Participation of the GABA B receptors in presynaptic inhibition of the spinal cord descending projections fibers in the frog Rana ridibunda

(-)-Baclophen was found to depress in a dose-dependent and reversible way the excitatory post-synaptic potentials (EPSPS) of motor neurons and the ventral root potentials evoked by stimulation of fibres of the ipsi- and contralateral ventral columns. The (-)-baclophen depressing effect could be eliminated with saclophen. Picrotoxin eliminated the depressing effect of the GABA on the descending EPSPS. Depressing effects of (-)-baclophen and GABA upon the ventral root potentials were also shown. The data obtained in pharmacological analysis corroborate to a certain extent existence of the GABAB receptor presynaptic inhibition in descending fibres monosynaptically corrected with the spinal cord motor neurons in the frog Rana ridibunda.     

Morphology of spinal electromotor neurons and presynaptic coupling in the gymnotidSternarchus albifrons

Brain Cell Biology - Spinal electromotor neurons in the gymnotidSternarchus albifrons were studied by light and electron microscopy. In this species, the electric organ discharge, which is of high...     

Non-peptidergic primary afferents are presynaptic to neurokinin-1 receptor immunoreactive lamina I projection neurons in rat spinal cord

ABSTRACT: BACKGROUND: Pain-related (nociceptive) information is carried from the periphery to the dorsal horn of the spinal cord mostly by two populations of small diameter primary afferents, the peptidergic and the non-peptidergic. The peptidergic population expresses neuropeptides, such as substance P and calcitonin gene-related peptide, while the non-peptidergic fibers are devoid of neuropeptides, express the purinergic receptor P2X3, and bind the isolectin B4 (IB4). Although it has been known for some time that in rat the peptidergic afferents terminate mostly in lamina I and outer lamina II and non-peptidergic afferents in inner lamina II, the extent of the termination of the latter population in lamina I was never investigated as it was considered as very minor. Because our preliminary evidence suggested otherwise, we decided to re-examine the termination of non-peptidergic afferents in lamina I, in particular with regards to their innervation of projection neurons expressing substance P receptors (NK-1r). We used retrograde labeling of neurons from the parabrachial nucleus combined with lectin IB4 binding and immunocytochemistry. Samples were examined by confocal and electron microscopy. RESULTS: By confocal microscopy, we studied the termination of non-peptidergic afferents in lamina I using IB4 binding and P2X3 immunoreactivity as markers, in relation to CGRP immunoreactivy, a marker of peptidergic afferents. The number of IB4 or P2X3-labeled fibers in lamina I was higher than previously thought, although they were less abundant than CGRP-labeled afferents. There were very few fibers double-labeled for CGRP and either P2X3 or IB4. We found a considerable number of IB4-positive fiber varicosities in close apposition to NK-1r-positive lamina I projection neurons, which were distinct from peptidergic varicosities. Furthermore, we confirmed at the ultrastructural level that there were bona fide synapses between P2X3-immunoreactive non-peptidergic boutons and neurokinin-1 receptor-positive lamina I dendrites. CONCLUSIONS: These results indicate the presence of direct innervation by non-peptidergic nociceptive afferents of lamina I projection neurons expressing NK-1r. Further investigations are needed to better understand the role of these connections in physiological conditions and chronic pain states.     

Transmission of amplitude-modulated signals in the presynaptic inhibition system of the cat spinal cord

In experiments with cats under the hexenal anesthesia it has been found that the transmission of information in multineuronic reflex ring carries out by frequency-dependent way. The optimum frequency subrange corresponds to each meaning of the modulation depth. Appearing signal distortions are accompanied by the phase lead of dorsal potentials with maximum on "resonance" frequency. The mechanism of presynaptic inhibition serves as control command amplifier. For all this the information signal amplitude grows, signal relation to noise increases, noise immunity of information transmission through the neuronic communication channel of multineuronic reflex ring improves considerably.     

Effects of spinal transection on presynaptic markers for glutamatergic neurons in the rat

To evaluate the hypothesis that glutamic acid may be the neurotransmitter of descending, excitatory supraspinal pathways, the uptake and release ofl-[³H] glutamate and the levels of endogenous glutamate were measured in preparations from rat lumbar spinal cord following complete mid-thoracic transection. Following transection, the activity of the synaptosomal high-affinty glutamate uptake process was increased in both dorsal and ventral halves of lumbar cord between 1 and 14 days after transection and returned to control levels by 21 days posttransection. At 7 days, the increased activity of the uptake process forl-[³H] glutamate resulted in elevation ofV _max with no significant alteration inK _t as compared to age-matched controls. Depolarization-induced release ofl-[³H]glutamate from prelabeled slices did not differ significantly from control in the lesioned rat except at 21 days after lesion when the amount of tritium release was significantly greater in the transected preparations than in control. Amino acid analysis of the lumbar cord from control and transected rats indicated only a 10% decrease in the level of endogenous glutamate and no alterations in the concentration of GABA and glycine 7 days after lesion. These findings do not support the hypothesis that glutamate serves as a major excitatory neurotransmitter in supraspinal pathways innervating the lumbar cord of the rat.     

