The thalamic reticular nucleus of the adult rat: experimental anatomical studies

Mechanisms of oscillatory activity in guinea-pig nucleus reticularis thalami in vitro: a mammalian pacemaker

1. The ionic mechanisms of rhythmic burst firing and single spike, tonic discharge were investigated with extracellular and intracellular recordings of single neurones in the guinea-pig nucleus reticularis thalami (NRT) maintained as a slice in vitro. 2. Activation of cortical/thalamic afferents to NRT neurones resulted in a short latency burst of action potentials which could be followed by a rhythmic sequence of oscillatory burst firing. Intracellularly, this oscillatory activity was associated with an alternating sequence of low threshold Ca2+ spikes separated by after-hyperpolarizing potentials. Intracellular injection of short duration hyperpolarizing current pulses resulted in a similar sequence of oscillatory burst firing, suggesting that this activity is an intrinsic property of NRT cells. The frequency of rhythmic burst firing was highly voltage and temperature dependent and was between 7-12 Hz at -65 to -60 mV at 38 degrees C. In addition, at depolarized membrane potentials, oscillatory burst firing was typically followed by a prolonged tail of single spike activity. 3. Application of the Na+ channel poison tetrodotoxin blocked the generation of fast action potentials, but left intact the rhythmic sequence of low threshold Ca2+ spikes separated by after-hyperpolarizing potentials (AHPs). The reversal potential of the AHPs was -94 mV, suggesting that it was mediated by an increase in K+ conductance. Extracellular application of tetraethylammonium or apamin, or intracellular injection of Cs+ or the Ca2+ chelating agent EGTA, blocked the Ca2+ spike AHP, indicating that it is mediated by a Ca(2+)-activated K+ current. 4. Block of the AHP resulted in the marked enhancement of a slow after-depolarizing potential (ADP). The slow ADP occurred only following the generation of low threshold Ca2+ spikes. Replacement of extracellular Ca2+ with Mg2+ or Sr2+ resulted in an abolition of the slow ADP. In addition, the increase in [Mg2+]o resulted in an abolition of the low threshold Ca2+ spike. In contrast, replacement of extracellular Ca2+ with Ba2+ did not abolish the slow ADP. These results indicate that the ADP can be activated by either Ca2+ or Ba2+, but not by Mg2+ or Sr2+. 5. Replacement of extracellular Na+ with choline+ did not abolish the slow ADP, while replacement with N-methyl-D-glucamine+ did, indicating that the slow ADP can be supported by choline+, but not by N-methyl-D-glucamine+. Neither chemical affected the low threshold Ca2+ spike. These results are consistent with the slow ADP being mediated by a Ca(2+)-activated non-selective cation (CAN) current.(ABSTRACT TRUNCATED AT 400 WORDS)

Selective loss and selective sparing of neurons in the thalamic reticular nucleus following human cardiac arrest

Neurons in the portion of the human thalamic reticular nucleus (RT) associated with the prefrontal cortex and mediodorsal thalamic nuclei were found to be selectively vulnerable to ischemic neuronal damage following relatively short (< or = 5-min) duration cardiac arrest. In contrast, selective sparing of these RT neurons occurred in cases with longer (> 10-min) duration of arrest that was sufficient to produce extensive ischemic neuronal damage throughout the cerebral cortex and thalamic relay nuclei. The selective degeneration of RT neurons appears to require the sustained activity of corticothalamic or thalamocortical projections to the RT following the ischemic insult. Loss of RT neurons associated with the frontal cortex and mediodorsal thalamus may be the biological basis of some types of persisting cognitive deficits in attentional processing experienced by patients following cardiac arrest, open heart surgery, or other forms of brief global cerebral ischemia.

Cholinergic responsiveness of neurons in the ventroposterior thalamus of the anesthetized rat

Acetylcholine has been implicated as an important neurotransmitter in the mechanisms of thalamic activation. Cholinergic mechanisms are thought to directly underlie the high level of excitability observed in thalamic relay neurons during waking and rapid eye movement sleep. We sought to determine if the cholinergic responsiveness of neurons in the ventroposterior nuclei of the thalamus in rat is consistent with this view. Neurons in the chloral hydrate-anesthetized rat were studied with extracellular recording and microiontophoretic application of cholinergic agents. In most cases (63% of 63 cells), the ejection of the agonist, carbachol, had no observable effect on spontaneous activity. Facilitation (25%), inhibition (8%) and inhibition followed by facilitation (3%) were also observed. Carbachol ejections that by themselves were ineffective in altering spontaneous activity proved capable, in 93% of 28 cells, of antagonizing the uniformly facilitatory responses produced by glutamate ejection. The putative M1-selective, cholinergic agonist, McN-A-343, was also ineffective alone in altering spontaneous activity in the majority of cases (74% of 27 cells) and produced only inhibitory responses in the remaining seven neurons studied. Interacting applications of McN-A-343 and glutamate resulted, in all cases, in antagonism of glutamate facilitation (N = 12). The various responses to applied cholinergic agonists were all capable of being antagonized by muscarinic receptor-blocking agents. Both the high proportion of inhibitory responses and the antagonism of glutamate facilitatory responses suggest that ventroposterior neurons in the rat differ from other thalamocortical relay neurons in the rat and cat with regard to cholinergic responsiveness. Additionally, the lack of predominantly facilitatory responding renders it unlikely that cholinergic mechanisms directly underlie increases in excitability of ventroposterior neurons observed during waking and rapid eye movement sleep.

Spindle rhythmicity in the reticularis thalami nucleus: synchronization among mutually inhibitory neurons

The sleep spindle rhythm of thalamic origin (7-14 Hz) displays widespread synchronization among thalamic nuclei and over most of the neocortex. The mechanisms which mediate such global synchrony are not yet well understood. Here, we theoretically address the hypothesis of Steriade and colleagues that the reticularis thalami nucleus may be considered as a genuine pacemaker for thalamocortical spindles. Interestingly, the reticularis consists of a population of neurons which are GABAergic and synaptically coupled. These cells, as do thalamic relay cells, exhibit a transient depolarization following release from sustained hyperpolarization. This postinhibitory rebound property is due to a T-type calcium ionic current which is inactivated at rest but de-inactivated by hyperpolarization. Theoretically, rebound-capable cells coupled by inhibition can generate rhythmic activity, although such oscillations are usually alternating (out-of-phase), rather than synchronous (in-phase). Here, we develop and apply to Steriade's pacemaker hypothesis our earlier finding that mutual inhibition can in fact synchronize cells, provided that the postsynaptic conductance decays sufficiently slowly. Indeed, postsynaptic receptors of the GABAB subtype mediate inhibition with a large decay time-constant (approximately 200 ms). In contrast, chloride-dependent, GABAA-mediated inhibitory postsynaptic potentials are fast and brief. Both GABAA and GABAB receptor binding sites are present in most thalamic regions, including the reticularis. We suggest that if GABAB receptors exist postsynaptically in the reticularis, they may play a critical role in the rhythmic synchronization among reticular neurons, hence in the thalamocortical system.

Morphology of neurons in the thalamic reticular nucleus (TRN) of mammals as revealed by intracellular injections into fixed brain slices

I have investigated the morphology of neurons in the thalamic reticular nucleus (TRN) by means of intracellular injections in fixed tissue in order to study whether neurons in visual (dorsocaudal part), somatosensory (intermediate part), or limbic/motor (rostral part) sectors in the rat, rabbit, and cat differ morphologically in relation to their different sensory cortical or thalamic inputs. In addition, I have compared the different mammalian species to ask whether there is a morphological difference of TRN neurons according to reported differences in the intrinsic thalamic organisation, for example, due to the presence of GABAergic local circuit neurons in the majority of thalamic nuclei in the cat and the lack of those neurons in most of the rat thalamic nuclei, and presynaptic dendrites in the cat but not in the rat. In all animals investigated so far, neurons in the caudal (visual) and intermediate (somatosensory) part of the TRN have an elongated dendritic morphology in all three species, but some neurons in the rostral part, in particular in dorsal sections, have a distinctive multipolar morphology. Neurons have round, ovoid, or elongated somata ranging in area between 150 and 860 microns 2. In general, 4-8 first order dendrites emerge directly from the two poles of the soma or from a thick stem segment. Most of the dendrites then run parallel to the borders of the nucleus extending for relatively long distances, up to 450 microns, but remain inside the border of the nucleus. Only a few (1-3) dendrites could be observed to run perpendicular to the border of the nucleus and generally only for a short distance (20-70 microns). Some of the smooth first order dendrites give rise to second order dendrites (up to 200 microns in length), which then branch into short (15-70 microns) third order dendrites. Dendritic spines and varicosities, spine-like protusions and/or hair-like processes are mainly found on second and third order dendrites. Surprisingly, the shape, arrangement, and the size of the dendritic field are not strictly related to the shape and size of the nucleus. In mammalian species with a comparatively narrow TRN (rat and cat) the dendritic field size was similar to that in the rabbit with a broad TRN. There was considerable variability in dendritic morphology in the caudal and intermediate parts of TRN. However, in contrast to two recent studies in the rat TRN I have found no obvious basis for classification of neurons in the mammalian TRN according to dendritic morphology.(ABSTRACT TRUNCATED AT 400 WORDS)

Degeneration of rat thalamic reticular neurons following intrathalamic domoic acid injection

Domoic acid (DA), an analog of kainic acid, produces attentional deficits in humans who have ingested shell fish contaminated with this excitotoxin. The thalamic reticular nucleus (RT), by virtue of its location, connections and intrinsic properties, has been implicated in attentional processes. This study demonstrated the vulnerability of RT neurons following intrathalamic DA injections in rats. Lesions were characterized by almost total neuronal loss throughout the RT and sparing of adjacent populations of relay neurons in the VL and VPL. Los of RT neurons may underlie some types of attentional deficits observed in humans following DA poisoning.

