Morphological artifacts induced in intracellularly stained neurons by dehydration: circumvention using rapid dimethyl sulfoxide clearing

Influence of spinal cord injury on the morphology of bladder afferent and efferent neurons

Severe micturition dysfunction can occur following spinal cord injury (SCI) due to abnormal contractions of the urethral sphincter during bladder contractions (bladder/sphincter dyssynergia). This causes urinary retention, bladder overdistension, and increases the workload of the bladder leading to hypertrophy of the bladder muscle. Bladder hypertrophy induced by urethral outlet ligation in rats is accompanied by enlargement of both the afferent and efferent neurons innervating the bladder. The primary aim of this study was to test whether SCI-induced bladder hypertrophy produces a similar enlargement of bladder afferent neurons in the dorsal root ganglia (DRG) or efferent neurons in the major pelvic ganglia (MPG). Following SCI in female Wistar rats, there was a four-fold increase in bladder weight. The mean cross-sectional area of bladder DRG cell profiles increased approx. 50% after SCI; however, the mean area of MPG cell profiles did not change significantly. Urinary diversion (disconnecting the ureters from the bladder) prevented both the bladder hypertrophy and the DRG cell hypertrophy after SCI, suggesting that bladder hypertrophy drives DRG cell enlargement. On the other hand, since the size of MPG cells did not change significantly after SCI, bladder hypertrophy does not mandate MPG cell enlargement. However, preliminary results indicate that the mean cross-sectional area of MPG cells did increase (2-3 times) in SCI rats when the neural input to the MPG was eliminated by transecting the pelvic and hypogastric nerves; this suggests that the lack of change in size of MPG cells after SCI may be due to an inhibitory influence from the spinal cord.

Different effects of subchronic clozapine and haloperidol on dye-coupling between neurons in the rat striatal complex

Atypical antipsychotic drugs, such as clozapine, are distinguished from classical antipsychotics (e.g. haloperidol) by their lower liability for producing motor side-effects. Although initial studies suggested that the clinical efficacy of antipsychotic drugs is related to their affinity for the D2 dopamine receptor, the delayed onset of both the therapeutic effects and the extrapyramidal symptoms associated with these drugs implicates a more complex mechanism of action. In this study, we found that continuous (but not acute) treatment of rats with either drug caused an increase in dye coupling between neurons in the limbic component of the rat striatal complex (i.e. the shell region of the nucleus accumbens) after withdrawal of the drugs. Furthermore, continuous treatment with haloperidol, but not clozapine, also increased dye coupling in the motor-related part of the striatal complex (i.e. the dorsal striatum). Thus, both therapeutically effective drugs show a delayed effect on dye coupling between neurons in the accumbens shell, whereas only the drug associated with motor side effects altered coupling between cells in the dorsal striatum. Antipsychotic drugs may therefore alleviate the profound disturbances in cognitive function of schizophrenics by producing sustained alterations in the way signals from the cortex are integrated within these brain regions.

Physiology and morphology of complex spiking neurons in the guinea pig dorsal cochlear nucleus

Intracellular recordings from the dorsal cochlear nucleus have identified cells with both simple and complex action potential waveforms. We investigated the hypothesis that cartwheel cells are a specific cell type that generates complex action potentials, based on their analogous anatomical, developmental, and biochemical similarities to cerebellar Purkinje cells, which are known to discharge complex action potentials. Intracellular recordings were made from a brain slice preparation of the guinea pig dorsal cochlear nucleus. A subpopulation of cells discharged a series of two or three action potentials riding on a slow depolarization as an all-or-none event; this discharge pattern is called a complex spike or burst. These cells also exhibited anodal break bursts, anomalous rectification, subthreshold inward rectification, and frequent inhibitory postsynaptic potentials (IPSPs). Seven complex-spiking cells were stained with intracellular dyes and subsequently identified as cartwheel neurons. In contrast, six identified simple-spiking cells recorded in concurrent experiments were pyramidal cells. The cartwheel cell bodies reside in the lower part of layer 1 and the upper part of layer 2 of the nucleus. The cells are characterized by spiny dendrites penetrating the molecular layer, a lack of basal dendritic processes, and an axonal plexus invading layers 2 and 3, and the inner regions of layer 1. The cartwheel cell axons made putative synaptic contacts at the light microscopic level with pyramidal cells and small cells, including stellate cells, granule cells, and other cartwheel cells in layers 1 and 2. The axonal plexus of individual cartwheel cells suggests that they can inhibit cells receiving input from either the same or adjacent parallel fibers and that this inhibition is distributed along the isofrequency contours of the nucleus.

5-Hydoxytryptamine evokes depolarizations and membrane potential oscillations in rat sympathetic preganglionic neurones

1. Whole-cell recordings were made from seventy-seven identified rat sympathetic preganglionic neurones (SPN) in spinal cord slices. Perfusion of 5-HT (0.5-30 microM) strongly depolarized 90% of neurones. The response was slow in onset, could last over 10 min and was associated with an increase in input resistance. 5-HT could also evoke rhythmical membrane potential oscillations in a population of previously quiescent neurones. 2. The 5-HT response persisted in TTX and also in low-Ca(2+)-high-Mg2+ artificial cerebrospinal fluid (ACSF), suggesting that the receptors are on SPN. The 5-HT uptake inhibitor 6-nitroquipazine potentiated the 5-HT-induced depolarization. 3. The 5-HT-induced depolarization was reduced and then abolished by membrane hyperpolarization to potentials of about -100 mV, but was not reversed in sign by further hyperpolarization. In voltage clamp, 5-HT evoked inward currents associated with the reduction of an outwardly rectifying potassium conductance. 4. The 5-HT2 receptor agonist alpha-methyl-5-HT mimicked the 5-HT response on all neurones, as did the 5-HT1 receptor agonist 5-carboxamidotryptamine (5-CT) on 71% of SPN. The responses to 5-HT, alpha-methyl-5-HT and 5-CT were inhibited by the 5-HT2 antagonists ketanserin and ritanserin. 5. Pressure ejection of 5-HT over the central canal region could evoke a biphasic inhibitory-excitatory response. This response persisted in TTX, suggesting that an inhibitory 5-HT receptor may be located on the medial dendrites. 6. SPN are powerfully depolarized by 5-HT acting at 5-HT2 receptors, via the closure of an outwardly rectifying potassium conductance. The long duration of the response and the ability of 5-HT to induce rhythmical oscillations suggest that 5-HT may have an important role in regulating SPN excitability.

Modulation of dorsal thalamic cell activity by the ventral pallidum: its role in the regulation of thalamocortical activity by the basal ganglia

The actions mediated by limbic system output projections of the basal ganglia were investigated by studying the effects of ventral pallidum (VP) stimulation on the activity of neurons in thalamic target nuclei, including several of the dorsal thalamic nuclei and the nucleus reticularis, using in vivo intracellular recordings in rats. Intracellular injection of Lucifer yellow was used in a subset of experiments to identify the neurons recorded and to confirm their location with respect to the specific thalamic nuclei targeted. Stimulation of the VP evoked ipsps in 79% of the mediodorsal cells recorded. In the reticular nucleus, 73% of the neurons tested responded with evoked ipsps. In contrast, in other dorsal thalamic nuclei VP stimulation evoked depolarizations in 58% of the cells recorded. The latency to onset of the ipsps in the mediodorsal nucleus and in the reticular nucleus were not substantially different (1.7 +/- 1.1 msec vs. 2.7 +/- 1.1 msec), whereas the depolarizing response evoked in dorsal thalamic nucleus neurons typically occurred at longer and more variable latencies (3.5 +/- 2.7 msec). These experiments support a dual functional role for limbic system output from the basal ganglia in the regulation of thalamocortical activity: a) a direct inhibitory projection from the VP to the mediodorsal nucleus and b) an indirect disinhibition of neurons in other dorsal thalamic nuclei that occurs via a direct inhibitory projection to the reticular nucleus of the thalamus. Such an anatomical arrangement may be relevant to the presence of hypofrontality and the breakdown of cognitive filtering observed in schizophrenics.

Cell body and dendritic tree size of intracellularly labeled thalamocortical projection neurons in the ventrobasal complex of cat

Fifteen thalamocortical projection (TCP) neurons from the adult cat ventrobasal complex (VB) were intracellularly labeled with horseradish peroxidase or neurobiotin and examined quantitatively. We find that cat TCP neurons share key morphological features and form one neuronal type. Previously reported variations in dendritic appearance cannot be supported by the present quantitative data. The number of dendrites varied between 4 and 13 (mean 9.1; +/- 4.0) and the total dendritic length of adult cat VB neurons varied between 9,421 and 19,646 microns (mean 13,120 microns; +/- 2,605). Linear regression analyses showed that soma diameter or cross-sectional area measurements provide a poor estimate for total dendritic length in TCP neurons. In contrast, the number of first order dendrites or the sum of first order dendrite diameters do provide a good estimate of overall TCP neuron size. This relationship is useful in predicting total dendritic length when it is not possible to reconstruct the entire dendritic tree. The mean dendritic path distance (distance from soma to the dendritic tip measured along the dendrite) was relatively constant for all neurons regardless of differences in total dendritic length or the number of branches that form the path distance.

