Projections of medial thalamic nuclei to putamen and cerebral frontal cortex in the cat

Whole-Brain Afferent Inputs to the Caudate Nucleus, Putamen, and Accumbens Nucleus in the Tree Shrew Striatum

Day-active tree shrews have a well-developed internal capsule (ic) that clearly separates the caudate nucleus (Cd) and putamen (Pu). The striatum consists of the Cd, ic, Pu, and accumbens nucleus (Acb). Here, we characterized the cytoarchitecture of the striatum and the whole-brain inputs to the Cd, Pu, and Acb in tree shrews by using immunohistochemistry and the retrograde tracer Fluoro-Gold (FG). Our data show the distribution patterns of parvalbumin (PV), nitric oxide synthase (NOS), calretinin (CR), and tyrosine hydroxylase (TH) immunoreactivity in the striatum of tree shrews, which were different from those observed in rats. The Cd and Pu mainly received inputs from the thalamus, motor cortex, somatosensory cortex, subthalamic nucleus, substantia nigra, and other cortical and subcortical regions, whereas the Acb primarily received inputs from the anterior olfactory nucleus, claustrum, infralimbic cortex, thalamus, raphe nucleus, parabrachial nucleus, ventral tegmental area, and so on. The Cd, Pu, and Acb received inputs from different neuronal populations in the ipsilateral (60, 67, and 63 brain regions, respectively) and contralateral (23, 20, and 36 brain regions, respectively) brain hemispheres. Overall, we demonstrate that there are species differences between tree shrews and rats in the density of PV, NOS, CR, and TH immunoreactivity in the striatum. Additionally, we mapped for the first time the distribution of whole-brain input neurons projecting to the striatum of tree shrews with FG injected into the Cd, Pu, and Acb. The similarities and differences in their brain-wide input patterns may provide new insights into the diverse functions of the striatal subregions.

Cerebral hemisphere regulation of motivated behavior

The goals of this article are to suggest a basic wiring diagram for the motor neural network that controls motivated behavior, and to provide a model for the organization of cerebral hemisphere inputs to this network. Cerebral projections mediate voluntary regulation of a behavior control column in the ventromedial upper brainstem that includes (from rostral to caudal) the medial preoptic, anterior hypothalamic, descending paraventricular, ventromedial, and premammillary nuclei, the mammillary body, and finally the substantia nigra and ventral tegmental area. The rostral segment of this column is involved in controlling ingestive (eating and drinking) and social (defensive and reproductive) behaviors, whereas the caudal segment is involved in controlling general exploratory or foraging behaviors (with locomotor and orienting components) that are required for obtaining any particular goal object. Virtually all parts of the cerebral hemispheres contribute to a triple descending projection - with cortical excitatory, striatal inhibitory, and pallidal disinhibitory components - to specific parts of the behavior control column. The functional dynamics of this circuitry remain to be established.

Striatal and cortical projections of single neurons from the central lateral thalamic nucleus in the rat

Striatal and cortical projections arising from the central lateral thalamic nucleus were studied in rats by tracing the axons of small pools of neurons labeled anterogradely with biocytin. Cells of the central lateral nucleus have a morphology that conforms to the classic descriptions of the bushy cells which represent the main neuronal type of most thalamic nuclei. They display many short radiating dendrites studded with sessile spines, protrusions and grapelike appendages. The total extent of their dendritic fields is about 250 mu m. After leaving the nucleus, all central lateral axons course through the rostrolateral pole of the thalamic reticular nucleus, where they branch profusely, enter the striatum, where they distribute collaterals, and arborize in the motor cortex. At striatal level, central lateral fibers form a loosely organized network composed of varicose axonal branches that appear to contact en passant several striatal neurons. In the cortex. central lateral axons from multiple (four to five patches of terminations in layers Va and III aligned along the rostrocaudal extent of the motor area. The projection to layers I and II is very sparse, consisting of occasional branches which show few ramifications. Our results indicate that most, and perhaps all, central lateral relay neurons project to both the striatum and cerebral cortex. The patchy innervation of mid cortical layers of the frontal motor areas by central lateral afferents strongly argues against the nonspecific character of this projection. It is proposed that the central lateral nucleus, which receives a strong innervation from brainstem cholinergic afferents, takes part in a mechanism of attention related to the central initiation of directed patterns of movements.