Unit activity in human thalamic reticularis neurons. II. Activity evoked by significant and non-significant verbal or sensory stimuli

In the nucleus reticularis thalami (n.Rt.) of 46 dyskinetic patients the responses of 340 single units to significant and non-significant verbal and sound stimuli and ordered voluntary movements were studied. The spontaneous activity of the same neuronal populations previously examined allowed the classification of these neurons into 3 groups, named A, B and C types. Only A and B cells were found to be activated during the verbal command to perform a movement and its realization. The patterns of the responses of these units were studied by means of principal component analysis (PCA) and of correlation techniques during different phases of the command presentation and of the movement. For A cells, two excitatory components A-PC1 and A-PC2 appeared during the command presentation: A-PC1 immediately after its beginning; A-PC2 (trigger component) when an imperative part of the command was pronounced. An excitatory component A-PC3 was connected with the initiation of movement (premotor component); a late excitatory component A-PC4 correlated with movement realization (motor component). For B-units, the inhibitory component B-PC1 corresponded to command presentation; the excitatory component B-PC2 was connected in time with the movement realization. Cross-correlations were studied for simultaneously recorded pairs of A, B and A and B cells. Transitory positive correlations of the activities of two A cells appeared at the time of A-PC1 and, especially of A-PC2 and A-PC3, as well as during the late activation accompanying the movement.(ABSTRACT TRUNCATED AT 250 WORDS)

Selective loss of neurons from the thalamic reticular nucleus following severe human head injury

The GABAergic neurons of the thalamic reticular nucleus, or nucleus reticularis thalami (RT), have been implicated as important components in attentional processing systems. Neurons in the RT are exquisitely sensitive to degeneration following kainic and domoic acid toxicity, experimental global ischemia, human cardiac arrest, and experimental closed head injury in nonhuman primates. The present study was performed to establish whether the selective loss of human RT neurons occurred following severe head injury. Brains from 37 human nonsurvivors of head injury were examined for evidence of RT neuronal loss. RT lesions in were found in 36 of 37 cases, representing 65 of 73 (89%) of the reticular nuclei examined. The incidence of RT lesions was similar in all age groups: 13 of 14 cases (92.9%) in the pediatric (< or = 16 years) group, 33 of 37 (89.2%) in the young adult (18-45 years) group, and 19 of 22 (86.4%) in the older adult (> 45 years) group. RT lesions were characterized by loss of one fourth to three fourths of the neurons from the region of the nucleus associated with the frontal cortex and thalamic mediodorsal (MD) and ventrolateral (VL) nuclei. Sparing of RT neurons correlated highly with the presence of extensive frontal cortical lesions, suggesting that an intact corticothalamic projection was necessary for RT degeneration following head injury. A pathologic cascade with a prominent excitotoxic component is proposed. The loss of these inhibitory thalamic reticular neurons and the resultant thalamic and neocortical neuronal dysfunctions may underlie some forms of attentional deficits that persist following head injury.

Bilateral cerebral metabolic effects of pharmacological manipulation of the substantia nigra in the rat: unilateral intranigral application of the putative excitatory neurotransmitter substance P

The metabolic activity of several anatomically distinct brain areas was investigated by means of the quantitative autoradiographic 2-deoxy-D[1-14C]glucose method in awake rats following unilateral intranigral application of the putative excitatory neurotransmitter substance P. The primary goal was to determine the metabolic effects of substance P on the substantia nigra and its targets. Intranigral injection of 1 mM substance P (1.5 microliters) induced metabolic activation locally in the substantia nigra reticulata by 117% and substantia nigra compacta by 35%, as well as distally in the contralateral substantia nigra reticulata by 22% and contralateral substantia nigra compacta by 21%. All the basal ganglia components, the striatum, pallidum, entopeduncular, subthalamic nucleus and nucleus accumbens displayed bilateral metabolic activations after unilateral intranigral substance P injection. Among the principal reticulata efferent projections, the ventromedial, ventrolateral, parafascicular, mediodorsal and centrolateral thalamic nuclei, as well as the pedunculopontine nucleus displayed bilateral metabolic activations after intranigral substance P application. Moreover, unilateral intranigral substance P injection elicited metabolic activations in the thalamic and cortical components of the reticular, intralaminar, limbic and prefrontal systems, mostly bilateral. It is suggested that substance P applied into one substantia nigra reticulata activates the compacta nigrostriatal dopaminergic and the reticulata nigrothalamic GABAergic outputs inducing distal metabolic effects, similar to those elicited by unilateral nigral electrical stimulation [Savaki et al. (1983) J. comp. Neurol. 213, 46-65] and, opposite to several of those induced by intranigral injection of the inhibitory GABAA agonist muscimol [Savaki et al. (1992) Neuroscience 50, 781-794]. Furthermore, it is suggested that the ipsilateral basal ganglia effects induced by intranigral substance P application are mediated via both the compacta dopaminergic nigrostriatal projection and the reticulata GABAergic nigro-thalamocortico-striatal loop, whereas the contralateral basal ganglia and associated thalamocortical effects are due to the activation of the GABAergic reticulata efferents and are mediated via an interthalamic circuitry involving the motor, reticular and intralaminar thalamic nuclei.

Behavioural effects after cholinergic stimulation of the reticular thalamic nucleus in rats

This study investigated the functional relationship between the experimentally induced changes in the activity of the cholinergic, muscarinergic system of the rostral area of the nucleus reticularis thalami (TRN) and the motor behaviour. The effect of direct stimulation of the rostral TRN by the cholinergic agonist carbachol on the behaviour of freely moving rats was observed. Unilateral injection of carbachol (0.2-3.2 micrograms/0.5 microliters) into the rostral TRN caused catalepsy which appeared rapidly and was short-lasting. Furthermore, it induced impairment of the performance on the rota rod. Both effects were dose-dependent. The cholinergic antagonist scopolamine (6.66 micrograms) coadministered with the equimolar dose of carbachol (3.2 micrograms) antagonized the effects of carbachol on both behavioural tests. The described effects seem to be cholinergic- and site-specific within the rostral TRN. The present results suggest that activation of the cholinergic, muscarinergic receptors in the rostral TRN modulate the motor function of rats.

Bilateral cerebral metabolic effects of pharmacological manipulation of the substantia nigra in the rat: unilateral intranigral application of the inhibitory GABAA receptor agonist muscimol

Rates of cerebral glucose utilization were measured by means of the autoradiographic 2-deoxy-D[1-14C]glucose technique in the rat brain in order to determine the metabolic effects of unilateral intranigral application of the GABAA agonist muscimol upon the substantia nigra and its targets. Intranigral injection of 1.5 microliters 0.3 M muscimol (52 micrograms total dose) induced local metabolic activation in the injected substantia nigra reticulata (by 87% as compared to the control group), and distal metabolic depressions in the nucleus accumbens, striatum, globus pallidus and subthalamic nucleus only ipsilaterally to the injected nigra. The remaining basal ganglia components, including the substantia nigra compacta and the entopeduncular nucleus were bilaterally unaffected. Among the principal efferent projections of the substantia nigra reticulata, the ventromedial and centrolateral thalamic nuclei as well as the deep layers of the superior colliculi were metabolically depressed bilaterally, whereas the ventrolateral, parafascicular and mediodorsal thalamic nuclei as well as the pedunculopontine nucleus displayed metabolic depressions ipsilateral to the muscimol-injection nigra. The ventromedial and centrolateral thalamic nuclei were depressed by 41 and 42%, respectively, in the ipsilateral side, and by 30 and 26% in the contralateral side, when compared to the respective values of the control group of rats. Furthermore, unilateral intranigral injection of 0.3 M muscimol induced metabolic depressions in reticular, intralaminar and prefrontal thalamocortical areas mostly ipsilateral to the injected nigra, as well as in limbic areas bilaterally. It is suggested that the present findings are due to a postsynaptic effect of muscimol on the nigral GABAergic cells and to a consequent metabolic depression of the basal ganglia and associated thalamocortical areas, in contrast to an earlier suggested presynaptic nigral effect of lower doses of intranigrally injected muscimol which induced metabolic activations within the same network. This suggestion is further supported by the fact that intranigrally injected substrate P19 induced similar effects to those elicited by the lower doses of intranigral muscimol and opposite to those induced at present by the higher muscimol dose. Moreover, it is further substantiated that the nigrothalamic GABAergic system is responsible for considerable transfer of information from one substantia nigra reticulata to the ipsilateral basal ganglia and associated thalamocortical components as well as to bilateral motor, intralaminar and limbic areas.