Dye-coupling between vagal motoneurones within the compact region of the adult rat nucleus ambiguus, in-vitro

The electrophysiological and morphological characteristics of vagal motoneurones lying within the compact region of the nucleus ambiguus were investigated in thin coronal slices of the adult rat medulla utilising intracellular recording techniques. The majority of neurones were found to be silent, displaying no underlying synaptic activity or oscillations in membrane potential. Intracellular dye-filling demonstrated that the neurones had multipolar cell bodies, with 2-8 major dendrites, each branching up to 4 times and extending up to 200 microns from the cell body. The existence of dye-coupling between adjacent neurones was shown in 30% of cells investigated. This evidence suggests a possible mechanism for the provision of synchronous activity within groups of vagal motoneurones, a process essential for the control of deglutination.

Birthdates of neurons in the retinal ganglion cell layer of the ferret

The present study determined the temporal and spatial patterns of genesis for neurons of different sizes in the retinal ganglion cell layer of the ferret. Fetal ferrets were exposed to tritiated thymidine on embryonic days E-22 through E-36. One to 3 months after birth, they were perfused and their retinae dissected, and autoradiographs were prepared from resin-embedded sections throughout the entire flattened retinal ganglion cell layer. Soma size differences in conjunction with separate retrograde labeling and calbindin immunocytochemical studies were used as criteria for identifying different retinal ganglion cell subtypes in juvenile and adult ferrets. Neurons of different sizes in the ganglion cell layer were generated at different stages during development. Medium sized cells were generated primarily between E-22 and E-26; the largest cells were generated between E-24 and E-29; small cells were generated between E-26 and E-32; and very small cells were generated between E-29 and E-36. The former three groups were interpreted to be three subtypes of retinal ganglion cells, while the latter group was interpreted to be displaced amacrine cells. This temporal order of the genesis of ganglion cell classes is consistent with the spatial ordering of their fibers in the mature optic chiasm and tract, and it is consistent with the developmental change in decussation pattern recently shown in the optic pathway of embryonic ferrets. The spatial pattern of genesis suggests that ganglion cells of a particular class are added to the ganglion cell layer in a centroperipheral fashion initiated in the dorsocentral retina nasal to the area centralis. No evidence was found for a wave of ganglion cell addition that proceeded in a spiralling pattern around the area centralis, as has been reported in the cat.

Identification and characterization of striatal cell subtypes using in vivo intracellular recording and dye-labeling in rats: III. Morphological correlates and compartmental localization

In the first two reports of this series, in vivo intracellular recording techniques were used to characterize the electrophysiological properties of two types of striatal neurons that had been identified by their distinct response patterns to stimulation of corticostriatal afferents. In this paper, we examined whether cells showing Type I or Type II response patterns also differed with respect to their morphology or compartmental localization by combining intracellular recording and Lucifer yellow staining with immunocytochemical localization of calbindin 28 kd immunoreactivity. In the majority of cases, both Type I and Type II neurons exhibited similar morphological characteristics, with 80% of the Type I cells (13/16) and all of the Type II cells (n = 40) being small or medium spiny neurons. In each case where the morphological class of the cell was different than the spiny cell class, the cell exhibited a Type I response pattern. These spiny neurons had somata that averaged 17.1 +/- 1.3 microns in diameter and gave rise to between four and eight primary dendrites. The axons typically arose from cell bodies (7/13 for Type I and 25/40 for Type II cells) and emitted extensive local axonal collaterals. However, the axons of Type I cells more frequently originated from the dorsal surface of the somata (9/13; 69%), whereas Type II axons more frequently arose from the ventral surface of the somata (25/35; 71%), which may account for their different extracellular waveforms. In coronally sectioned tissue (n = 18), the axons always projected laterally when the somata were located in the medial striatum and projected medially when the somata were in the lateral striatal region. In a subset of experiments (N = 22), Lucifer yellow-stained neurons were localized with respect to their position within the patch and matrix compartments of the striatum using subsequent staining for calbindin 28 kd immunoreactivity. Of the 20 labeled medium spiny neurons examined (Type II: N = 13; Type I: N = 7), 19 were located in the calbindin-positive matrix compartment. The only neuron localized to the patch compartment was a medium spiny cell that exhibited a Type II paired impulse response pattern. In addition, of the two aspiny neurons from this group with beaded dendrites, one was localized to the border between adjacent patch and matrix compartments, whereas the other was located completely within the matrix compartment. Therefore, despite their distinct paired impulse response patterns, the majority of both Type I and Type II neurons were medium spiny cells located in the matrix compartment of the striatum.(ABSTRACT TRUNCATED AT 400 WORDS)

Synaptic- and agonist-induced chloride currents in neonatal rat sympathetic preganglionic neurones in vitro

1. By using the whole-cell recording configuration of the patch-clamp technique in a spinal cord slice preparation, we have made recordings from visually identified neurones in the lateral horn of the thoracic and lumbar spinal cord of neonatal rats (newborn to 14 days postnatal). 2. Some of the recorded neurones were labelled with the fluorescent dye Lucifer Yellow (n = 27). Their morphology was typical for sympathetic preganglionic neurones (SPNs). Based on the size of the cell soma and the electrophysiological properties, unlabelled neurones were also regarded as SPNs. 3. Spontaneous synaptic activity of different patterns could be observed in 73% of the recorded neurones (n = 106). It reversed at the chloride equilibrium potential (ECl) and could be reversibly blocked by strychnine (1-10 microM), but not by bicuculline (10 microM) or SR95531 (5-10 microM). 4. Synaptic activity could be elicited by focal electrical stimulation in the vicinity of the recorded neurone. These evoked synaptic events exhibited features similar to the spontaneous synaptic activity. 5. Application of glycine (100 microM-1 mM) by a fast microperfusion system induced a chloride current in twenty-seven out of thirty cells tested. The currents were reversibly blocked by strychnine (1-10 microM), but were only weakly sensitive to bicuculline (10 microM). Stability of current responses to glycine was increased by inclusion of ATP (4 mM) in the intracellular medium. 6. Application of gamma-aminobutyric acid (GABA; 100 microM-1 mM) by the fast microperfusion system induced a chloride current in all twenty neurones tested. These currents were reversibly blocked by bicuculline (10 microM). Strychnine (1-10 microM) blocked this current only weakly. Run-down of GABA-induced currents was prevented to a great extent by inclusion of ATP (4 mM) in the pipette. 7. These results suggest that the inhibitory synaptic activity recorded from SPNs in thin, transverse slices of neonatal rat spinal cord is mediated by glycine receptor-gated Cl- channels. GABAA receptor-gated Cl- channels might be activated by inputs from other spinal segments and/or descending pathways from higher brain regions.

Expiratory neurons of the Bötzinger Complex in the rat: a morphological study following intracellular labeling with biocytin

The term "Bötzinger Complex" (BOT) refers to a distinct group of neurons, located near the rostral portion of the nucleus ambiguus, which are known to play an important role in the control of respiratory movements. Previous studies conducted in cats have demonstrated that most of these neurons are active during expiration, exerting a monosynaptic inhibitory action on several subpopulations of inspiratory neurons in the medulla and spinal cord. The aim of this study was to examine morphological properties and possible synaptic targets of BOT neurons in the rat. Forty-one expiratory neurons were labeled intracellularly with biocytin; 12 were interneurons (BOT neurons) and 29 were motoneurons. The latter could not be antidromically activated following stimulation of the superior laryngeal or vagal nerves. BOT neurons showed extensive axonal arborisations in the ipsilateral medulla, with some projections to the contralateral side. Bouton-like axon varicosities mainly clustered in two areas: near the parent cell bodies, and in the area corresponding to the rostral part of the ventral respiratory group (VRG). In five pairs of labeled neurons, each consisting of one BOT neuron and one inspiratory neuron in the rostral VRG, no appositions were identified at the light microscopic level between axons of BOT neurons and dendrites or cell bodies of inspiratory neurons. These results demonstrate that some features of BOT expiratory neurons in the rat are similar to those previously described in cats. The differences include their more ventral location in relation to the compact formation of nucleus ambiguus (retrofacial nucleus), and the relative paucity in the rat of neurons displaying an augmenting pattern of activity and of neurons with spinally projecting axons. In addition, we were unable to find morphological evidence for contacts between labeled BOT neurons and ipsilateral inspiratory neurons near the obex level, a finding not consistent with previous electrophysiological studies in the cat in which such synaptic connections have been identified.

