones was increased compared with virgin female rats. Nucleolar dry mass of PV neurones but not SO neurones increased further during lactation. This change was biphasic, with a nadir at 2 weeks post partum. After day 5 post partum, nucleolar dry mass of PV and SO neurones was increased only in rats suckling pups. Adjustment of litter size to 10 or 22 to 24 pups on the first day post partum did not affect nucleolar changes in PV and SO neurones. Nucleolar changes were less when only one pup was nursed. The results are discussed in relation to oxytocin secretion induced by the suckling stimulus and the synthetic response of PV and SO neurones to increased secretion.     

Responses of mouse spinal neurones in culture to locally applied Phe-Met-Arg-Phe-NH2

Embryonic mouse spinal cord neurones were maintained in a primary dissociated culture with a medium free from antibiotics. Intracellular recordings were made and the effects of local application of the neuropeptide FMRFamide were tested on selected neurones. Two types of response were seen. One response was depolarizing, with an accompanying decrease in conductance. This response was probably caused by a reduction in permeability to potassium ions. The second type of response was accompanied by an increase in conductance. Such responses showed a wide variation in their reversal potentials between different neurones. A combination of permeability changes to sodium and chloride ions appeared to be responsible for these responses.     

Changes in glutamate dehydrogenase activity in the neurons of the motor cortexof the cerebral hemispheres during light deprivation

It has been shown that early light deprivation (keeping the rats for eight weeks from birth in a dark chamber) produces compensatory changes in the majority of pyramidal neurones in layers III and V of the brain motor area: significant enhancement of glutamatdehydrogenase activity activity in the bodies and processes of the neurones, increase of their volumes, augmentation of the number of neuroglial satellites with a high ferment activity. The revealed morphochemical changes, more pronounced in the layer V, are considered as a manifestation of enhanced functional activity of the coritcal end of the motor analyser, resulting from visual dereceptation.     

Functional significance of the serotoninergic influence on neuronal activity of the somatosensory cortex in 12-day-old kittens

Monoamines, which participate in synaptic transmission as transmitters, also accomplish the modulation of neuronal activity. The role of serotonin (5-hydroxytryptamine--5-HT) was investigated in 8 to 14-day-old kittens by means of iontophoretic application onto neurones of the somatosensory cerebral cortex. The most typical response was the inhibition of neuronal activity. Another type of reaction was generated by inhibitory interneurones. After the microiontophoretic application of 5-HT, the tonic response of cortical neurones to the stimulation of the sciatic nerve changed into a phasic response. It is being suggested that the application of 5-HT to cortical neurones increases the excitability of inhibitory neurones. Hence, the serotoninergic regulation of neuronal activity in the somatosensory cortex may be operational from the 11th to the 12th day of postnatal life in cats.     

Culture of intramural cardiac ganglia of the newborn guinea-pig

The ultrastructure of cultured intrinsic neurones and SIF (small intensely fluorescent) cells dissociated from the atria and interatrial septum of newborn guinea-pig heart has been studied for the first time and compared with these cells in situ. Mononucleate and binucleate neuronal somata and their processes were observed in the culture preparation; their ultrastructure was similar to that of neurones in intracardiac ganglia observed in situ. The number of neurites associated with neuronal cell bodies increased after the first week in culture. A subpopulation of intracardiac neurones showed abnormalities in culture, comparable to the changes previously described in neurones of the monkey heart after unilateral vagotomy in situ. Small granule-containing cells were observed in culture, corresponding to those described in the heart in situ. One type of large process in the culture preparation containing densely packed mitochondria has not been seen in situ, suggesting that changes in cell ultrastructure due to the conditions of culture cannot be discounted. However, the ultrastructure of the cultured cells was, for the most part, consistent with that of the same cell type in situ, indicating that the culture preparation may be a useful model for investigation of the roles and interactions of intramural neurones in the heart, which are inaccessible for such studies in situ.     

Ultrastructure of nervous tissue developing in the anterior chamber of the eye. 1. Perikaryons and dendrites

Embryonic tissues of septum and hippocampus were transplanted into the anterior eye chamber (AEC) of adult rats. The morphology of initial embryonic tissues and of transplants within 3 to 4 months of cultivation in AEC was studied. The transplanted tissue consists of neuroblasts and immature neurones: no synaptic contacts are observed. Within 3 to 4 months, highly differentiated neurones establishing synaptic contacts can be seen in the transplants. At the same time the fine structure of perikaryons and dendrites undergoes some changes: increased vacuolization, transformation of ergastoplasm into lamellar bodies. These can be due to an elevated functional activity of some neurones. Another group of morphological abnormalities (increased number of dendrite processes and microphyllopodia, somatic spines, dendrite cones of growth, tight junctions between perikaryons) suggests incomplete tissue maturation. These might be due to the absence of normal afferent and trophic influences in AEC.     

Glyoxylic acid fluorescence and ultrastructural studies of neurones in the coeliac-superior mesenteric ganglion of the aged rat

Summary Sympathetic post-ganglionic neurones in the coeliac-superior mesenteric ganglion (CSMG) complex of aged (24 month) rats have been studied by glyoxylic acid-induced fluorescence and electron microscopy. Comparisons have been made with the CSMG of young adult (4 month) rats. In the aged rats the noradrenaline fluorescence of the majority of neuronal perikarya was very low or absent and few intraganglionic fluorescent varicosities were seen. Lipofuscin pigment was very prominent at the nuclear pole region of neurones and also in dendrites and axonal processes. Ultrastructural studies revealed large accumulations of residual bodies at the nuclear poles and in axons and dendritic profiles. Within the perikarya many mitochondria were distorted or swollen, the rough endoplasmic reticulum was disarranged and much dilated as were Golgi cisternae. Primary lysosomes were encountered throughout the neurone perikaryon and its axonal or dendritic processes.In contrast to the young adult CSMG, no evidence for loading of transmitter storage vesicles with an identical dose level of 5-hydroxydopamine was detected in any part of the neurones of aged rats. This might reflect an impairment of the uptake mechanisms and/or storage of noradrenaline in aged sympathetic neurones and their axonal and dendritic processes.     

Cell volume regulation in the nervous system

There is good evidence that the three main compartments of the brain, i.e. extracellular space, neurones and glial cells, change their volume during physiological and pathophysiological neuronal activity. However, there is strikingly little knowledge about the mechanisms underlying such alterations in cell volume. For this purpose, a better understanding of the electrophysiological behavior of the neurones and glial cells during volume changes is necessary. Examples are discussed for which changes in cell volume can be derived from the underlying changes in membrane permeabilities. Volume regulatory mechanisms in the brain have not been described under isotonic conditions. However, a rapid volume regulatory decrease is occurring in cultured glial cells during exposure to hypotonic solutions. In contrast, in these cells no volume regulatory increase was found during superfusion with hypertonic media. On the other hand, the entire brain is able to compensate chronic hypertonic perturbations within hours to days. Interestingly, not only ion fluxes induce cellular volume changes but, in turn, water movements can also influence ion fluxes in both neurones and glial cells. With respect to this it should be considered that volume regulatory membrane processes might not exclusively be activated by changes in transmembranal ion gradient, but also by changes of membrane surface shape. Future studies on cellular mechanisms of volume regulation in the brain should imply a combined use of recent techniques such as computerized video-imaging, radiotracer flux measurements and ion-sensitive microelectrodes in defined cell cultures. Optical monitoring and ion-sensitive microelectrodes should enable measurements of volume changes in identified cellular elements of intact nervous structures such as brain slices.