Cytoarchitectonic heterogeneities in the thalamic reticular nucleus of cats and ferrets

The thalamic reticular nucleus has been classically defined as a group of cells surrounding most of the rostral and lateral surfaces of the dorsal thalamus, lateral to the fibres of the external medullary lamina and medial to those of the internal capsule. With the use of Nissl staining and antibodies to gamma-aminobutyric acid (GABA), somatostatin, and parvalbumin, this study describes the cytoarchitecture of the thalamic reticular nucleus of cats and ferrets. In cats, three subdivisions of the nucleus are distinguished, two of which are distinct in ferrets also. First, the main body of the reticular nucleus lies lateral to the fibres of the external medullary lamina (except ventrally) and medial to those of the internal capsule. In both cats and ferrets, this structure is heterogeneous, consisting of distinct layers, the details of which vary along the dorsoventral axis. A prominent rostroventral portion of comparatively small rounded cells is also apparent within the main body. Most reticular cells in all areas of the main body are labelled with all of the above mentioned antibodies. Second, the inner small-celled region is a group of small cells located between the external medullary lamina (ventrally) and the medial margin of the ventral regions of the main body of the reticular nucleus: the inner small-celled region is clearly differentiated in cats only. Previous studies have referred to this area as being part of the main body of the reticular nucleus, but we suggest that it may form a separate subnucleus. For example, the inner small-celled region stands in striking contrast to the main body of the reticular nucleus in that none of its cells are GABA immunoreactive and only a small caudal subpopulation are parvalbumin immunoreactive. A very similar pattern of immunostaining is apparent for the cells in the zona incerta, although the latter contains a small rostral subpopulation of GABA immunoreactive cells. Furthermore, although morphologically distinct from the zona incerta, the inner small-celled region fuses with it ventrocaudally. We suggest that the inner small-celled region may constitute a previously undescribed dorsal extension of the zona incerta, rather than a subdivision of the reticular nucleus. Third, the perireticular nucleus, hitherto unidentified, is a discrete group of small cells lateral to the main body of the reticular nucleus and medial to the corpus striatum (globus pallidus and caudate-putamen). It is apparent throughout most of the dorsoventral extent of the main body of the reticular nucleus of cats and ferrets.(ABSTRACT TRUNCATED AT 400 WORDS)

Calbindin immunoreactivity in a subset of cat thalamic reticular neurons

Recent studies have shown that the thalamic reticular nucleus of cats is made up of several cytoarchitectonically distinct subdivisions and that the nucleus contains accurate topographical maps of the cortical sheet and of the dorsal thalamus. The present study describes immunocytochemically demonstrable heterogeneity in the reticular nucleus of cats, with an antibody to calbindin D28k. The striking feature of calbindin immunoreactivity in the reticular nucleus of cats is that the immunoreactive neurones are located in the caudal half of the nucleus only. In these regions, labelled cells form a small proportion of the total population of reticular cells only and are not distinct in somal size or shape from neighbouring non-labelled reticular cells. Double labelling shows that the calbindin-immunoreactive cells are also immunoreactive to parvalbumin and GABA. There is a distinct tendency for the calbindin-immunoreactive cells to be more numerous ventrally than dorsally in the caudal half of the nucleus, which receives afferents from the somatosensory and auditory systems.

Patterns of antigenic expression in the thalamic reticular nucleus of developing rats

The present study describes the development of the thalamic reticular nucleus in rats with the use of Nissl staining and antibodies to parvalbumin and pro-alpha-thyrotropin-releasing hormone (alpha TRH). Two major subdivisions of the reticular nucleus are apparent: 1) the main body, which is itself heterogeneous and lies for the most part between the fibres of the internal capsule and external medullary lamina, and 2) the perireticular nucleus, which lies lateral to the main body and medial to the globus pallidus. In the main body of the reticular nucleus of adults, most cells in all regions are immunoreactive to parvalbumin and alpha TRH. During development there are two waves of parvalbumin and alpha TRH expression. The first wave occurs between postnatal day (P) 0 and P10, and labelled cells are apparent in rostrolateral areas of the main body of the nucleus only. At P10, such cells are not apparent. From P7 to adult, there is a second wave of parvalbumin and alpha TRH expression: labelled cells emerge first in central, then in caudal, and finally in rostral areas of the nucleus. In adults, the perireticular nucleus is made up of a few small cells which are immunostained for parvalbumin and alpha TRH. These cells are more frequent in areas of the internal capsule adjacent to the ventral regions of the main body of the reticular nucleus, rostrodorsal to the entopeduncular nucleus. From E (embryonic day) 17 to about P10, the perireticular nucleus consists of a surprisingly large population of neurones, many of which are parvalbumin and alpha TRH immunoreactive. By about P10, as in adults, there are few perireticular cells.

Noradrenergic innervation of the thalamic reticular nucleus: a light and electron microscopic immunohistochemical study in rats

Fluoro-ruby injections in the rat locus coeruleus result in scattered chain-like arrays of varicose anterogradely labeled axons within the thalamic reticular nucleus of rats. An abundant meshwork of axons giving rise to en passant boutons is detected immunohistochemically within this thalamic nucleus by means of an antibody to dopamine-beta-hydroxylase (DBH). The density of DBH-positive axonal boutons within the reticular nucleus neuropil is greater than that found in the relay nuclei of the dorsal thalamus (with the exception of the anterior group nuclei). Single DBH-positive axons appear to contact both proximal and distal dendrites and occasionally the somata of reticular nucleus neurons. Labeled axons are seen closely juxtaposed not only to the swollen segments of the beaded reticular neuron dendrites, but to the constricted segments as well. Electron microscopic examination of DBH-positive axon terminals within the reticular nucleus neuropil indicates that many of the axonal boutons detected light microscopically participate in asymmetric synaptic contacts. The postsynaptic densities of these synapses are thicker than those of nearby symmetric synapses, but often subtend a shorter length of the postsynaptic membrane than the densities associated with other nearby asymmetric synapses. These observations indicate that the ascending noradrenergic system, in addition to influencing the dorsal thalamus and the cerebral cortex directly, is well situated to influence signal transmission through the nuclei of the dorsal thalamus indirectly via a moderately dense terminal projection upon the thalamic reticular nucleus.

Thalamic processing of vibrissal information in the rat: II. Morphological and functional properties of medial ventral posterior nucleus and posterior nucleus neurons

Extracellular recording, intracellular recording, intracellular horseradish peroxidase injection, and receptive field mapping techniques were employed to evaluate the physiological and morphological properties of medial ventral posterior nucleus (VPM) and posterior nucleus (POm) neurons in normal adult rats. Overall, we physiologically characterized 148 VPM and 121 POm neurons. Over 82% of the VPM cells were excited only by deflection of one or more mystacial vibrissae, 10% were activated by displacement of guard hairs, and the remainder were either excited by indentation of the skin or were unresponsive. Less than 40% of the POm cells were activated by vibrissa deflection, 18% were excited by displacement of guard hairs, and another 17% were unresponsive. Most of the rest of the POm cells were excited by stimulation of skin, mucosa, or activation of muscle-related afferents. Small percentages of POm cells responded only to noxious stimulation, were classified as having a wide dynamic range, or were inhibited by peripheral stimulation. Electrical stimulation of either PrV or SpI activated most neurons in both VPM and POm. This excitation was almost invariably followed by a long-lasting hyperpolarization which was generally strong enough to prevent responses to either electrical stimuli delivered in the brainstem or mechanical stimulation of the periphery. The receptive fields of vibrissa-sensitive cells in POm were generally much larger than those of cells in VPM. Data obtained with extracellular recording indicated that VPM and POm cells responded to an average of 1.4 and 4.0 vibrissae, respectively. Intracellular recording from smaller samples of VPM and POm cells demonstrated the existence of inputs that were insufficient to produce spikes from the cell, but did yield epsp's. When both sub- and suprathreshold excitation were considered, the average number of vibrissa in the receptive field of a VPM cell was 2.7 and the value for POm cells became 7.8. HRP-filled neurons recovered in POm (N = 20) generally had much larger dendritic arbors than neurons in VPM (N = 31). For the former cells, the size of the dendritic tree was significantly correlated with the number of vibrissa to which the cell responded; for the latter neurons, it was not.