Depression of glutamatergic and GABAergic synaptic responses in striatal spiny neurons by stimulation of presynaptic GABAB receptors

The influence of gamma-aminobutyric acidB (GABAB) receptor stimulation on the excitatory and inhibitory synaptic potentials and membrane properties of identified striatal spiny neurons was examined in a corticostriatal slice preparation. Stimulation of the subcortical white matter evoked a monosynaptic, excitatory postsynaptic potential (EPSP) and a polysynaptic, inhibitory postsynaptic potential (IPSP) in spiny neurons. The EPSP had two components: a large amplitude response which could be blocked by the kainate/quisqualate receptor antagonist, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 10 microM), and a small amplitude, long-duration depolarization which could be blocked by the N-methyl-D-aspartate receptor antagonist, d-(-)-2-amino-5-phosphonovaleric acid (APV, 100 microM). The IPSP was observed as a membrane depolarization when recorded from neurons at resting membrane potential. However, when neurons were injected with the Na(+)-channel blocker, QX-314, allowing cells to be depolarized above their spike thresholds, a prominent hyperpolarizing IPSP was readily observed which could be blocked by the GABAA antagonist, bicuculline (10-50 microM). This bicuculline-sensitive IPSP was responsible for the inhibition of EPSP amplitude and probability of spike discharge revealed using paired stimulation of the subcortical white matter. The amplitude of both the EPSP and the IPSP were depressed by the GABAB receptor agonist, p-chlophenyl-GABA (baclofen, 0.5-100 microM) in a concentration-dependent manner. Baclofen also blocked paired stimulus inhibition of spike discharge. These effects of baclofen persisted in slices in which the cortex was removed and were reversed by the GABAB receptor antagonist, 3-amino-3-hydroxy-2-(4-chlorophenyl)-propanesulphonic acid (saclofen, 100-500 microM). In contrast to its profound influence on synaptic input, baclofen did not alter resting membrane potential, input resistance, membrane current-voltage relationship, or spike threshold of the cells recorded, and therefore did not appear to exert direct postsynaptic effects on the striatal spiny neurons. Taken together, these data indicate that the depressant effects of baclofen on EPSPs are mediated through GABAB receptors located on the terminals of glutamatergic afferents within the striatum. Moreover, the results suggest that the actions of baclofen on IPSPs and paired stimulus inhibition are produced by activation of GABAB receptors within the striatum at a site presynaptic to spiny neurons, either on the terminals of GABAergic afferents or on an interposed non-spiny GABAergic cell. Thus, GABAB hetero- and auto-receptors have the capacity to provide a negative feedback mechanism through which the major excitatory and inhibitory inputs to striatal spiny neurons are regulated.

Differences in Fluorogold and wheat germ agglutinin-horseradish peroxidase labelling of bladder afferent neurons

Rat urinary bladder afferent neurons were significantly smaller (34%) when labelled with Fluorogold (FG) than when labelled with wheat germ agglutinin-horseradish peroxidase (WGA-HRP). This study showed that this difference was due to an artifact of tissue processing (ethanol dehydration) and was not due to uptake and transport of the two tracers by two different subpopulations of bladder afferents.

Physiological and morphological properties of accumbens core and shell neurons recorded in vitro

The morphology and electrophysiological properties of neurons in the nucleus accumbens were studied using intracellular recording techniques in rat brain slices maintained in vitro. Neurons were subdivided according to their location in the shell or core region of the nucleus accumbens. Most of the cells in both regions had small to medium-sized (15.8 +/- 2.8 microns) somata with densely spinous dendrites, somewhat similar to the striatal medium spiny neuron. However, minor morphological differences between neurons from accumbens core and shell regions were found, such as fewer primary dendrites in shell neurons than in the core (3.8 +/- 0.8 vs. 4.4 +/- 1.0) and the spatial organization of their dendritic trees. In general, the passive membrane properties of neurons in each region were similar. However, shell neurons appeared to be less excitable in nature, as suggested by (1) a faster time constant, (2) the absence of TTX-insensitive events resembling low-threshold spikes, and (3) the lower probability of evoking spikes in shell neurons by stimulation of amygdaloid or cortical afferents in comparison to the responses of core neurons to cortical afferent stimulation. In most nucleus accumbens neurons the action potentials evoked by membrane depolarization were preceded by a slow Ca(2+)-dependent depolarization and showed firing-frequency adaptation. Following TTX administration, all-or-none spike-like events resembling high-threshold calcium spikes were observed in both regions. In summary, except for minor differences, most of the properties of core and shell neurons are similar, supporting their characterization as subdivisions of a single structure. Therefore, differences in the functional properties of these neuronal populations are likely to be due to their distinct connectivity patterns.

Spiny neurons of area CA3c in rat hippocampal slices have similar electrophysiological characteristics and synaptic responses despite morphological variation

Area CA3c is an area of morphologically diverse neurons. In addition to the presence of interneurons and pyramidal cells that are similar to those found in other subfields of area CA3, many neurons of area CA3c are different. They do not resemble interneurons, since they bear numerous spines, yet they also differ substantially from pyramidal cells in their morphology. To determine if the variants of area CA3c spiny cells are distinct physiologically as well as morphologically, intracellular recordings were made to record the electrophysiological properties of area CA3c cells in rat hippocampal slices, and each cell was identified morphologically following intracellular dye injection. The results show that the spiny cells, regardless of their often extensive morphological variation, have relatively uniform, pyramidal-like electrophysiological properties. The aspiny cells are quite different from the spiny cells morphologically (i.e., in their paucity or complete lack of spines), and are also extremely different electrophysiologically, exhibiting features of "fast-spiking" cells. Thus, spiny cells in area CA3c correspond to cells with pyramidal-like electrophysiology, and the aspiny cells in area CA3c correspond to cells with interneuronal physiological properties. This correlation between structure and function appears to be a rule that pertains to each of the subfields of the hippocampus.

Medial vestibular nucleus in the guinea-pig: histaminergic receptors. I. An in vitro study

Antihistaminergic drugs are currently used for the symptomatic treatment of vestibular-related syndromes such as vertigo and motion sickness. We therefore investigated whether histamine could modulate the firing of medial vestibular nuclei neurons (MVNn). Recently, we have demonstrated that different cell types are present among MVNn in guinea-pig brainstem slices. Bath-application of histamine at 10(-4) or 10(-5) M induced a small membrane depolarization accompanied by a slight decrease in membrane resistance and a reversible increase in spontaneous firing in all MVN cell types. These effects were presumably postsynaptic as they persisted in a low-calcium/high-magnesium solution. Using a variety of agonists and antagonists of histamine receptors (H1, H2 and H3), we conclude that these effects are mediated by H2 receptors. The companion paper is concerned with an in vivo study of the histaminergic modulation of the vestibular function (Yabe et al., in press).

Intracellular injection in fixed slices in combination with neuroanatomical tracing techniques and electron microscopy to determine multisynaptic pathways in the brain

Intracellular Lucifer Yellow filling in fixed tissue has been recently introduced as a novel neuroanatomical approach to reveal the detailed morphology of individual neurons in isolated preparations of the central nervous system. Since dye injections are performed under visual control, the method is characterized by a high degree of inherent staining selectivity, thus circumventing the element of randomness often considered to be the crux of classical golgi-impregnation techniques. Moreover, the opportunity to optically monitor the injection procedure renders fixed slice preparations highly advantageous to be used in combination with retrograde fluorescent tracing. Subsequently, dye-filled neurons may be subjected to a simple photoconversion procedure leading to the intracellular formation of a stable polymer thus obtaining permanent specimens for light microscopy purposes. Due to the osmiophilic nature of the precipitate the photoconverted material is equally suitable for correlated electron microscopy, thus enabling the analysis of neuronal microcircuitry. At the ultrastructural level, sources of afferent input to identified projection neurons may be revealed by lesion-induced anterograde degeneration of synaptic terminals, therefore enabling the direct demonstration of multisynaptic links. Finally, morphologically identified neurons may be immunocytochemically characterized at the pre- and postembedding levels. It is therefore suggested that their methodological versatility and relative technical ease render intracellular fixed-slice injections a promising complement to the catalogue of anatomical techniques.

Morphological and electrophysiological evidence for electrotonic coupling of rat dorsolateral septal nucleus neurons in vitro

Intracellular injections of Lucifer Yellow were utilized to evaluate the incidence of dye-coupling among dorsolateral septal nucleus (DLSN) neurons recorded from slice preparations of adult rat septal nuclei. Twenty percent of single injections of Lucifer Yellow resulted in pairs of labeled neurons. These dye-coupled cells were morphologically heterogeneous and did not exhibit any morphological characteristics that could be used to distinguish them from non dye-coupled neurons. The spatial separation of cell bodies and close apposition of dendrites within each pair indicated that the dye transfer site(s) were situated at dendrodendritic and/or dendrosomatic rather than somatosomatic junctions. The main axon of some dye-coupled neurons gave rise to intrinsic axon collaterals prior to exiting the nucleus indicating that these coupled neurons function as projection neurons as well as local circuit interneurons. Electrophysiological recordings of the passive membrane properties and spontaneous activity of individual dye-coupled neurons revealed no significant difference from non dye-coupled cells in the DLSN. Some neurons exhibited spontaneously occurring fast potentials which presumably represent electrotonic potentials. These fast potentials were often tightly coupled with action potentials but could be distinguished from synaptic potentials by their shape and their lack of voltage-dependent changes in amplitude. These morphological and supportive electrophysiological data provide the first indirect evidence for electrotonic coupling of dorsolateral septal neurons. The functional significance of this coupling may lie in the potential for synchronization of the output of the DLSN which could play an important role in the septal maintenance and modulation of hippocampal Theta rhythm.