A presynaptic locus of the action of Met-enkephalin demonstrated in mouse spinal cord cultures

Monosynaptic excitatory post-synaptic potentials (EPSPs) evoked in spinal cord (SC) neurons by stimulation of dorsal root ganglion (DRG) neurons in cell cultures were reduced by perfusion application of the opiate peptide, Met-enkephalin (2-4 microM). In about 2/3 of cases examined, EPSPs evoked by stimulation of spinal cord cells were also reduced by Met-enkephalin. The effects were antagonized by concomitant perfusion with naloxone (1-2 microM) and recovered when perfusion with Met-enkephalin was stopped. Statistical analysis of synaptic responses indicated that the reduction of EPSP amplitude was due, at least to a major extent, to a decrease in presynaptic transmitter release.     

Modulation of sensory input to the spinal cord by presynaptic ionotropic glutamate receptors

Sensory input from peripheral nerves to the dorsal horn of the spinal cord is mediated by a variety of agents released by the central terminals of dorsal root ganglion (DRG) neurons. These include, but are not limited to, amino acids, especially glutamate, peptides and purines. The unraveling of the mechanisms of synaptic transmission by central terminals of DRG neurons has to take into account various ways in which the message from the periphery can be modulated at the level of the first central synapse. These include postsynaptic and presynaptic mechanisms. Homomeric and heteromeric complexes of receptor subunits for the different transmitters released by DRG neurons and interneurons, clustered at the postsynaptic site of central synapses, can be expressed in different combinations and their rate of insertion into the postsynaptic membrane is activity-regulated. Inhibitory mechanisms are an important part of central modulation, especially via presynaptic inhibition, currently believed to involve GABA released by inhibitory intrinsic neurons. Recent work has established the occurrence of another way by which sensory input can be modulated, i.e. the expression of presynaptic ionotropic and metabotropic receptors in central terminals of DRG neurons. Microscopic evidence for the expression, in these terminals, of various subunits of ionotropic glutamate receptors documents the selective expression of glutamate receptors in functionally different DRG afferents. Electrophysiological and pharmacological data suggest that activation of presynaptic ionotropic glutamate receptors in central terminals of DRG neurons may result in inhibition of release of glutamate by the same terminals. Glutamate activating presynaptic receptors may spill over from the same or adjacent synapses, or may be released by processes of astroglial cells surrounding synaptic terminals. The wide expression of presynaptic ionotropic glutamate receptors, especially in superficial laminae of the dorsal horn, where Adelta- and C fibers terminate, provides an additional or alternative mechanism, besides GABA-mediated presynaptic inhibition, for the modulation of glutamate release by these fibers. Since, however, presynaptic ionotropic glutamate receptors are also expressed in terminals of GABAergic intrinsic interneurons, a decrease of GABA release resulting from activation of these receptors in the same laminae, may also play a role in central sensitization and hyperalgesia.     

Regulation of cholinergic expression in cultured spinal cord neurons

Factors regulating development of cholinergic spinal neurons were examined in cultures of dissociated embryonic rat spinal cord. Levels of choline acetyltransferase (CAT) activity in freshly dissociated cells decreased rapidly, remained low for the first week in culture, and then increased. The decrease in enzyme activity was partially prevented by increased cell density or by treatment with spinal cord membranes. CAT activity was also stimulated by treatment with MANS, a molecule solubilized from spinal cord membranes. The effects of MANS were greatest in low-density cultures and in freshly plated cells, suggesting that the molecule may substitute for the effects of elevated density and cell-cell contact. CAT activity in ventral (motor neuron-enriched) spinal cord cultures was similarly regulated by elevated density or treatment with MANS, whereas enzyme activity was largely unchanged in mediodorsal (autonomic neuron-enriched) cultures under these conditions. These observations suggest that development of cholinergic motor neurons and autonomic neurons are not regulated by the same factors. Treatment of ventral spinal cord cultures with MANS did not increase the number of cholinergic neurons detected by immunocytochemistry with a monoclonal CAT antibody, suggesting that MANS did not increase motor neuron survival but rather stimulated levels of CAT activity per neuron. These observations indicate that development of motor neurons can be regulated by cell-cell contact and that the MANS factor may mediate the stimulatory effects of cell-cell contact on cholinergic expression.     