Cholinergic modulation of responses to glutamate in the thalamic reticular nucleus of the anesthetized rat

Neurons in the thalamic reticular nucleus (TRN) of the chloral hydrate-anesthetized rat were studied with extracellular recording and microiontophoretic application of cholinergic agents. In most cases (63%), the ejection of the agonist, carbachol, had no observable effect on spontaneous activity, and in an additional 33% of cases was observed to inhibit discharge rate. Carbachol ejections with identical current and duration parameters proved capable of antagonizing the uniformly facilitatory responses produced by glutamate ejection in these same cells. The muscarinic nature of cholinergic effects was documented by scopolamine's specific antagonism of the responses. The muscarinic antagonists, pirenzepine and AF-DX-116, both diminished the effects of carbachol. Application of muscarinic agonists, such as McN-A-343 and oxotremorine-M, yielded qualitatively the same results as carbachol, though, with current as a criterion, oxotremorine-M was slightly more and McN-A-343 much less potent than carbachol. The functional implications of cholinergic modulation of the facilitatory inputs to TRN are discussed, with particular emphasis on the role of acetylcholine and the TRN in the sleep/wake-related activity of thalamic neurons.

The reticular thalamic nucleus (RTN) of the rat: cytoarchitectural, Golgi, immunocytochemical, and horseradish peroxidase study

Experiments have been performed on adult albino rats in order to study the cellular organization of the thalamic reticular nucleus. For this purpose four approaches have been used: Nissl stain, Golgi impregnation, retrograde transport of horseradish peroxidase after injection in different thalamic nuclei, and immunocytochemistry with antibodies against GABA and glutamic acid decarboxylase. In sections through the horizontal plane, three morphologically different neurons have been observed. Cells with round perikarya and with multipolar dendrites were found predominantly in the rostral pole of the nucleus. Neurons with large fusiform cell body and with dendrites arborizing mainly on the horizontal plane were detected through the whole extent of the nucleus. Small fusiform neurons were observed almost exclusively in the medial third of the dorso-ventral extent of the nucleus. The Golgi impregnation method demonstrated that dendrites of small fusiform neurons develop in the vertical plane perpendicular to the dendritic arborization of large fusiform neurons. In coronal sections neurons with round perikarya and with large fusiform cell bodies are detectable while small fusiform neurons are only rarely visible. These data have been confirmed by statistical form factor analysis. Moreover, by means of the horseradish peroxidase and the immunocytochemical study, it has been confirmed that all three groups of neurons project within the thalamus and that they are GABAergic. The data concerning the distribution within the nucleus of the three morphologically different neurons are discussed in relation to the topographic distribution of cortical sensory afferents and to the topographic maps within different sectors of the reticular nucleus.

The thalamic clock: emergent network properties

Rhythmical oscillation of thalamic neuronal populations occurs under physiological conditions and in several disease states. In the present experiments we examined the network properties of population rhythmicity and the possible involvement of N-methyl-D-aspartate receptors in the frequency regulation and maintenance of rhythmic thalamic bursts. Multisite recording of neuronal activity and local microinjections of drugs were performed on the freely moving rat. Rhythmic thalamic population bursts at 6 to 9 Hz and concurrent neocortical high voltage spike-and-wave spindles were observed during awake immobility, with the thalamic rhythm leading the neocortical high voltage spindle. Even though all individual thalamocortical neurons fired in a phase-locked manner to the high-voltage spindle, the majority discharged at a significantly lower frequency than that of the population (multiunit) activity. In contrast, neurons in the nucleus reticularis thalami discharged at the frequency of the population bursts. Neurons in the extrapyramidal system and neocortex but not the hippocampal formation also fired in a phase-locked manner to the high-voltage spindle. Systemic administration or local microinjection of either non-competitive or competitive N-methyl-D-aspartate blockers (ketamine or ap-5) slowed the frequency of thalamic multiunit bursts and associated high-voltage spindles from 8 to 2 Hz, or completely blocked rhythmicity. Unilateral thalamic injection of ketamine or ap-5 resulted in a suppression of the amplitude of high-voltage spindles in the injected hemisphere. It is concluded that thalamic rhythmicity is not due to the "pacemaker" properties of thalamic cells but is rather an emergent property of the relay thalamus-nucleus reticularis network. Furthermore, we hypothesize that the frequency of network oscillation is regulated by the interplay between two major classes of voltage-dependent conductances in the thalamocortical cells: low-threshold calcium channels and high-threshold N-methyl-D-aspartate channels.

Light and electron microscopic evidence for a GABAergic projection from the caudal basal forebrain to the thalamic reticular nucleus in rats

Neurons in the magnocellular nucleus of the caudal basal forebrain extend an axonal projection which arborizes within the reticular nucleus of the thalamus. The present study addresses the ultrastructure and neurochemistry of this projection in rats. Many labeled terminals are apparent within the thalamic reticular nucleus following Phaseolus vulgaris leucoagglutinin injections into the caudal basal nucleus; anterogradely labeled axon terminals most commonly contact both somata and dendrites of reticular nucleus neurons with symmetric membrane specializations. Thus, the majority of the labeled terminals examined contrast with choline acetyltransferase positive terminals which have been previously identified as contacting dendrites and forming asymmetric synapses within this nucleus. Many of the neurons within the caudal basal nucleus which are retrogradely labeled following tracer injections into the thalamic reticular nucleus are gamma-aminobutyric acid (GABA) immunoreactive. In addition, following injections of Phaseolus vulgaris leucoagglutinin or fluoro-ruby into the caudal basal forebrain, some of the labeled axonal swellings and boutons within the thalamic reticular nucleus also contain glutamic acid decarboxylase. These results indicate that a significant component of the projection is GABAergic. These anatomical observations suggest that the projection from the caudal basal nucleus onto the thalamic reticular nucleus could facilitate the relay of information through the dorsal thalamus by inhibiting reticular nucleus neurons, and thus, in turn, disinhibiting thalamic relay neurons.

A different type of vertebrate thalamic organization

The presence of a reptilian thalamic reticular nucleus was investigated in Caiman crocodilus. Injections of horseradish peroxidase made into the dorsal thalamus produced retrogradely labeled neurons in the nucleus of the dorsal peduncle of the lateral forebrain bundle. A separate population of thalamic neurons located in the nucleus of the dorsal peduncle of the lateral forebrain bundle with morphology different from those neurons projecting to the dorsal thalamus were found to be immunoreactive for glutamic acid decarboxylase. Taken together, these findings suggest that Caiman, like mammals, contain a thalamic reticular nucleus but that thalamic organization in Caiman differs significantly from that of mammals.

Thalamic spindles in an isolated and perfused preparation in vitro

Intracellular recordings were obtained from thalamic nuclei neurones in isolated and perfused whole brains of adult guinea pigs in vitro. Thalamic neurones presented the same basic membrane properties in this preparation as in slices. The majority of cells displayed, in addition, spontaneous spindle oscillations similar to those observed in the cat in vivo. This activity could be blocked by the cholinergic agonist carbachol perfused at 10(-4) M. Thalamic spindles could also be recorded in decorticated preparations, in which perfusion to the cerebral cortex was interrupted. Such preparations could be useful for studying in vitro the spindle generating mechanism in rodents as well as some aspects of brainstem/diencephalic interactions related to the control of sleep and arousal.

Alz-50 immunoreactivity in the thalamic reticular nucleus in Alzheimer's disease

Examination of the thalamic reticular nucleus (Rt) with the monoclonal antibody Alz-50 in brains of Alzheimer's disease patients reveals dense extracellular and terminal-like immunoreactivity in the absence of neurofibrillary tangles or neuritic plaques. Similar terminal-like immunoreactivity is not present in other thalamic nuclei of AD brains or in the brains of controls. Based on (1) an immunocytochemical and histopathological analysis of areas known to project to the Rt, (2) that Alz-50 immunocytochemistry reveals immunoreactive neurons, neurofibrillary tangles and neuritic plaques, and (3) evidence that Alz-50 immunoreactivity can be demonstrated in the terminal fields of immunoreactive neurons, the terminal-like immunoreactivity in the Rt probably corresponds to altered preterminal axons and terminals from degenerating basal forebrain neurons. Given the presumed physiological role of the Rt, these selective lesions could alter thalamocortical processing and contribute to the cognitive impairment in Alzheimer's disease.