Anatomical and electrotonic coupling in developing genioglossal motoneurons of the rat

Dye-, tracer- and electrotonic coupling were studied independently in genioglossal (GG) motoneurons using intracellular recordings in in vitro brainstem slices from rats postnatal ages 1-30 days. The subpopulation of GG motoneurons were retrogradely labeled after an injection of dextran-rhodamine into the posterior tongue. Dye-coupling was studied with Lucifer yellow injected into 55 motoneurons and tracer-coupling with neurobiotin injected into 89 presumptive GG motoneurons. Of the motoneurons injected with Lucifer yellow, only 6 of 41 cells (16.2%) exhibited dye-coupling; all occurred in animals less than 9 days old. In all but one instance, dye-coupling was restricted to only one other cell. No evidence of dye-coupling was found in the 14 cells injected in animals older than 8 days. Tracer-coupling (neurobiotin) was demonstrated in 12 of 30 cells (40%) from animals 1-2 days old and in 6 of 21 cells (28.6%) from animals 3-8 days old. Of the remaining 38 cells from animals 10 days of age and older, only one cell was found to be tracer-coupled. Cells injected with neurobiotin were coupled to an average of two other cells. Electrotonic coupling, as demonstrated with a short latency depolarization (SLD) in response to stimulation of hypoglossal axons, was found in developing GG motoneurons. These SLDs were revealed in 17 of 40 GG motoneurons (42.5%) examined in 1-8-day-old animals. There were no SLDs recorded in the 10 cells examined from animals of 10 days and older. The significance of coupling relative to patency of the newborn upper airways is discussed.

Measurement of neuronal surface area using high-voltage electron microscope tomography

High-voltage electron microscopy (HVEM) and axial tomography were used to reconstruct the three-dimensional structure of dendrites of intracellularly stained neostriatal spiny neurons. Neurons were stained using iontophoretic injection of horseradish peroxidase from an intracellular micropipet. Thick sections were cut on a vibratome, reacted with diaminobenzidine, and embedded in plastic. High-voltage electron microscopy was used to obtain high-resolution images of neuronal processes in 2- to 3-micron plastic sections cut from those blocks. Series of high-voltage electron micrographs were taken at 2 degrees increments of specimen tilt over a range of at least +/- 60 degrees, and three-dimensional reconstructions were generated from the series using an R-weighted backprojection method. An interactive procedure was used to draw the dendritic profiles from slices through the reconstructed volume and to measure volumes and surface areas of the dendrites. Values obtained in this manner matched previous findings using reconstruction from serial thin sections. The HVEM-tomography method offers an alternative to the serial-thin-section method for the quantitative analysis of neuronal shape.

NADPH diaphorase in the spinal cord of rats

To identify spinal neurons that may synthesize nitric oxide, cells and fibers histochemically stained for NADPH diaphorase (a nitric oxide synthase) were studied in the spinal cord of rats. The histochemical reaction gave an image similar to the best Golgi impregnations, staining cells down to their finest processes. Transverse, horizontal, and parasagittal 50 and 100 microns sections were used to follow dendritic and axonal arborizations of stained neurons. Major cell groups were identified in the superficial dorsal horn and around the central canal (at all spinal levels), and in the intermediolateral cell column (at thoracic and sacral levels). Scattered positive cells were also found in deeper dorsal horn, ventral horn, and white matter. In some cases, axons of cells in the dorsal horn could be traced into the white matter; many of these cells resembled neurons projecting to various supraspinal targets. Stained cells in the intermediolateral column, which sent their axons into the ventral root, were presumed to be preganglionic autonomic neurons. Dense plexes of fibers were stained in laminae I and II and in the intermediolateral column. A large number of NADPH diaphorase-positive neurons in the spinal cord appear to be involved in visceral regulation. Fibers of the intermediolateral system had a special relationship with vasculature, suggesting that nitric oxide may help to couple neural activity with regional blood flow in the spinal cord. The abundance of NADPH diaphorase-positive neurons and fibers in the superficial dorsal horn suggests that nitric oxide may also be involved in spinal sensory processing.

Morphological analysis of the neurons in the area of the hypothalamic magnocellular dorsal nucleus of the guinea pig

In the guinea-pig hypothalamus, a group of enkephalinergic cells forms a well-circumscribed nuclear area called the magnocellular dorsal nucleus (MDN). This nucleus gives rise to a prominent projection to the lateral septum: the hypothalamo-septal enkephalinergic pathway. In the present study, MDN neurons visualized by Golgi impregnation were subjected to morphological analysis in order to define the potential segregation of cellular types within the MDN. This study was complemented by additional observations of MDN neurons intracellularly injected by Lucifer yellow (LY) or horseradish peroxidase (HRP) during the in vitro incubation of hypothalamic slices. The following results were obtained from the analysis of 200 neurons: 163 Golgi-impregnated cells plus 37 injected cells (LY = 14; HRP = 23). Thirteen HRP-injected cells were precisely located in the MDN and 10 were located in the perifornical area surrounding the MDN. Four different cellular types were identified. Type-I neurons (41%) displayed a globular perikaryon, a variable number of primary dendrites that were poorly ramified, no preferential orientation, and an axon emerging from the perikaryon. Type-II neurons (30.5%) had a triangular perikaryon, three well-ramified primary dendrites, an orientation perpendicular to the third ventricle, and an axon emerging from the perikaryon. Type-III neurons (22%) exhibited a spindle-shaped perikaryon, two opposed well-ramified primary dendrites, an orientation perpendicular to the third ventricle, and an axon emerging from a primary dendrite. Type-IV neurons (6.5%), showed a globular perikaryon, a variable number of primary dendrites, poorly ramified dendrites, an orientation parallel to the third ventricle, and an axon whose orientation could not be identified. Neurons labeled after intracellular injection belonged to the first three cellular types.

Changes in size and dendritic arborization patterns of adult cat spinal alpha-motoneurons following permanent axotomy

This study was performed to analyse quantitatively the changes in dimensions and dendritic branching patterns of adult cat spinal alpha-motoneurons following permanent axotomy, i.e., in a situation in which the transected motoraxons are prevented from reinnervating their peripheral target muscle. After transection and ligation of the medial gastrocnemius nerve of adult cats, homonymous alpha-motoneurons were intracellularly labelled with horseradish peroxidase and subjected to quantitative light microscopic analyses. The cell bodies and proximal dendrites were studied at 3, 6, and 12 weeks after the axotomy. An initial increase in cell body size at 3 weeks was followed by a gradual return towards normal values. The mean diameter of the stem dendrites was decreased at all time periods studied, and the combined diameter of the stem dendrites was reduced at 12 weeks after the axotomy. Entire dendritic trees were reconstructed at 12 weeks postoperatively, and the regression equations describing the correlations between dendritic stem diameter, on one hand, and the size of the entire dendrite, on the other, were used to calculate the total dendritic length, volume, and membrane area of whole axotomized motoneurons. The dendritic branching patterns were also analysed. In comparison with normal medial gastrocnemius alpha-motoneurons, the dendritic membrane area and volume of the axotomized cells had decreased by 36% and 29%, respectively, at 12 weeks after the axotomy. This reduction in dendritic size was due to a loss of preterminal and terminal dendritic segments. Abnormal dendritic elongations were observed in 2 of 16 completely reconstructed dendrites.

Morphology of single medial vestibulospinal tract axons in the upper cervical spinal cord of the cat

The morphology of single medial vestibulospinal tract (MVST) axons was investigated by iontophoretic injection of horseradish peroxidase into single axons at the upper cervical cord in pentobarbital-anesthetized cats. MVST axons were identified by their monosynaptic responses to stimulation of the vestibular nerve and their direct responses to stimulation of the medial longitudinal fusciculus (MLF). Reconstructions of the axonal trajectory were made from 22 uncrossed and 19 crossed MVST axons at C1-C4. MVST axons ran in the ventral funiculus and gave rise to multiple axon collaterals to the upper cervical gray matter at different segments. These axons could be traced over the distance of 2.5-15.3 mm. Within these lengths, up to 9 axon collaterals were identified per axon (mean +/- s.d., 3.3 +/- 2.0, n = 41). Axon collaterals ramified in the gray matter several times and spread in a delta-like manner in both the transverse and horizontal planes. There were usually gaps free from terminal arborizations between adjacent axon collaterals, since the rostrocaudal extension of individual axon collaterals (mean = 820 microns) was very much limited in contrast to wide intercollateral intervals (mean = 1,510 microns). Axon terminals were distributed mainly in laminae IX, VIII, and VII, and sometimes in laminae VI-IV. Most abundant terminals were observed in lamina IX, including the ventromedial (VM), the spinal accessory (SA) nuclei and the nucleus dorsomedial to the VM nucleus (DM nucleus). A majority of individual axon collaterals provided some terminal branches to at least one of the above three motor nuclei. Axon collaterals projecting to laminae VIII-VI without terminals in the motor nuclei were rarely observed. Individual MVST axons had a preferential terminal distribution in each motor nucleus, but all three motor nuclei were covered by axon terminals of an ensemble of all MVST axons, indicating that all neck muscles innervated by these three motor nuclei are influenced by vestibular inputs through MVST axons. Most collaterals from a single axon produced circumscribed terminal arborizations in one or two common areas in the transverse plane (mainly in lamina IX) that were in line with one another in the longitudinal axis of the cord. This longitudinal arrangement of discontinuous terminal arborizations in lamina IX from a single axon may correspond to a continuous sagittal column of motoneurons for a particular muscle.(ABSTRACT TRUNCATED AT 400 WORDS)