Extensive fusion of mitochondria in spinal cord motor neurons

The relative roles played by trafficking, fission and fusion in the dynamics of mitochondria in neurons have not been fully elucidated. In the present study, a slow widespread redistribution of mitochondria within cultured spinal cord motor neurons was observed as a result of extensive organelle fusion. Mitochondria were labeled with a photoconvertible fluorescent protein (mitoKaede) that is red-shifted following brief irradiation with blue light. The behavior of these selectively labeled mitochondria was followed by live fluorescence imaging. Marking mitochondria within the cell soma revealed a complete mixing, within 18 hours, of these organelles with mitochondria coming from the surrounding neurites. Fusion of juxtaposed mitochondria was directly observed in neuritic processes at least 200 microns from the cell body. Within 24 hours, photoconverted mitoKaede was dispersed to all of the mitochondria in the portion of neurite under observation. When time lapse imaging over minutes was combined with long-term observation of marked mitochondria, moving organelles that traversed the field of view did not initially contain photoconverted protein, but after several hours organelles in motion contained both fluorescent proteins, coincident with widespread fusion of all of the mitochondria within the length of neurite under observation. These observations suggest that there is a widespread exchange of mitochondrial components throughout a neuron as a result of organelle fusion.     

Cell death of asynaptic neurons in regenerating spinal cord

The weakly electric fish Sternarchus albifrons possesses a unique class of asynaptic neurons, the electromotor neurons, whose axons constitute the electric organ. The cell bodies of origin of the electrocyte axons are located in the spinal cord. Both spinal cord and electromotor neurons ( electrocytes ) regenerate after amputation of the tail. Sternarchus spinal cords which have regenerated for 1 or more years show a progression in number of perikarya of electromotor neurons along the rostro-caudal axis. The most recently regenerated region of the cord is at the caudal end, which consists of a tube of ependyma. Progressing rostrally along regenerated spinal cord from the caudal end, numerous cells are generated and large numbers of electromotor neurons differentiate. The maximum number of electromotor neurons per transverse section of regenerated cord is five times higher than in normal mature cord. Rostral to this, the number of electromotor neurons decreases gradually to the normal number near the transition zone (the border with unregenerated cord). As the more rostral regenerated cord has presumably had a longer period of regeneration, we conclude that excess numbers of electromotor neurons are generated initially, and that subsequently the number of these neurons is decreased by cell death. This conclusion is supported by the fact that younger regenerates (2-4 months) have larger-than-normal numbers of perikarya of electromotor neurons extending up to the transition zone (Anderson and Waxman , 1981). No evidence of migration or depletion of electromotor neurons from unregenerated cord rostral to the amputation has been observed. Since the axons of the electromotor neurons in Sternarchus do not normally form any synapses, this study provides evidence that factors other than synaptic competition must be responsible for determining cell death during regeneration of these spinal neurons.     

Stereometric characteristics of ultrastructure of presynaptic terminals in the dorsal horn of the cat spinal cord

Morphometric statistical techniques were used to investigate geometric aspects of 240 axodendritic presynaptic terminals (PT) located in the dorsal horn of the gray matter of the cat spinal cord. Parameters describing the configuration and average spatial radius of the three-dimensional PT (approximated by irregular ellipsoid were estimated on the basis of the morphometry of random PT sections applying aspects of the theory of probability. Lack of any correlation between location of the active zone and the configurational pattern (extent) of terminals was demonstrated. Densitometric distribution of average spatial PT radii was obtained (mean: 0.820 µm). The relatively limited scatter of this distribution would indicate extremely close similarity between parameters of the PT comprising the test group.Dnepropetrovsk University. A. A. Bogomolets Institute of Physiology, Academy of the Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 21, No. 3, pp. 403–410, May–June, 1989.     

Physiological types of substantia gelatinosa neurons in the rat spinal cord

Electrophysiological properties of neurons in the substantia gelatinosa (SG, or lamina II) were studied in vitro in spinal cord slices from 3-to 5-week-old rats. Based on the type of action potentials (APs) firing in response to long depolarization (0.5 to 0.8 sec), neurons were categorized into three types: tonic (APs were generated over the whole duration of the stimulus, n = 26, or 41.2%), adapting (a few APs occurred only at the beginning of stimulation, n = 8, 12.7%), and delayed-firing neurons, DFNs (APs occurred at the end of stimulation, n = 22, 35.1%); 11% of the cells had intermediate properties. Neurons of each type expressed distinct ion currents that were subthreshold for AP generation (< −40 mV). Tonic and adapting neurons either had no subthreshold currents (n = 21, or 61.3%) or expressed T-type calcium currents (n = 13, or 38.7%). All DFNs had outward A-type potassium currents. Statistical analysis confirmed this classification scheme: neurons of each type were differentially distributed in a 3-D parametric space of the main cellular properties. Distributions of tonic and adapting neurons partially overlapped, while that of DFNs differed significantly from both the above groups. It is suggested that DFNs perform a special function in the processing of sensory information; the functions of tonic and adapting neurons might be rather similar to each other. Neirofiziologiya/Neurophysiology, Vol. 40, No. 3, pp. 191–198, May–June, 2008.     