Dissimilar responses of adult thalamic monoaminergic and somatosensory afferent fibers to implantation of thalamic fetal cells

It is generally accepted that transplanted fetal neurons can, after several weeks to months, establish connections with the host CNS. Host afferent systems seem, however, to show different types of responses to the presence of grafted fetal neurons. The present study is a preliminary step to identify mechanisms involved in the reactions of adult axons to transplanted fetal neurons. The right ventrobasal thalamus of adult rats was depleted of neurons by in-situ injection of kainic acid and cell suspensions from homotopic thalamic embryonic primordia which were injected into the lesioned area. After various post-implantation delays, ranging from five to 30 days, two types of experiments were performed: (i) noradrenaline and serotonin immunohistochemistry with specific antibodies on alternate sections; and (ii) anterograde tracing using wheat germ agglutinin conjugated to horseradish peroxidase from the dorsal column nuclei and the principal sensory trigeminal nucleus. Five days after transplantation, host monoaminergic fibers (either noradrenergic or serotoninergic) had already grown into the transplants. Ingrowing fibers were thin and poorly varicose, exhibiting endings morphologically similar to the growth cones observed during axogenesis. Seven days after grafting, growth cones were no longer visible and monoaminergic fibers exhibited either normal-sized or very large varicosities. Large varicosities progressively decreased in number and, after three weeks, the fibers displayed a normal adult morphology, forming a dense network all over the transplants. In contrast, host somatosensory afferents, labeled by anterograde transport of wheat germ agglutinin conjugated to horseradish peroxidase, did not grow into the transplants. Intermingling of somatosensory afferents and transplanted cells was observed only after 10 days, when grafted neurons extended outside the original transplantation site into the neuron-depleted area containing the somatosensory afferents. The present results demonstrate that adult monoaminergic and somatosensory afferents, when deprived of their usual target, do not react in a similar way to the addition of fetal neurons. It is proposed that adult monaminergic fibers have the ability to regain morphological (and probably functional) immature forms which were considered to be restricted to the period of axogenesis or to lesion-induced regeneration. In contrast, fetal transplants do not seem to induce, by themselves, a similar alteration of genetic expression in adult somatosensory neurons. It has been proposed that "diffuse" and "point-to-point" axonal systems may be differentiated in the CNS on anatomical bases. The present results add to the identification of two different systems by demonstrating that, in the thalamus, they present dissimilar responses to the implantation of fetal cells.

Projections to the rostral reticular thalamic nucleus in the rat

Afferent pathways to the rostral reticular thalamic nucleus (Rt) in the rat were studied using anterograde and retrograde lectin tracing techniques, with sensitive immunocytochemical methods. The analysis was carried out to further investigate previously described subregions of the reticular thalamic nucleus, which are related to subdivisions of the dorsal thalamus, in the paraventricular and midline nuclei and three segments of the mediodorsal thalamic nucleus. Cortical inputs to the rostral reticular nucleus were found from lamina VI of cingulate, orbital and infralimbic cortex. These projected with a clear topography to lateral, intermediate and medial reticular nucleus respectively. Thalamic inputs were found from lateral and central segments of the mediodorsal nucleus to the lateral and intermediate rostral reticular nucleus respectively and heavy paraventricular thalamic inputs were found to the medial reticular nucleus. In the basal forebrain, afferents were found from the vertical and horizontal limbs of the diagonal band, substantia innominata, ventral pallidum and medial globus pallidus. Brainstem projections were identified from ventrolateral periaqueductal grey and adjacent sites in the mesencephalic reticular formation, laterodorsal tegmental nucleus, pedunculopontine nucleus, medial pretectum and ventral tegmental area. The results suggest a general similarity in the organisation of some brainstem Rt afferents in rat and cat, but also show previously unsuspected inputs. Furthermore, there appear to be at least two functional subdivisions of rostral Rt which is reflected by their connections with cortex and thalamus. The studies also extend recent findings that the ventral striatum, via inputs from the paraventricular thalamic nucleus, is included in the circuitry of the rostral Rt, providing further evidence that basal ganglia may function in concert with Rt. Evidence is also outlined with regard to the possibility that rostral Rt plays a significant role in visuomotor functions.

Calbindin D-28k and parvalbumin in the rat nervous system

This paper describes the distribution of structures stained with mono- and polyclonal antibodies to the calcium-binding proteins calbindin D-28k and parvalbumin in the nervous system of adult rats. As a general characterization it can be stated that calbindin antibodies mainly label cells with thin, unmyelinated axons projecting in a diffuse manner. On the other hand, parvalbumin mostly occurs in cells with thick, myelinated axons and restricted, focused projection fields. The distinctive staining with antibodies against these two proteins can be observed throughout the nervous system. Calbindin D-28k is primarily associated with long-axon neurons (Golgi type I cells) exemplified by thalamic projection neurons, strionigral neurons, nucleus basalis Meynert neurons, cerebellar Purkinje cells, large spinal-, retinal-, cochlear- and vestibular ganglion cells. Calbindin D-28k occurs in all major pathways of the limbic system with the exception of the fornix. Calbindin D-28k is, however, also found in some short-axon cells (Golgi type II), represented by spinal cord interneurons in layer II and interneurons of the cerebral cortex. It is also detectable in some ependymal cells and abundantly occurs in vegetative centres of the hypothalamus. The "paracrine core" of the nervous system and its adjunct (1985, Nieuwenhuys, Chemoarchitecture of the Brain. Springer, Berlin) is very rich in calbindin D-28k. The distribution of calbindin D-28k-positive neurons is very similar to that of the dihydroperydine subtype of calcium channels. Most of the cells containing calbindin D-28k are vulnerable to neurodegenerative processes. Parvalbumin-immunoreactive neurons have a different, and mostly complementary distribution compared with those which react with calbindin D-28k antisera, but in a few cases (Purkinje cells of the cerebellum, spinal ganglion neurons), both calcium-binding proteins co-exist in the same neuron. Many parvalbumin-immunoreactive cells in the central nervous system are interneurons (Golgi type II) and, to a lesser extent, long-axon cells (Golgi type I), whereas conditions are vice versa in the peripheral nervous system. Intrinsic parvalbuminic neurons are prominent in the cerebral cortex, hippocampus, cerebellar cortex and spinal cord. Long-axon parvalbumin-immunoreactive neurons are, for example, the Purkinje cells, neurons of the thalamic reticular nucleus, globus pallidus, substantia nigra (pars reticulata) and a subpopulation among large spinal-, retinal-, cochlear- and vestibular ganglion cells. Parvalbumin is rich in cranial nerve nuclei related to eye movements. In addition to nervous elements, parvalbumin immunoreactivity occurs in a few ependymal cells and in some pillar cells of the organ of Corti.(ABSTRACT TRUNCATED AT 400 WORDS)

Degeneration of neurons in the thalamic reticular nucleus following transient ischemia due to raised intracranial pressure: excitotoxic degeneration mediated via non-NMDA receptors?

Transient global ischemia was produced in rats by cisternal fluid infusion, producing a negative cerebral perfusion pressure by elevating the intracranial pressure (ICP) 25-50 mm Hg above mean arterial pressure (MAP). Animals were allowed to survive for 2-7 days following a transient ischemic episode of 5-30 min. The brains were examined for signs of ischemic degeneration in Nissl-stained sections and adjacent sections reacted with antisera against glial fibrillary acidic protein (GFAP) or aspartate aminotransferase (AAT). Neurons in the thalamic reticular nucleus (RT), a pure population of gamma-aminobutyric acid (GABA)ergic neurons which project their axons to thalamic relay nuclei, were found to have the lowest threshold for degeneration in this model, consistently undergoing degeneration under conditions which completely spared the hippocampal CA1 from degeneration. Whereas it took up to 30 min of complete ischemia to produce degeneration of CA1 neurons when ICP was raised using room temperature infusion fluids, 15 min of ischemia under these conditions was sufficient to produce extensive degeneration of neurons in the entire ventral 3/4 of the RT. Prolonged (greater than 25 min) episodes of partial ischemia (ICP less than or equal to MAP) were also sufficient to produce massive degeneration of RT neurons. The lesion in the RT was most clearly evident in sections reacted with antisera to GFAP, labeling intensely reactive protoplasmic astrocytes within the regions of the RT where neuronal degeneration had occurred. Neuronal loss and accompanying proliferation of microglial cells were evident in Nissl-stained sections but the extent of the neuronal loss was most clearly obvious in sections reacted with an antisera to AAT, an enzyme present in detectable quantities in GABAergic neurons. Pretreatment with the non-competitive NMDA antagonist MK-801 at doses sufficient to completely prevent massive degeneration of the hippocampal CA1 failed to prevent the degeneration of RT neurons, suggesting that if RT degeneration involves an excitotoxic process it acts through non-NMDA receptors.

The cholinergic influence upon rat dorsal lateral geniculate nucleus is dependent on state of arousal

Several lines of evidence suggest a role for acetylcholine (ACh) in mediating the effects of state of arousal on transfer of visual information through the lateral geniculate nucleus (LGN). Local application of cholinergic agonists to geniculate relay cells in anesthetized cats and rats produces predominantly facilitatory effects. This indicates that presynaptic release of ACh may be responsible for the increased excitability of LGN relay cells that is observed during waking and REM sleep. In this study in rats we have examined the influence of cholinergic agonists applied during the 3 natural states of arousal: waking, slow-wave (SW) sleep and rapid eye movement (REM) sleep. Pharmacological agents were iontophoretically administered to identified, single cells in head-restrained, unanesthetized rats free to sleep and wake. Application of cholinergic agonist produced state-dependent differences in response in all geniculate relay-cells studied. During both waking and REM sleep, a facilitatory response was always observed, whereas in SW sleep responses were of three types: no effect (62%), inhibition (24%), and biphasic inhibition followed by facilitation (14%). All response types were antagonized by scopolamine. In contrast to the qualitatively different state-dependent effects of cholinergic agonists, response to application of glutamate, with quantitative variations, was uniformly facilitatory in all states, though responses in SW sleep tended to be lower in magnitude. The effects of gamma-aminobutyric acid (GABA), glycine, and serotonin were inhibitory in all states. These data are consistent with the suggested role of ACh in mediation of increased relay-cell excitability during REM sleep and waking. Our findings, however, also indicate that in the transition from SW sleep to REM or waking, local release of ACh is not solely responsible for alterations in cell excitability.