A single-cell study of the axonal projections arising from the posterior intralaminar thalamic nuclei in the rat

Thalamostriatal projections arising from the posterior intralaminar nuclei (P1; the parafascicular nucleus and the adjacent caudalmost part of the posterior thalamic group) were studied in rats by tracing the axons of small pools of neurons labelled anterogradely with biocytin. Thirteen P1 cells were also stained by juxta cellular application of the tracer. Relay cells of P1 nuclei have a morphology that differs radically from the classical descriptions of the bushy cells which represent the main neuronal type of the sensory thalamic relay nuclei. P1 cells have ovoid or polygonal somata of approximately 20-25 microm, from which emerge four or five thick, long and poorly branched dendrites bearing spines and filamentous appendages; their dendritic domains extend for up to 1.5 mm. Before leaving the nucleus 20% of axons give off collaterals that ramify locally. All axons course through the thalamic reticular nucleus, where they also distribute collaterals, and arborize massively in the striatum and sparsely in the cerebral cortex. At the striatal level four or five collaterals leave the main axon and terminate in patches scattered dorsoventrally within a rostrocaudally oriented slab. As revealed by calbindin D-28k immunohistochemistry, only the matrix compartment receives terminations from P1 axons. The cortical branch form small terminal puffs centred upon layer VI of the motor cortex. Before entering the striatum some axons of the parafascicular nucleus give rise to descending collaterals that arborize in the entopeduncular nucleus, in the subthalamic nucleus and in the vicinity of the red nucleus. Other axons arising from the caudal part of the posterior group send descending branches only to the entopeduncular nucleus. These findings show that P1 cells belong to a distinct category of thalamic relay neurons which, beside their massive projection to the striatum, also distribute collaterals to other components of the basal ganglia. Moreover, these results provide the first direct evidence that virtually all P1 cells project to both striatum and cerebral cortex. Finally, it is proposed on the basis of morphological, histochemical and hodological criteria that the caudal part of the posterior thalamic group in the rat is homologous to the suprageniculate-limitans nuclei of cats and primates.

The projections from the parafascicular thalamic nucleus to the subthalamic nucleus and the striatum arise from separate neuronal populations: a comparison with the corticostriatal and corticosubthalamic efferents in a retrograde fluorescent double-labelling study

The parafascicular thalamic nucleus projects to the subthalamic nucleus and the striatum. Double-retrograde fluorescent tracing was used to determine whether these projections arise from the same neurons via axon collaterals. True Blue was injected into the subthalamic nucleus and Nuclear Yellow was injected into the striatum of each rat and the parafascicular thalamic nucleus was examined under the fluorescence light-microscope. Individual parafascicular neurons were not double-labelled with the tracers. The True Blue- and Nuclear Yellow-labelled neurons wee located in different parts of the parafascicular nucleus ipsilateral to the injections. In the rostral part of the parafascicular nucleus, True Blue-labelled neurons were located ventral to the fasciculus retroflexus, and in the caudal part of the nucleus. True Blue-labelled neurons were located close to the medial and lateral borders of fasciculus retroflexus. Nuclear Yellow-labelled neurons were found mainly to encircle the fasciculus retroflexus in the rostral part of the parafascicular nucleus and in the dorsolateral sector of the caudal part of the parafascicular nucleus. Double-labelled neurons were, however, found in the cortex. The proportion of neurons projecting to both the subthalamic nucleus and the striatum accounted for 38% of the total number of cortiscosubthalamic neurons in the prefrontal cortex, 15.5% in the cingulate cortex and 9% in the sensorimotor cortex. The present finding of an individualization between the parafascicular efferents to the subthalamic nucleus and the striatum emphasize the importance of this projection and provides further evidence of the associative functions attributable to the subthalamic nucleus.