Whole-cell recordings from sympathetic preganglionic neurons in rat spinal cord slices

Whole-cell patch-clamp recordings (WCR) were made from sympathetic preganglionic neurons (SPN) in neonate rat spinal cord slices. SPN were identified histologically by filling them with the fluorescent dye Lucifer Yellow contained within the patch pipette solution. Current clamp recordings were obtained from SPN with a potassium based pipette solution. The cells exhibited many of the characteristic properties of SPN seen previously with intracellular recordings in both the rat and the cat. However, we found an order of magnitude increase in both cell input resistance (950 M omega) and time constant (118 ms) over those seen with conventional recordings. We believe these values approximate better the situation in intact cells, and will have a vital bearing upon how SPN integrate inputs. We conclude that WCR in spinal cord slices provides a powerful tool for investigating the cellular properties of SPN.

Regular mosaics of large displaced and non-displaced ganglion cells in the retina of a cichlid fish

Large retinal ganglion cells in the tilapid cichlid fish Oreochromis spilurus (standard length 15-54 mm) were filled with horseradish peroxidase and studied in flatmounts. Three types, with distinct patterns of dendritic stratification, formed spatially independent, nonrandom mosaics. One type (about 0.3% of all ganglion cells) resembled the outer (off) alpha cells of mammals. They were very large, with thick primary dendrites and large, sparsely branched planar trees in the outer part of the inner plexiform layer (IPL). About 300 were arrayed regularly across each retina, their exact number and spacing depending on its size. Their somata were often displaced into the IPL, even where neighbours in the mosaic were orthotopic. Another type (0.8%) resembled the inner (on) alpha cells of mammals. These had slightly smaller somata that were never displaced and smaller trees in the middle layers of the IPL. About 800 were arrayed uniformly and regularly across each retina. A rarer type (0.06-0.08%) had two planar trees: one forming a coarse mosaic in the outer part of the inner plexiform layer (co-planar with the trees of outer alpha-like cells) and another in the outer plexiform layer. These "biplexiform" cells were smaller and rounder than alpha-like cells and always displaced. The dendrites were finer and less tapered. Cells in which we could identify an outer plexiform tree failed to cover the retina completely, but were nonrandomly distributed. We draw three main conclusions: (1) some nonmammalian vertebrates have separate inner and outer mosaics of large ganglion cells like those of mammals, (2) the vertical displacement of ganglion cell somata can vary widely within a single mosaic and may thus be functionally irrelevant, and (3) biplexiform ganglion cells exist in fish but differ in morphology from the biplexiform types described in some other vertebrates.

Neurophysiological maturation of cat caudate neurons: evidence from in vitro studies

The membrane properties and synaptic physiology of developing cat caudate (Cd) nucleus neurons were studied in in vitro slice preparations. Recordings were obtained from 98 cells in kittens from fetal day (F) 56 to postnatal day (P) 90. With increasing age, the following maturational changes occurred; resting membrane potentials became more negative, action potential rise times decreased, action potential amplitudes increased, and action potential durations and input resistances decreased. The frequency of occurrence of afterhyperpolarizations and of anomalous rectification increased with age. The primary response to local extracellular stimulation was a depolarization usually accompanied by an action potential. Evoked hyperpolarizing responses were seen after P28 but only occurred if the membrane was depolarized by intracellular current injection. Cells identified by intracellular injection of Lucifer yellow were primarily medium-sized spiny neurons although it was not always possible to determine the cell type in slices from animals less than P5. Somatic diameter, dendritic length, and spine density increased with age. Dye-coupling occurred in slices less than P20. Its frequency decreased with age. These results show that Cd neurons undergo significant maturation during late prenatal and early postnatal periods. In contrast, substantia nigra neurons mature more rapidly and should be capable of influencing the less mature Cd neurons during development.(ABSTRACT TRUNCATED AT 250 WORDS)

Neurophysiological maturation of cat substantia nigra neurons: evidence from in vitro studies

The membrane properties and synaptic physiology of developing cat substantia nigra (SN) neurons were studied in in vitro slice preparations. Stable intracellular recordings were obtained from 46 neurons in 20 kittens ranging in age from fetal day (F) 51 to postnatal day (P) 120. Only two of these properties changed with development. The percentage of cells displaying inward rectification and the percentage of cells that generated low-threshold Ca++ spikes increased with age. Properties that did not change included resting membrane potentials, action potential amplitudes and durations, and input resistances. At all ages locally evoked synaptic responses consisted of sequences of excitatory postsynaptic potentials followed by inhibitory postsynaptic potentials. Most of the cells recorded had the electrophysiological properties which have been attributed to SN dopamine-containing neurons. To identify neurons morphologically, and verify the recording site, cells were filled with Lucifer yellow at the end of each experiment. Somatic shapes varied widely from oval to fusiform to triangular. Somatic diameters and dendritic length increased with development. Filopodial processes and growth cones were present up to the first postnatal month. Dye-coupling occurred only in the fetal group. These results indicate that cat SN neurons have many mature physiological properties during late fetal and early postnatal development. This contrasts with the significant maturation that occurs in cat caudate neurons during the same developmental period.

In vitro neurons in mammalian cortical layer 4 exhibit intrinsic oscillatory activity in the 10- to 50-Hz frequency range

We report here the presence of fast subthreshold oscillatory potentials recorded in vitro from neurons within layer 4 of the guinea pig frontal cortex. Two types of oscillatory neurons were recorded: (i) One type exhibited subthreshold oscillations whose frequency increased with membrane depolarization and encompassed a range of 10-45 Hz. Action potentials in this type of neuron demonstrated clear after-hyperpolarizations. (ii) The second type of neuron was characterized by narrow-frequency oscillations near 35-50 Hz. These oscillations often outlasted the initiating depolarizing stimulus. No calcium component could be identified in their action potential. In both types of cell the subthreshold oscillations were tetrodotoxin-sensitive, indicating that the depolarizing phase of the oscillation was generated by a voltage-dependent sodium conductance. The initial depolarizing phase was followed by a potassium conductance responsible for the falling phase of the oscillatory wave. In both types of cell, the subthreshold oscillation could trigger spikes at the oscillatory frequency, if the membrane was sufficiently depolarized. Combining intracellular recordings with Lucifer yellow staining showed that the narrow-frequency oscillatory activity was produced by a sparsely spinous interneuron located in layer 4 of the cortex. This neuron has extensive local axonal collaterals that ramify in layers 3 and 4 such that they may contribute to the columnar synchronization of activity in the 40- to 50-Hz range. Cortical activity in this frequency range has been proposed as the basis for the "conjunctive properties" of central nervous system networks.

Stereology: a method for analyzing images

This review deals with notions of shape, sizes, numbers, densities and orientation in space, all basic concepts in stereology. With the initiation by Delesse in 1847, but mainly since the beginning of the XXth century, many stereological methods have been published allowing us to relate two-dimensional measurements easily obtainable on flat histological images with three-dimensional characteristics of the structure analysed. Looking at these methods, the neurobiologist, generally impermeable to concepts of sampling, statistical bias, efficiency, cost of effort and distribution-free, is discountenanced and continues old laboratory usages and customs. Furthermore, for the last ten years, the advent of a plethora of new powerful tools, considered as assumption-free and more efficient than the previous ones, increase the risk proportionately the disarray of the potential user. The purpose of this review is to present synthetically all traditional and actual aspects of stereology in order to guide the reader in the labyrinth of this speciality. The necessarily short exposition is compensated by many references to which the beginner or the initiated can refer.

Changes in size and shape during histochemical preparation for light and electron microscopy of neurons intracellularly labelled with horseradish peroxidase

In this study we show that neurons labelled intracellularly with horseradish peroxidase react differently from surrounding unlabelled neurons in vibratome sections during histological preparations for light and electron microscopy. The diameters and cross-sectional area of the cell bodies of intracellularly horseradish peroxidase-labelled neurons increased by about 6 and 11% respectively, while the surrounding unlabelled neurons decreased by the same amount. Also, the caliber of the proximal dendrites of horseradish peroxidase-labelled neurons increased during the histological preparation while dendritic path lengths remained unchanged. Since the surrounding tissue shrunk, the dendritic path shapes became more tortuous during histological processing. The demonstrated reaction of horseradish peroxidase-labelled neurons is suggested to be caused by the horseradish peroxidase reaction product.