Red nucleus of Macaca fascicularis: an electron microscopic study of its synaptic organization

The parvicellular and magnocellular divisions of the red nucleus of the old world monkey, Macaca fascicularis, were analyzed at an electron microscopic level to examine the morphology of the synaptic profiles terminating on rubral neurons and to categorize them by their individual characteristics. The parvicellular division, or anterior two-thirds of the nucleus, is composed of small (10-15 microns) and medium-size (20-30 microns) cells, which are uniformly distributed with high packing density throughout this portion of the nucleus. These cells have invaginated nuclei and are often indented by blood vessels and glial cell somata (satellite cells) that lie in close proximity. The magnocellular portion, occupying the caudal one-third of the nucleus, is composed of an additional population of large cells, ranging from 50-90 microns in diameter, which often contain prominent lipofuscin granules and are frequently indented by blood vessels. Satellite glial cells are not a prominent feature in the magnocellularis portion of the nucleus. The large cells are separated one from the other by fields of myelinated axons either coursing through the nucleus or projecting to and from the nucleus itself. Although the divisions of the nucleus in the Macaca fascicularis are spatially distinct, each possesses a morphological similarity in regard to the categories of synaptic profiles seen at the electron microscopic level. These synaptic profiles are classified as follows: large terminals containing numerous, predominantly rounded vesicles (LR), which can often be seen to form the central profile in a synaptic glomerular arrangement; terminals of similar size with predominantly rounded vesicles but with a pale axoplasmic matrix (LRP); small profiles with rounded vesicles (SR); profiles containing granular dense-cored vesicles (DCV); profiles with numerous flattened vesicles (F); profiles containing pleomorphic vesicles (PL), some of which can be interpreted as presynaptic dendrites (PSD) because they are seen to be postsynaptic and contain ribosomes; and profiles with rounded synaptic vesicles, which are associated with subsynaptic Taxi bodies (T). Most of the various synaptic profile types were found to have similar distributions on the dendritic arbors of rubral neurons in both divisions of the nucleus. However, the LRP-type terminal predominates on the cell bodies and proximal dendrites of the large neurons in magnocellularis. Unlike other regions in the nervous system, F type terminals are rarely seen to contact neuronal somata. This study provides a basis for future experimental studies of afferents to the nucleus in this species.(ABSTRACT TRUNCATED AT 400 WORDS)

Axonal arborizations of a magnocellular basal nucleus input and their relation to the neurons in the thalamic reticular nucleus of rats

A dense axonal plexus, arising in a portion of the magnocellular basal nucleus, was identified in the thalamic reticular nucleus in adult rats. The details of these axonal arbors as well as their relation to the neurons of the reticular nucleus were investigated by using Phaseolus vulgaris leucoagglutinin injections into the basal nucleus and intracellular injections of Lucifer yellow into reticular nucleus neurons. Axons arising in the caudal basal nucleus at the medial margin of the globus pallidus do not enter the dorsal thalamus but are confined to the reticular nucleus, where they arborize widely and densely. Neurons in the reticular nucleus are large, with sparsely spined and beaded dendrites, which radiate within the plane of the nucleus. Bouton-like swellings along basal nucleus axons are often found apposed to the somata of reticular nucleus neurons, although many are also apposed to dendrites. These morphological observations suggest a second potentially significant route, in addition to its well-known direct cortical projection, through which the magnocellular basal nucleus could influence cortical function: it may, by strategically modulating the excitability of reticular nucleus neurons, alter the general state of the thalamus and hence affect the initial transmission of information to the cortex.

Ultrastructural analysis of GABA-immunoreactive elements in the monkey thalamic ventrobasal complex

This study describes the ventrobasal complex of the primate by using GABA immunocytochemistry at the electron microscopic level. The primate ventrobasal complex has a similar synaptic organization to sensory thalamic nuclei in other species. Two synaptic profiles within the ventrobasal complex contain flattened or pleomorphic synaptic vesicles and are GABA-immunoreactive. F-boutons (= F1 type, Guillery's classification; Guillery: Z. Zellforsch. 96:1-38, '69) are located principally in the extraglomerular neuropil and contain densely packed flattened synaptic vesicles and several elongate mitochondria and establish symmetric (Gray's type II) synaptic contacts. These boutons are not found postsynaptic to any other element and are presynaptic principally to nonimmunoreactive elements that are thought to be thalamocortical relay cell dendrites. PSD-boutons (= F2 type, Guillery's classification) contain a moderate number of flattened or pleomorphic synaptic vesicles and fewer mitochondria than F-boutons. PSD-boutons are found in glomerular and extraglomerular areas of neuropil and establish symmetric synaptic contacts. These boutons are considered to be appendages of interneuron dendrites and are postsynaptic to RL-, RS (Guillery's classification)-, F-, and other PSD-boutons. PSD-boutons are presynaptic to thalamocortical relay neurons and interneuron dendrites including PSD-boutons. Problems in distinguishing F- from PSD-boutons are addressed by comparing immunostained and nonimmunostained material and by the use of serial sections. The majority of synaptic contacts between pleomorphic vesicle-containing profiles appear to be between PSD-boutons and other components of interneurons. Few contacts between F-boutons and local circuit neurons are seen. These data suggest the principal GABAergic input to interneurons in the primate ventrobasal complex is derived from other interneurons.

Burst discharges of thalamic reticular neurons: an intracellular analysis in anesthetized rats

In order to analyze the mechanism of burst discharges intracellular recordings were made from 27 somatosensory thalamic reticular (S-TR) neurons in urethane-anesthetized rats. Burst discharges, composed of 2-7 spikes, were always superposed on a slow depolarization (SD) lasting for 40-60 ms, which appeared only when the membrane was hyperpolarized. The number of spikes superposed on an SD varied depending upon the amplitude of the SD. A single shock stimulation of the lemniscus medialis elicited a series of SDs, each without being preceded by a phasic hyperpolarizing potential. The SDs were repeated with spindle rhythms. Evidence has been provided that EPSPs contribute to the mechanism for triggering SDs. In spontaneous rhythmic SDs occurring with the rhythm of EEG spindles, steps representing EPSPs were recordable on the rising phase of each SD. It is suggested that excitatory synaptic inputs to S-TR neurons with the spindle rhythm are responsible for the rhythmic generation of SDs. Ventrobasal relay neurons are presumed as the source of the inputs.

First month of development of fetal neurons transplanted as a cell suspension into the adult CNS

It has been demonstrated elsewhere that fetal thalamic tissue, when transplanted as a cell suspension into the excitotoxically neuron-depleted adult somatosensory thalamus, can grow, differentiate, and receive projections from host afferents. In the present study, we used the same paradigm to analyse the transplanted neurons during their morphogenesis, i.e. during the first month after transplantation. Using various anatomical criteria, at the light and electron microscope levels, we compared the development of transplanted neurons with the normal ontogeny of homologous neuronal populations. Confined solely to the mechanically lesioned area during implantation at seven days post-grafting, the transplant increased in size to occupy most of the previously neuron-depleted area by the third week after grafting. The final size of the transplant thus depended upon the size of the lesion. At seven days post-grafting, the neurons were small in size and the cellular density was high. At this immature stage few synaptic contacts were visible and the ultrastructure was characterized by large extracellular spaces. At 10 days post-grafting, the size of the neurons had increased and the cellular density had decreased. Both an extensive dendritic proliferation and a simultaneous active synaptogenesis could also be observed. All these events continued to evolve and during the third week the neuropil progressively acquired more mature ultrastructural characteristics. Synaptic contacts exhibiting characteristics comparable to those observed in the intact thalamus also became more numerous. At 20 days post-grafting, axonal myelination had started, the development of the graft apparently stopped and the various criteria had stabilized. Until that developmental stage, growth of grafted neurons compared to that of normal thalamic ones. At later stages, however, grafted neurons failed to grow larger and did not reach the size of the homologous population in the adult animal. It seems, therefore, that transplants of thalamic fetal neurons can be used as a tool with which to study thalamic neuronal development, within definable limits.