Structural proteins in the growth cone of cultured spinal cord neurons

The distribution of several structural proteins in the extending neurites and growth cones of cultured embryonic mouse spinal cord neurons was studied by indirect immunofluorescence, using affinity chromatography-purified antibodies. Fibroblastic cells in the same cultures served as internal standards for the evaluation of staining intensities. Anti-tubulin, anti-actin, and anti-clathrin stained neurons and their processes intensely, while staining with anti-α-actinin was only moderate compared with fibroblasts. Microtubules were resolved by anti-tubulin in the ‘palm’ of the growth cone but not in the neurite. Anti-actin stained even the finest lamellae and filopodia of the growth cone, and the neurite. Anti-α-actinin revealed an irregularly speckled pattern of cross-reactive material in the neurite and in the palm of the growth cone and was absent from the filopodia. Anti-clathrin stained the neurite intensely and homogeneously, and to a lesser extent the palm of the growth cone. The staining with antibodies against tubulin and clathrin differed grossly between neurons and fibroblastic cells. Within the neuron there were only gradual differences in staining intensities. The growth cone was not qualitatively different from the rest of the neurite, except for the filopodia which lacked tubulin and α-actinin, similar to the microvilli of epithelial cells.     

Structure and localization of sympathetic neurons in the cat spinal cord

By the method of retrograde axonal transport of horseradish peroxidase (HP) structure and localization of sympathetic neurons sending axons to the cranial cervical ganglion (CCG) have been revealed ipsilaterally in the ventral horns and in 4 nuclei of the spinal cord: nucl ILp, nucl. ILf. nucl. IC, nucl. ICpe. Orientation of the neurons, their number, structure of the nuclei formed by them, degree of the CCG efferentation by the preganglionic fibres, which run from various nuclei, are different. In nucl. ILf two types of neurons have been revealed-triangle and spindle-shaped, they always orienting by their long axis in mediolateral direction. The greatest amount of HP-positive neurons are found in nucl. ILp. They form a well distinquished compact nucleus in the lateral horns. HP-labelled neurons in nucl. ILp are found at the level of segments T1-T8 with their maximal amount at the level of segments T1-T3. HP-positive neurons are detected in nucl. ILf beginning from the segment C8 up to the middle of T4, in nucl. IC-from the segment C8 up to T6, in nucl. ICpe-from the segment C8 up to T5, in the ventral horns-from the segment T1 up to T5. In rostocaudal direction from the segment C8 up to T8 the number of HP-positive neurons is decreasing, but the part of nucl. ILp neurons in the CCG efferentation, comparing to the neurons in other sympathetic structures of the spinal cord, is increasing.     

Microtubule-synaptic vesicle associations in cultured rat spinal cord neurons

Summary This paper describes new ultrastructural features of neural processes and of synapses in cultured CNS tissue treated with albumin before fixation using a modification of the technique recently introduced by Gray (1975). Nerve fibre bundles in explants of foetal spinal cord grown in vitro for 15–18 days were transected microsurgically. After transection the cultures were exposed to 20% albumin in distilled water and then fixed in unbuffered osmium tetroxide followed by unbuffered glutaraldehyde.In this material, but not in controls (injured but not exposed to albumin; exposed to albumin without injury) microtubules were found within many axonal varicosities, often situated close to presynaptic membrane specializations. These microtubules were closely associated with vesicles resembling synaptic vesicles, which were occasionally aligned in rows along the microtubules. Similar vesicle-microtubule associations were also found in non-terminal axons. Microtubules were also observed very close to some postsynaptic densities.The possibility that the microtubule-vesicle associations are involved in vesicle movements (along axons and/or within axon terminals) is discussed. A more direct involvement of microtubules in terminals in the mechanism of transmitter release is also considered.The author wishes to thank Dr. A.R. Lieberman for his help and advice, Mr. Derek Fraser and Mr. Peter Felton for their technical assistance, Mr. Stuart Waterman for the photographic prints, and Professor D.W. James for laboratory facilities