Electrophysiology and lucifer yellow injection of nucleus gigantocellularis neurones in an isolated and perfused guinea pig brain in vitro

Intracellular recordings from nucleus gigantocellularis (NGC) neurones were obtained in isolated and perfused whole brains of guinea pigs in vitro. A majority of cells (90%) were characterized by an action potential of short duration (0.3 ms) followed first by a fast and then by a slower afterhyperpolarization (AHP). Their firing pattern was mostly irregular. These cells were shown to have high threshold calcium spikes and plateau potentials. The other cell type represented only 10% of the recorded cells in the NGC. It was characterized by a wider (0.6 ms) action potential, a large single AHP, the presence of a transient rectification presumably due to an A-current and a rather regular resting discharge. Using Lucifer yellow injections in brainstem slices, both cell types were shown to correspond to gigantocellular neurones.

Single fiber studies of ascending input to the cuneate nucleus of cats: I. Morphometry of primary afferent fibers

The morphology of afferent fibers ascending to the cuneate nucleus has been examined in this and the subsequent paper in order to quantify the pattern of arborization and bouton arrangement of selected classes of primary afferents and to compare these data with data from postsynaptic fibers ascending to the cuneate nucleus. Electrophysiologically identified G hair and Ia muscle afferent fibers in the cuneate fasciculus were intraaxonally injected with horseradish peroxidase. Cutaneous afferents terminated dorsal to proprioceptive afferents, especially at middle levels of the cuneate nucleus. The spacing of collaterals along G hair fibers was variable, but averaged 1.46 collaterals per mm; collateral density was higher at middle cuneate levels than in the rest of the nucleus. Collateral density of Ia fibers was lower than for G hair fibers and was lowest at caudal levels of the nucleus. Branches of G hair collaterals, though often initially diverging, usually converged to terminate in a single focus in the dorsal part of the nucleus. The probability of bifurcation of Ia collaterals decreased steadily at successive branch points. These collaterals branched less symmetrically than G hair collaterals, and terminated in the ventral cuneate with less dense arbors, stretched mediolaterally, but of comparable cross-sectional area. Individual G hair collaterals gave rise to more boutons than Ia collaterals; in both cases they were mostly of the en passant type. Boutons were restricted to distal branches of G hair collaterals, whereas boutons of Ia collaterals were also located on proximal branches. Bouton size was similar for the two classes of collaterals. The data reported here, in combination with the published literature, suggest that the collaterals of roughly 300 G hair fibers overlap at any given point at middle levels of the cuneate nucleus. This high degree of anatomical convergence is not predicted by the functional segregation described with electrophysiological mapping, implying the presence of intrinsic nuclear mechanisms enhancing response specificity.

Neuropeptide Y- and substance P-like immunoreactive amacrine cells in the retina of the developing Xenopus laevis

The development of neuropeptide Y-like (NPY-LI) and substance P-like (SP-LI) immunoreactive neurons was studied in retinas of Xenopus laevis from young tadpole through to adult animals. In adult retina these neuropeptides are present in wide-field amacrine cells located in the inner nuclear layer and the ganglion cell layer of the retina. Retinal wholemount preparations and sectioned material showed that immunoreactive cells appeared during early larval life and NPY-LI occurred earlier than SP-LI cells. The primary dendritic branching of NPY-LI neurons appeared from early larval life whilst SP-LI was evident in dendrites from mid-larval stages. In postmetamorphic animals the numbers of immunoreactive cells increased in proportion to retinal area growth with a relatively constant cell density of about 35 cells/mm2 for SP-LI and 45 cells/mm2 for NPY-LI. The maturation of dendritic morphology of both NPY- and SP-LI amacrine cells appeared later in larval development than the appearance of immunoreactivity in cell somas. However, the sequence of expression of NPY- or SP-LI and their dendritic maturation was different for the two classes of amacrine cells. It is suggested that the maturation of dendritic fields of amacrine cells is complete just prior to metamorphosis, consistent with the postmetamorphic onset of electrophysiological features of ganglion cells attributed to amacrine cells.

A light- and electron-microscopic investigation of the optic tectum of the frog, Rana pipiens, II: The neurons that give rise to the crossed tecto-bulbar pathway

The superficial layers of the frog's optic tectum, Potter's (1969) layers A-G, comprise a complex neuropil made up of many afferent axons, the somata of a few neurons, and many dendrites from the neurons located in the deeper layers. Different types of retinal axons are believed to terminate in different layers (Maturana et al., 1960; Kuljis & Karten, 1988; Sargent et al., 1989), but little is known about the relationships between each type of input and the dendrites of the deep tectal neurons that extend into these superficial layers. The present study used the method of retrograde transport of horseradish peroxidase to study the synaptic contacts on the dendrites of the neurons that give rise to the crossed tecto-bulbar pathway. These cells have apical dendrites that ascend through the superficial retino-recipient layers. The somata of the cells that give rise to the crossed tecto-bulbar pathway are located in the superficial half of layer 6, preferentially clustered along the caudal, lateral, and rostral margins of the tectum. The somata of these cells range from 8-30 microns in diameter. Their axons are large (2-4 microns in diameter) myelinated fibers that arise from either their somata or proximal dendrites. Their axons travel within the deep medullary layer to leave the tectum at the lateral margin. Their dendritic arbors extend obliquely through the superficial layers to reach layer B where they turn and extend within the layer for up to 0.5 mm. The somata of these cells receive only a scant synaptic input. In contrast, their dendrites receive input in every layer, but the nature of this input varies from layer to layer. Synaptic terminals that resemble retinal ganglion cell boutons contact the labeled dendrites in layers B, F, and G. This indicates that the dendrites may receive monosynaptic input from several types of retinal ganglion cells. Terminals with small, flattened vesicles also contact the dendrites of these cells in each layer. In layer F and below, the terminals with flattened vesicles constitute 15% of the contacts; above layer F they constitute only 5-8% of the contacts. Terminals with medium-sized, flattened vesicles also contact the dendrites of these cells in every layer and constitute a large proportion of their input (33-95%). The latter terminals resemble those that are often postsynaptic to retinal terminals.

Dendritic morphology and retinal distribution of tyrosine hydroxylase-like immunoreactive amacrine cells in Bufo marinus

Tyrosine hydroxylase-like immunoreactive (TH-IR) amacrine cells (ACs) in the retina of metamorphosing and adult Bufo marinus were visualized, and their retinal distribution established, using immunohistochemistry on retinal wholemount and sectioned material. The somata of TH-IR ACs were located in the innermost part of the inner nuclear layer (INL). Their dendrites branched predominantly in the scleral sublamina of the inner plexiform layer (IPL), with sparse branching also in the vitreal sublamina. In the retinae of metamorphosing animals 592 +/- 113 (mean +/- S.D.) immunoreactive cells and in adult 5,670 +/- 528 cells were found. Usually 1, 2 or 3 stem dendrites arose from the somata of TH-IR cells which branched 2 or 3 times. In the adult retinae the dendritic field sizes of immunoreactive cells were in the range of 0.059 +/- 0.012 mm2, which resulted in a considerable dendritic overlap across the retina. TH-IR cells were unevenly distributed over the retina, with 72 cells/mm2 in the central temporal retina, 45-50 cells/mm2 along the naso-temporal axis of the retina and 25 cells/mm2 in the dorsal and ventral peripheral retina. The average density was 36 +/- 6 cells/mm2. A considerable number of TH-IR cells (range 52-133, n = 4) were displaced into the ganglion cell layer (GCL) of the retina. The mean soma sizes of immunoreactive cells were significantly higher in the low density (95 +/- 13 microns 2) than in the high cell density areas (86 +/- 12 microns 2).(ABSTRACT TRUNCATED AT 250 WORDS)

An intracellular study of grafted and in situ preoptic area neurones in brain slices from normal and hypogonadal mice

1. Intracellular recordings have been obtained from forty-one preoptic area (POA) neurones at times up to 14 months after they were grafted into the third ventricle of the mouse. Thirty-one neurones were in grafts from hypogonadal (hpg) mice in which a reversal of the hypogonadism was seen (responders), six were in grafts from hpg mice in which no such reversal occurred (non-responders) and four were in grafts from normal mice. 2. The grafted neurones had a mean resting potential (Em) of -57 mV, a mean apparent input resistance (Rm) of 136 M omega and a mean membrane time constant (tau m) of 7.7 ms. The slopes of the current-voltage (I-V) relations were linear. Approximately a quarter of neurones in responders fired action potentials spontaneously either singly or in bursts. Such activity could underlie the release of gonadotrophin hormone-releasing hormone (GnRH) which is known to occur from such grafts. 3. Two types of response were seen when these neurones were depolarized to firing threshold from Em, in one group a single action potential was discharged; in the other group one or more action potentials arising from a transient, slowly rising and falling depolarization (low-threshold response, LTR) was recorded. Some cells in the former category exhibited a LTR when depolarized from a potential more negative than Em. 4. The commonest response to stimulation of the median eminence in responders was an EPSP either alone or in combination with an IPSP. Antidromic action potentials were seen in four neurones and in two of these cells excitatory synaptic inputs could be demonstrated when the host hypothalamus adjacent to the graft was stimulated. It is suggested that these responses may represent activation of an afferent input from the host to neurones in the graft. 5. The morphology of neurones in POA grafts was determined by intrasomatic injection of horseradish peroxidase (HRP). A variety of profiles were seen and although some neurones extended over distances of up to 635 microns and branched extensively only one appeared to enter the host tissue at the ventrolateral edge of the graft. 6. A comparison was made between grafted POA neurones and cells in the medial preoptic area (MPOA), a region which constituted a significant component of the grafted tissue. No significant difference was noted between neurones in the graft and neurones in the MPOA in terms of their passive membrane properties. With regard to the active properties MPOA neurones could also be classified according to whether or not a LTR was elicited when the neurone was depolarized from Em. The major difference between the grafted neurones and those in the MPOA lay in the proportion of cells which exhibited a LTR under such conditions, being significantly greater in the latter group.