The Topographic Organization and Axis of Projection within the Visual Sector of the Rabbit's Thalamic Reticular Nucleus

The organization of the visual field representation within the thalamic reticular nucleus (TRN) of the rabbit was studied. Focal injections of horseradish peroxidase (HRP) and/or [3H]proline were made into visuocortical areas V1 and V2 and the dorsal lateral geniculate nucleus (dLGN). The resultant labelling in the thalamus was analysed. A single injection in V1 or V2 results in a single zone of terminal label within the TRN that is restricted to the dorsocaudal part of the sheet-like nucleus. In comparisons of the zones of label following injections at two different cortical sites in V1, a medial to lateral shift in label across the thickness of the TRN sheet is accompanied by a medial to lateral shift in label in the dLGN; a dorsal to ventral shift in label within the plane of the TRN sheet is accompanied by a dorsal to ventral shift in label in the dLGN. Thus, like the dLGN the TRN receives a precise topographic projection from V1. In reconstructions from horizontal sections the zones of label within the TRN resemble 'slabs', which lie within the plane of the nucleus parallel to its borders. Thus, the slabs of visuocortical terminals and reticular dendrites are similarly oriented. As revealed by the orientation of the slabs, the lines of projection representing points in visual space are represented by the oblique rostrocaudal dimension of the TRN. Injections restricted to V1 produce terminal labelling that is confined to the outer two-thirds of the TRN across its thickness, whilst those involving V2 result in terminal labelling within the inner one-third of the nucleus. Thus, the adjacent cortical areas V1 and V2 project in a continuous fashion across the mediolateral dimension of the TRN. The organization of the map within the TRN, which was revealed by visuocortical injections, was confirmed by the pattern of retrograde labelling within the nucleus following geniculate injections of HRP. On the basis of these findings and those in other mammalian species, two major conclusions can be reached that alter our view of the TRN. First, rather than mapping onto the whole nucleus in a continuous fashion, the cortical projection to the TRN has significant discontinuities. Second, rather than integrating efferents from widespread cortical areas, the reticular dendrites are related to focal areas of cortex.

Excitatory amino acid treatment of the ventromedial globus pallidus enhances dopamine utilization in the prefrontal cortex of the rat via the thalamic mediodorsal nucleus

Infusion of a low dose (5 microM) of the cell-selective chemical excitant quisqualic acid (QUIS) into rostral ventromedial globus pallidus (GP) had no immediate effect on DA utilization (assessed as [DOPAC]:[DA] and [HVA]:[DA] ratios) in either the medial bank of the prefrontal cortex (FCx) or the agranular insular cortex (AgCx). In contrast, a larger dose (630 microM) of another excitant sodium ibotenate (IBO) produced an immediate bilaterally symmetrical increase in both indices of DA utilization in FCx. There was also a marked trend towards a bilateral increase in these indices of DA utilization in AgCx. In order to determine whether these effects on cortical DA utilization are mediated by a direct cortical route or via the thalamic mediodorsal nucleus (lateral division, MDL), infusions of IBO into GP were repeated in animals with a 1-week-old N-methyl-D-aspartate lesion of MDL. The increase in DA utilization of FCx following infusion of IBO into GP was abolished, although the trend towards increased DA utilization in AgCx was still maintained. Since MDL innervates FCx but not AgCx and since we have previously shown that MDL lesions alone have no effect on DA utilization in either cortical region, the present results suggest that the changes in cortical DA utilization are probably mediated via MD. Thus in addition to the well-documented control exerted by the thalamus over brain DA function, this has now been extended in the present study to include GP, which projects both directly and indirectly to the thalamus.

Ultrastructure of ChAT-immunoreactive synaptic terminals in the thalamic reticular nucleus of the rat

The thalamic reticular nucleus has been shown to receive cholinergic innervation from both the nucleus basalis of Meynert in the forebrain and the pedunculopontine and laterodorsal tegmental nuclei in the brainstem (Steriade et al.: Brain Res. 408:372-376, '87; Levey et al.: Neurosci. Lett. 74:7-13, '87). Relatively dense populations of choline acetyltransferase-(ChAT) immunoreactive axons and terminallike varicosities have been shown to be distributed throughout this nucleus (Levey et al.: J. Comp. Neurol. 257:317-332, '87). In this study, the ultrastructure of ChAT-immunoreactive axons and of their synaptic terminals in the reticular nucleus was examined in the electron microscope. All ChAT-immunoreactive axonal profiles in the reticular nucleus were presynaptic; the postsynaptic elements were exclusively dendritic profiles; and no axo-axonic or axosomatic contacts from labelled axons were observed. Most ChAT-immunoreactive synaptic contacts were made by profiles less than 0.25 micron in minor diameter. Single ChAT-immunoreactive axons made synaptic contact with several dendritic profiles as the axons were followed through serial sections. These results suggest that the cholinergic innervation of the reticular nucleus will modulate the function of reticular neurons by synapsing onto the dendrites of its neurons without direct effect on the corticothalamic and thalamocortical terminals which also innervate the reticular nucleus.

Synaptic organization of the thalamic reticular nucleus

This study describes the synaptic organization of the thalamic reticular nucleus (TRN) in the rat, cat, and monkey using electron microscopy combined with immunocytochemistry, degeneration, or horseradish peroxidase (HRP) tracing methods. Three morphological types of terminals are described in the TRN of the rat: a small terminal with densely packed spherical vesicles (D-terminal), which originates from the cortex; a large terminal with loosely packed spherical vesicles (L-terminal), which originates in the dorsal thalamus; and a terminal containing flattened synaptic vesicles (F-terminal) that is probably a TRN recurrent collateral. The cortical input to the TRN has been shown by double-labeling studies to terminate directly upon TRN projection neurons. Similar classes of terminals are found in the TRN of cat and monkey, but there is in addition a large terminal with spherical synaptic vesicles that is invaginated by dendritic spines. Also present in the cat and monkey, but not in the rat, are vesicle-containing dendrites and dendritic appendages. In the rat, degeneration experiments indicate that the terminals of TRN projection neurons in the dorsal thalamus are F-terminals. These terminals contain flattened synaptic vesicles and exhibit GABA immunoreactivity.

Electrophysiological characteristics of morphologically identified reticular thalamic neurons from rat slices

This study is aimed at the investigation of the morphological and electrophysiological characteristics of neurons from the nucleus reticularis thalami in rat thalamic slices incubated in vitro. Ten neurons were recorded in the ventrobasal complex, four of which were successfully injected following horseradish peroxidase injection. Two main types of reticular thalamic neurons were morphologically identified: (1) the small fusiform 'f' cells characterized by a very elongated perikaryon, dendritic arborization prevalent in the rostrocaudal and dorsoventral planes, and an axon without any collaterals branching within the nucleus reticularis thalami; and (2) the large fusiform 'F' neurons with dendrites arborizing mainly in the horizontal plane and with axonal branches within the nucleus reticularis thalami. The electrophysiological properties of the neurons were similar in F and f cells. The reticular neurons showed, in resting conditions, a single spike response followed by a postexcitatory hyperpolarizing potential. The hyperpolarization of these neurons transformed the single spike response into a burst discharge similar to that observed in thalamic relay neurons at resting membrane potential. The same phenomenon was observed when bicuculline was administered by perfusion to the slices and, in this case, a recovery to a single spike response was obtained by a depolarizing d.c. current injection. By contrast, the local administration of GABA induced a depolarization with a pronounced decrease in input resistance. The present data demonstrate the presence of at least two neuronal subtypes within the nucleus reticularis thalami, suggesting that only one is responsible for the phenomenon of auto-inhibition by means of intrinsic axon collaterals. Moreover, it is hypothesized that intranuclear GABAergic collaterals could control neuronal excitability of reticular thalamic cells by both shunting the membrane and shifting the burst firing to a single spike firing mode.

Fetal homotypic transplant in the excitotoxically neuron-depleted thalamus: light microscopy

One month after an in situ injection of kainic acid into the ventrobasal thalamic complex (VB), the lesioned area is totally depleted of neurons. The present study has been undertaken to determine the cytoarchitecture and connectivity of the nucleus constructed by fetal thalamic neurons implanted into the excitotoxically lesioned area. Adult rats received an injection of kainic acid inducing a total neuronal depletion of the right lateral thalamus (including both the nucleus reticularis thalami and the lateral portion of the ventrobasal complex). One month later, homotypic neurons were taken from the dorsal thalamic primordium of rat embryos (gestational age 15-16 days), dissociated, and injected into the lesioned area as a cell suspension. After 2-4-month survival, the cytoarchitecture of the neonucleus formed by the grafted neurons within the previously neuron-depleted area was analyzed. Additionally, connectivity was analyzed in seven rats in which dorsal column nuclei and/or cortical projections to the area were labeled anterogradely with either 3H-leucine or wheat-germ agglutinin conjugated to HRP, and the animals were perfused and processed following various histological procedures (Nissl staining, autoradiographic processing, and histochemistry for visualization of peroxidase). Fetal neurons grew, differentiated, and progressively occupied the previously neuron-depleted area of the adult host CNS. They organized themselves into a neonucleus with particular cytoarchitectural features including 1) the existence of two concentric zones--a central zone containing neurons and glial cells and a marginal zone only filled with a band of glial cells, 2) an increase in cellular density compared to the intact thalamus, 3) the grouping of neurons in spherical clusters, and 4) apparent polymorphism of neuronal somata. Lemniscal and corticothalamic afferents originating from the host were observed in the neonucleus when the fetal neurons had been implanted correctly into the lesioned area but not when they had been misplaced into either normal thalamic tissue or the internal capsule. The afferents labeled from either the dorsal column nuclei or the somatosensory cortex were, however, less dense in the neonucleus than in the normal thalamus. These results are discussed with regard to the normal cytoarchitecture and connectivity of the ventrobasal complex of the rat thalamus.