Neonate rat sympathetic preganglionic neurons intracellularly labelled with lucifer yellow in thin spinal cord slices

Sympathetic preganglionic neurons and interneurons were intracellularly labelled with lucifer yellow in thin transverse spinal cord slices of neonatal rats. Preganglionic neurons had spindle or oval shape somata and were located in the intermediolateral nucleus. The axons of these neurons coursed ventrally along the border of gray matter and exited the ventral horn; two to four long dendrites projected medially to the central canal and several relatively short dendrites oriented toward the lateral white matter. Interneurons were generally multipolar and located outside the immediate area of intermediolateral nucleus; their axons could sometimes be traced to the ventral funiculus. Interestingly, dye-coupled preganglionic neurons were observed for the first time. Our findings suggest that the dendritic domain of neonatal rat sympathetic preganglionic neurons is out-reaching and may represent potential sites of interaction with incoming segmental and/or descending inputs. In addition, the observation of dye-coupled preganglionic neurons raises the possibility that these neurons may have the capability of recruiting and/or synchronizing sympathetic outflow.

Osmotic effects upon excitability in rat neocortical slices

Acute osmotic disturbances can lead to profound neurological problems, yet there has been little experimentation at a cellular level to assess if neurophysiological changes are induced by altered osmolality. Using extra- and intracellular recording in the rat neocortical slice preparation, we examined pyramidal neurons of layers II-III under changing osmotic conditions. Single cell properties, field potentials, synaptic transmission and epileptiform discharges were studied in control saline (295 mOsm) and compared with corresponding data collected during exposure to osmolalities between 245 and 375 mOsm. Single cell properties (resting membrane potential, cell input resistance, action potential threshold and duration) did not change significantly, but neuronal interactions were considerably influenced by osmotic change within minutes. Hyposmolality increased the amplitude of evoked field potentials and of excitatory postsynaptic potentials recorded intracellularly. Hyperosmolality, induced with mannitol, decreased these parameters. Electrotonic coupling, as gauged by the degree of dye coupling and by cell input resistance, was not influenced by shifts in osmolality. The clinical finding that overhydration promotes seizure onset was examined in slices made epileptogenic in Mg2(+)-free saline. Hyposmolality increased the frequency and decreased the duration of interictal bursts, whereas raising osmolality with mannitol had opposite effects. None of the aforementioned effects occurred when osmolality was increased with a freely permeable substance such as dimethylsulfoxide, nor could they be ascribed to changes in saline Na+ or Ca2+ concentrations. The results are consistent with hyposmotic solutions reducing extracellular space by causing cells to swell. Theoretically, during population discharge, this should both concentrate K+ released extracellularly and possibly increase field (ephaptic) interactions. How lowered osmolality strengthens spontaneous and evoked excitatory synaptic transmission in neocortex is not yet clear. However, it may be an important mechanism underlying the increased seizure susceptibility of patients and experimental animals with lowered plasma osmolality. Conversely, suppression of excitatory postsynaptic potentials by osmotically active substances may be involved in the lowered seizure susceptibility observed clinically.

Neuropeptide Y-like immunoreactive amacrine cells in the retina of Bufo marinus

Neuropeptide Y-like immunoreactive (NPY-LI) amacrine cells of the Bufo marinus retina were morphologically characterized, and their retinal distribution was established using immunohistochemistry on retinal wholemount preparations and sectioned material. The somas of NPY-LI amacrine cells were situated in the innermost part of the inner nuclear layer and their dendrites branched primarily in the scleral sublamina of the inner plexiform layer. A subgroup of the NPY-LI cells had dendrites in both the scleral and vitreal sublamina. All immunoreactive cells had large dendritic fields (average 0.5 mm2) that resulted in a high dendritic overlap across the retina. NPY-LI amacrine cells were evenly distributed across the retina, with an average density of 30 cells/mm2, although higher densities were observed at regions adjacent to the ciliary margin. The dendritic field size of the NPY-LI cells, together with the previously characterized substance P-like immunoreactive (SP-LI) amacrine cells, indicates that they belong to the class of wide-field amacrine cells. However, unlike the SP-LI neurons whose dendrites branch in the vitreal sublamina of the inner plexiform layer, the dendrites of the majority of the NPY-LI neurons branch in the scleral sublamina.

In vitro electrophysiology of neurons in the lateral dorsal tegmental nucleus

The lateral dorsal tegmental nucleus (LDT) provides ascending cholinergic projections to forebrain structures such as prefrontal cortex, septum, habenula, and thalamus, but relatively little is known of the physiology of LDT neurons. Intracellular recordings from LDT neurons in guinea pig brain slices found that most neurons fired action potentials either tonically or in bursts. The voltage dependent characteristics of the neurons suggest that a prolonged afterhyperpolarization due to an outward potassium current and a low-threshold calcium conductance contributed to these two modes of firing. Intracellular injections of Lucifer Yellow and subsequent staining for NADPH-diaphorase activity permitted positive identification of cholinergic neurons.

Morphological characterization of substance P-like immunoreactive amacrine cells in the anuran retina

Using substance P immunohistochemistry it was possible to demonstrate a class of morphologically homogeneous group of neurons in the inner nuclear layer (INL) of the retina of two anuran species: Xenopus laevis and Bufo marinus. The number of cells with substance P-like immunoreactivity (SP-LI) was about 250 and 800 in juvenile and 600 and 2500 in adult Xenopus and Bufo, respectively, SP-LI cells had a small soma with one primary dendrite having up to four slender branches, located in the vitreal sublamina of the inner plexiform layer (IPL). Mean dendritic field sizes were 0.12 and 0.30 mm2 in juvenile and 0.29 and 0.65 mm2 in adult Xenopus and Bufo, respectively. The density of SP-LI cells was 40/mm2 in juvenile and 24/mm2 in adult Xenopus compared with 20/mm2 in juvenile and 13/mm2 in adult Bufo. Nearest neighbour distance measurements indicated that SP-LI cells were randomly distributed across the entire retina in both species. The location and the morphology of SP-LI cells indicated that they correspond to a subclass of wide-field amacrine cells, similar to types 20 and 21 described by Golgi techniques in the cat.

Intracellular study of oculomotor neurons in the rat

The electrical and morphological properties of oculomotor neurons were investigated in the rat with intracellular recordings and intracellular horseradish peroxidase staining. Motoneurons were identified by their antidromic response to electrical stimulation of the ipsilateral medial rectus muscle. The antidromic action potential was followed by a delayed depolarization and an afterhyperpolarization of 20-50 ms in duration. The whole neuron input resistance calculated from intensity/voltage curves, was found between 4 and 15 M omega. Passive membrane properties showed the existence of anomalous rectifications. Motoneurons were studied on the basis of their responses to long-lasting depolarizing current pulses. The intensity/frequency curves suggest the existence of two ranges of discharges. The average intensity frequency slope during the steady state was 33 imp/s/nA. Ten oculomotor neurons were intracellularly labelled with horseradish peroxidase and fully reconstructed. The soma (23-33 microns in diameter) gave off five-eight primary dendrites which could extend over 600-800 microns from the soma. The oculomotor neurons were principally oriented in the sagittal plane. The soma size of oculomotor neurons was not related to the size of proximal tree. According to our observations, the morphological features of motoneurons did not allow us to predict the whole neuron input resistance. The comparison between in vivo and in vitro studies of oculomotor neurons revealed one major difference in the input resistance of the whole neuron which was three times higher in slices.

Dye-coupling in the neostriatum of the rat: I. Modulation by dopamine-depleting lesions

Evidence from experiments performed in turtle and fish retina suggests that dopamine (DA) modulates the permeability of gap junctions. The present experiment was aimed at determining if DA has a similar role in the mammalian neostriatum. Adults rats received one of four treatments: unilateral electrolytic substantia nigra lesions, unilateral injection of 6-hydroxydopamine (6-OHDA) into the substantia nigra, unilateral neocortical aspiration, or no treatment. After 3-5 weeks, neostriata from both sides of the brain were prepared for in vitro intracellular recordings. Recorded neurons (N approximately 150) were filled with Lucifer Yellow (LY), a low molecular weight dye that crosses gap junctions. In animals with electrolytic nigral lesions, dye-coupling in the ipsilateral neostriatum occurred after 38% of the intracellular injections. After 6-OHDA lesions, 19% of the injections produced dye-coupling in the ipsilateral neostriatum. This difference may have been accounted for by the fact that electrolytic lesions produced a greater degree of DA loss than 6-OHDA injections. Both of these percentages contrast with the very small percentage of dye-coupling found in intact animals or in animals with neocortical lesions. Dye-coupling occurred only between medium-sized spiny cells. No morphological differences between dye-coupled and non-dye-coupled cells were observed with light microscopy. Overall, passive and active electrophysiological properties of dye-coupled and single neurons were similar. The results suggest that DA may function in the neostriatum to control permeability of gap junctions.

Dye-coupling in the neostriatum of the rat: II. Decreased coupling between neurons during development

Physiological and morphological evidence for coupling between neostriatal neurons was obtained from the developing rat. Intracellular injections of Lucifer Yellow-CH (LY) were made in rat neostriatal slices to study dye transfer (coupling) between neurons. The incidence of interneuronal coupling was 70% in early postnatal (P) periods and declined gradually to 10% in the adult. The number of neurons filled by a single intracellular injection also declined with age. LY injection into single neurons commonly marked aggregates of 4 to 6 cells in neonates. Single injections never produced more than one coupled pair in P20 or older rats. Neurons in which fast prepotentials (FPPs) could be evoked were consistently found to be dye-coupled. FPPs were resistant to collision with action potentials generated by intracellular current injection. When chemical synaptic transmission was blocked Mn2+, short-latency depolarizations (SLDs) could be evoked by extracellular stimulation. The SLDs were distinguished from chemical synaptic potentials by their "all or none" nature and by their insensitivity to changes in membrane potential. No SLDs were observed in adult neurons. FPPs and SLDs may be indicators of electronic transmission between coupled cells. The high incidence of coupling early in development might reflect intercellular communication that contributes to the differentiation and growth of neostriatal neurons.

Intracellular injection of lucifer yellow into cortical neurons in lightly fixed sections and its application to human autopsy material

In this paper a method is described for injecting Lucifer yellow intracellularly in lightly fixed cortical slices. The resultant filling reveals detailed neuronal morphology of somata, dendrites, and their appendages offering the following advantages over currently available cell staining techniques: (1) a large number (10-30) of neurons can be filled intracellularly in a single experiment, (2) when coupled with retrograde fluorescent tracing methods, specific populations of neurons can be chosen for study, (3) good results can be obtained reliably, (4) neurons from autopsy or biopsy material can be intracellularly filled, (5) other neuronal features can be identified by combining this method with lectin or neurotransmitter immunocytochemistry, and (6) filled cells can be made electron dense, permitting specimens to be examined under the electron microscope.

Morphological and electrophysiological properties of a novel in vitro preparation: the electrosensory lateral line lobe brain slice

An in vitro brain slice preparation of the electrosensory lateral line lobe (ELL) of weakly electric fish was developed. The morphology of this slice was studied and revealed that most ELL neurons and synapses retained their normal appearance for at least 10 h in vitro. The electrophysiological characteristics of the main ELL output neurons, the pyramidal cells, were measured. Extracellular electrode recordings demonstrated that pyramidal cells are capable of spontaneous, rhythmic spike activity. Intracellular recordings showed that intrinsic oscillations in membrane potential underlie the bursting behavior. The majority of pyramidal cells respond to depolarizing current pulses with an initial lag in spike firing followed by a non-accommodating, higher frequency spike train. Time and voltage-dependent properties of pyramidal cell responsiveness, as well as the effects of pharmacological blocking agents indicated that rhythmic activity and repetitive firing are dominated by a persistent, subthreshold sodium conductance (gNa) which activates at depolarizing levels and is the driving force behind the membrane potential oscillations and the sustained (non-accommodating) spike firing. In addition, a transient, outward potassium conductance (gA) is responsible for the lag in spike firing by acting as a 'brake' during the initial 50-200 ms of a depolarizing stimulus. Calcium currents and calcium-dependent potassium conductance add to the interval between spontaneous bursts but appear insufficient for spike frequency accommodation. The in vitro behaviour of pyramidal cells differs substantially from the behaviour of the same cell type in vivo. These observations raise possibilities that intrinsic membrane properties together with local synaptic interactions may regulate pyramidal cell responsiveness.

A versatile means of intracellular labeling: injection of biocytin and its detection with avidin conjugates

Biocytin is a biotin-lysine complex of low molecular weight containing about 65% biotin, which retains a high affinity for avidin. Since the latter molecule has been conjugated to several histochemical markers, the use of biocytin as an intracellular marker was investigated. Electrodes were filled with a solution of 4-6% biocytin dissolved in 0.5 M KCl and 0.05 M Tris buffer, pH 7-7.6. Neurons were recorded intracellularly in the supraoptic nucleus of an explant preparation of the rat supraoptico-neurohypophysial system and injected for 1-20 min with either hyperpolarizing or depolarizing current. Following variable recovery times, the explants were fixed in either 10% formalin or 4% paraformaldehyde overnight, sectioned on a vibratome, and incubated with the avidin-biotin complex (ABC) or avidin which had been conjugated to fluorescein, rhodamine, Texas Red or horseradish peroxidase and containing 1% Triton-X 100. A high percentage of injected neurons were recovered using each of the labels with about equal success. Both negative or positive current injection could be used with little electrode clogging. Labeling with fluorescent conjugates was qualitatively similar to that of Lucifer Yellow, whereas labeling with avidin coupled to horseradish peroxidase or with ABC was qualitatively similar to filling neurons directly with horseradish peroxidase. The advantages of this technique are the ease of injection of biocytin and the versatility in allowing the investigator to choose among light-emitting and light-absorbing images.

Nerve cells with irregular processes: demonstration of anisotropic core geometry of a pyramidal cell

An analytical, recursive method has been developed to demonstrate the anisotropic electrotonic geometry of nerve cells containing varicose or spiny dendrites. The procedure has been based on the distribution of the core geometry of dendrites into modules which consist of module elements where the physical length is much shorter than the actual space constant. The unambiguous representation of the anisotropic core geometry has been possible by plotting the decomposed geometries separated under the condition of the unidirectional spread of the wave front of dendritic potentials. This decomposition has revealed the bidirectional, "smoothed" core geometries as a function of irregular distribution of varicosities or spines. The shape of decomposed core geometries may change according to the position of the input site. The shaping of core geometry reflects the electrotonic effectiveness of a synaptic site to any arbitrary locations which may lead to considerable savings in computations on synaptic effects. The detailed, computer-reconstructed geometry of the apical dendritic field of the pyramidal cell has been analysed by the proposed method. The frequency-dependence of input impedances has been compared between the original and the transformed core geometries assuming that the current is injected into the soma. The significance of dendritic irregularities in the impedance matching has been studied when the shaping of the core geometry has been induced by laminar inputs. The proposed approach may be useful in comparing the input dependence of the receptive fields of different non-smooth cells. The mismatch of the core geometries induced by the opposite travelling waves from the same anatomical location has also been studied and the possible control of the preferred, direction-sensitive activities will be discussed. The important differences between the compartmental modelings based on the known isotropic treatment of dendrites and the more realistic anisotropic approach will be illustrated.

Mudpuppy retinal ganglion cell morphology revealed by an HRP impregnation technique which provides Golgi-like staining

A new technique of retrograde labeling of ganglion cells with horseradish peroxidase (HRP) has been developed, based on orbital injections of HRP combined with a detergent (lysolecithin). When injections are followed by an appropriate survival time, dense staining of a small number of widely scattered cells results in Golgi-like filling of each neuron. This technique, as well as a variation which causes mass staining of ganglion cell somas, has been used to analyze the morphology of mudpuppy retinal ganglion cells. Morphological analysis has relied on computer reconstruction techniques for display, analysis of dendritic sublamination pattern, and morphometric analysis of the dendrites and soma. Based on morphological criteria, the mudpuppy retina contains a rich variety of ganglion cell types which vary according to soma placement, dendritic field size, polar vs. non-polar dendritic fields, dendritic branching pattern, and dendritic sublamination. The mudpuppy retina contains both conventional and displaced ganglion cells: the latter constitute about 15% of the total ganglion cell population. Both conventional and displaced ganglion cells show morphological diversity of dendritic sublamination branching pattern; cells from each group have a dendritic branching pattern confined to either distal or proximal divisions of the inner plexiform layer, whereas other cells have dendrites which branch in both sublaminae. Using morphological criteria, two subtypes of ganglion cells were identified, which have a distinctive branching pattern and dendritic tree size. The size and distribution of ganglion cell somas were analyzed from retinas in which mass staining of ganglion cells was present. The total number of ganglion cells was estimated at approximately 14,500 cells per retina. There was a tendency for soma size and density to decrease near the optic disk. The somas of displaced ganglion cells are smaller than their conventional counterparts, at the same retinal eccentricity. The somas of all HRP filled cells swell when compared to those of unstained fixed and freshly dissected retinas. The degree of swelling is proportional to the length of exposure to HRP. Cell swelling was evident for both retrograde labeling and intracellularly injected HRP. This artifact of HRP staining could influence the interpretation of studies in which quantitative differences in soma sizes are based on the use of HRP labeling.