Fine structure of the dorsal part of the nucleus submedius of the rat thalamus: an anatomical study with reference to possible pain pathways

The dorsal portion of the nucleus submedius of the rat thalamus receives spinal and trigeminal projections which may convey noxious inputs. The present study was undertaken to analyse the fine structure of the nucleus with particular reference to a possible trigemino-thalamo-prefrontal cortical pathway relaying in nucleus submedius. Presynaptic terminals in the dorsal portion of the nucleus submedius were classified into three broad categories usually observed in thalamic nuclei: "small round", "flat" and "large round" types. Axonal tracing using either anterograde transport of horseradish peroxidase or degeneration methods indicated that some "small round" terminals originate from the pre-frontal cortex. Some "large round" terminals were labelled from the trigeminal subnucleus caudalis. These "large round" terminals exhibited distinct morphological features when compared with trigeminal terminals in other thalamic nuclei. In particular they made synaptic contacts predominantly with dendritic protrusions and were surrounded by multilamellate astrocytic processes. Double-labelling experiments were performed by means of the combined retrograde transport of horseradish peroxidase and Wallerian degradation techniques. Terminals degrading after lesion of the trigeminal subnucleus caudalis contacted submedius neurons labelled retrogradely from the prefrontal cortex. These observations demonstrate the existence of a direct monosynaptically relayed pathway from subnucleus caudalis to prefrontal cortex which relays in the dorsal part of nucleus submedius.

Two types of thalamic reticular cells in relation to the two visual thalamocortical systems in the rat

We found in urethane-anesthetized rats that thalamic reticular (TR) cells responding to an electrical stimulus of the optic tract (OT) can be further subdivided into two types, viz. S- and L-type cells. S-type cells, which were selectively excited from area 17 of the visual cortex, were characterized by short latency responses (2.3-6.1 ms) to OT stimulation. TR cells activated antidromically from the dorsal lateral geniculate nucleus were all classified as S-type. Long OT latencies (5.2-15.3 ms) and selective excitation from area 18a were peculiar to L-type cells, which showed antidromic responses to the lateral posterior nucleus stimulation. Mapping studies documented that cells belonging to each type were segregated in the thalamic reticular nucleus; L-type cells were located in the most posterior part. It is suggested that S- and L-type cells are inhibitory interneurons modulating activity of geniculocortical and extrageniculocortical projection cells, respectively.

Projections of brainstem core cholinergic and non-cholinergic neurons of cat to intralaminar and reticular thalamic nuclei

We combined the retrograde transport of wheat germ agglutinin conjugated with horseradish peroxidase with choline acetyltransferase immunohistochemistry to study the projections of cholinergic and non-cholinergic neurons of the upper brainstem core to rostral and caudal intralaminar thalamic nuclei, reticular thalamic complex and zona incerta in the cat. After wheat germ agglutinin-horseradish peroxidase injections in the rostral pole of the reticular thalamic nucleus, the distribution and amount of retrogradely labeled brainstem neurons were similar to those found after tracer injection in thalamic relay nuclei (see preceding paper). After wheat germ agglutinin-horseradish peroxidase injections in the caudal intralaminar centrum medianum-parafascicular complex, rostral intralaminar central lateral-paracentral wing, and zona incerta, the numbers of retrogradely labeled brainstem neurons were more than three times higher than those found after injections in thalamic relay nuclei. The larger numbers of horseradish peroxidase-positive brainstem reticular neurons after tracer injections in intralaminar or zona incerta injections results from a more substantial proportion of labeled neurons in the central tegmental field at rostral midbrain (perirubral) levels and in the ventromedial part of the pontine reticular formation, ipsi- and contralaterally to the injection site. Of all retrogradely labeled neurons in the caudal midbrain core at the level of the cholinergic peribrachial area and laterodorsal tegmental nucleus, 45-50% were also choline acetyltransferase-positive after the injections into central lateral-paracentral and reticular nuclei, while only 25% were also choline acetyltransferase-positive after the injection into the centrum medianum-parafascicular complex. These findings are discussed in the light of physiological evidence of brainstem cholinergic mechanisms involved in the blockade of synchronized oscillations and in activation processes of thalamocortical systems.

Afferent projections to the dorsal thalamus of the rat as shown by retrograde lectin transport--I. The mediodorsal nucleus

The topography of afferent projections to the mediodorsal thalamic nucleus of the rat has been studied using the retrograde transport of unconjugated wheat germ agglutinin as identified by immunocytochemistry. Inputs were defined according to the lateral, central or medial segments of the nucleus injected, and controlled by additional injections into the habenula, central medial and paraventricular nuclei of the thalamus. Cortical afferents to the lateral segment arose from anterior cingulate and prelimbic areas on the medial surface of the hemisphere, those to the central segment arose mainly from ventral orbital area, whilst those to the medial segment arose from the infra-limbic and agranular insular areas. This strict cortical topography was matched by the organization of afferents from the reticular thalamic nucleus; i.e. lateral, intermediate and medial reticular neurons from the rostral nucleus projected to lateral, central and medial segments of the mediodorsal thalamus respectively. In the basal forebrain ventral pallidum projected only to the medial segment, whilst magnocellular preoptic region projected only to the central segment. Lateral preoptic area projected to lateral and central segments and the diagonal band mainly to central segment. Projections from substantia innominata were found regardless of the area of mediodorsal nucleus injected. The paraventricular nucleus of thalamus, lateral habenula and substantia nigra reticulata projected to the lateral segment only, whilst central gray projected only to the medial segment. Projections from amygdala (mainly basolateral and central nucleus) were found only following central and medial segment injections. All regions of the mediodorsal nucleus injected received input from the lateral hypothalamus, the ventral tegmental area and the dorsal tegmental gray. The results are discussed and particular emphasis is placed on the possible functions of the thalamocortical connections and the role of the reticular thalamic nucleus as a potential regulator of thalamocortical activity.

The intrinsic organization of the ventroposterolateral nucleus and related reticular thalamic nucleus of the rat: a double-labeling ultrastructural investigation with gamma-aminobutyric acid immunogold staining and lectin-conjugated horseradish peroxidase

An electron-microscopic investigation of the synaptic organization of the rat's ventroposterolateral nucleus (VPL) and of a reticular thalamic nucleus (RTN) area related to somatosensory thalamic nucleus was performed. In a group of 11 rats, wheatgerm agglutinin conjugated to horseradish peroxidase (WGA:HRP) was injected either in the first somatosensory area of cortex (SI) or in the dorsal column nuclei (DCN). The retrogradely and/or anterogradely transported enzyme was visualized using paraphenylenediamine-pyrocatechol (PPD-PC) as substrate. In a second series of six experiments, an immunocytochemical procedure using a specific anti-gamma-aminobutyric acid (anti-GABA) was employed. Postembedding localization of GABA was performed for ultrastructural observation by means of the colloidal gold immunostaining procedure. Thin sections of recognized VPL and RTN areas from WGA:HRP-injected animals were further processed for immunocytochemistry in order to localize simultaneously, at the electron-microscopic level, the transported enzyme and GABA. The results obtained with this procedure demonstrated that HRP-labeled terminals from DCN contacted the soma and proximal dendrites of VPL neurons, while the terminals labeled after SI cortical injections were predominantly localized to the distal portion of the dendrites. The same cortical injection also determined the presence of labeled synaptic boutons contacting the soma, and both proximal and distal dendrites of RTN neurons. GABA-immunolabeled terminals were observed in VPL in a number larger than those observed with other methods, since not only typical F terminals were labeled but also terminals containing round and/or pleomorphic vesicles. GABA-ergic terminals contacted the soma and the proximal and distal dendrites of VPL neurons, while in RTN cells they made synaptic contact mainly with the soma and proximal dendrites. In the double-labeling experiments, terminals containing both HRP and specific immunogold GABA staining were never observed. The present data provide a direct demonstration of the presence of a strong inhibitory input from RTN upon VPL neurons and of the existence of autoinhibition within RTN neurons.

Neuronal organization of rat thalamus for processing information of vibrissal movements

Vibrissa-responding neurons were searched for in the somatosensory part of the thalamic reticular nucleus (S-TR) and in the ventrobasal nucleus (VB) in urethane-anesthetized rats. More than 90% of the recorded neurons of both species had receptive fields (RFs) on single vibrissae. Movements of RF-vibrissae produced a burst of multiple discharges in S-TR neurons and single spike discharges followed by a prominent suppression of spontaneous discharges in VB neurons. Antidromic invasion from stimulation of the somatosensory cortex in VB neurons was suppressed after RF-vibrissae were stimulated. A possible functional organization comprising VB and S-TR neurons for processing impulses of vibrissal movements was suggested.