Cerebrovascular changes elicited by electrical stimulation of the centromedian-parafascicular complex in rat

Electrical stimulation of the centromedian-parafascicular complex (CM-Pf) in anesthetized (chloralose) and paralyzed (tubocurarine) rats elicits a widespread cerebrovascular dilatation. Regional cerebral blood flow (rCBF) was measured in dissected tissue samples of 10 brain regions (medulla, pons, cerebellum, inferior colliculus, superior colliculus, frontal parietal and occipital cortices, caudate-putamen and corpus callosum) by [14C]iodoantipyrine method. In unstimulated and sham-operated rats rCBF ranged from 40 +/- 3 (ml/100 g/min) in corpus callosum to 86 +/- 6 (ml/100 g/min) in inferior colliculus. During CM-Pf stimulation, rCBF increased significantly (P less than 0.05, analysis of variance and Scheffe's test) in all cerebral regions bilaterally ranging from +118% in parietal cortex to +38% in cerebellum. Although cerebral vasodilation elicited by CM-Pf stimulation persisted after unilateral transection of the cervical sympathetic trunk, the cortical CBF was significantly reduced (P less than 0.05) on the denervated side. Acute adrenalectomy significantly (P less than 0.05) decreased elevated rCBF during CM-Pf stimulation in all cortical regions (frontal-36%, parietal -34%, and occipital -27%) and in caudate nucleus (-37%). Thus, excitation of neurons originating in, or fibers passing through the CM-Pf can elicit a powerful cerebral vasodilation. The cerebral vasodilation is modulated by cervical sympathectomy and circulating adrenal hormones. We conclude that CM-Pf elicited vasodilation is at least partly mediated by intrinsic neural pathways.

Single intralaminar thalamic neurons project to cerebral cortex, striatum and nucleus reticularis thalami. A retrograde anatomical tracing study in the rat

The hypothesis of triple axonal branching to the cortex, striatum and nucleus reticularis thalami (RT) of the forebrain projecting thalamic intralaminar neurons (TIN) was studied by retrograde axonal transport of horseradish peroxidase (HRP), iron-dextran complex and [3H]wheat germ agglutinin [3H]WGA. The best combination of tracers for this purpose was demonstrated to be: HRP-pellet implantation in the rostral cortex, iron-dextran injections into the striatum and [3H]WGA injections into the rostral RT. Prussian blue labeled neurons were observed in the ipsilateral TIN, substantia nigra, mediodorsal nucleus, medial part of the ventral anterior-ventral lateral complex, anterior medial and anterior ventral nuclei. HRP labeled neurons were observed in ipsilateral ventral nuclei, mediodorsal nucleus and the TIN. Radiolabeled neurons were located only in the TIN. HRP-Prussian blue labeled neurons (cortex-striatum branched neurons) were scattered in the TIN. Prussian blue radiolabeled neurons (striatum-RT branched neurons) could be observed in the TIN, as well as a few HRP radiolabeled neurons (cortex-RT branched neurons). Triply labeled neurons were scattered throughout the TIN until the rostral part of the centre median nucleus. These results demonstrate the existence of triple axonal branching on TIN efferent axons directed to the cerebral cortex, striatum and RT. The RT directed branch provides an anatomical basis to describe an intrathalamic regulatory loop well suited to control ascending messages arising from the TIN.

Organization of thalamic projections in the nucleus accumbens and the caudate nucleus in cats and its relation with hippocampal and other subcortical afferents

The organization of thalamic projections in the nucleus accumbens (NA) and the caudate nucleus of cats and its relation to other subcortical striatal afferents were studied with a retrograde tracing technique by use of lectin-conjugated horseradish peroxidase. The study showed that the paraventricular and medial parafascicular nuclei (PF) of the thalamus project to the medial NA and the parataenial and medial PF project to the lateral NA. The ventral tegmental area and substantia nigra pars dorsalis (SNpd) project to medial and lateral NA. The midline thalamic nuclei, rostral intralaminar nuclei, ventroanterior nucleus, medial and lateral PF, lateral posterior complex, and nucleus limitans project to medial caudate nucleus. The most medial substantia nigra pars compacta (SNpc) and rostral SNpd project to medial caudate nucleus. The center median, ventrolateral, and the central lateral nuclei of thalamus, SNpc, and SNpd project to lateral caudate nucleus. These results suggest that the thalamic and subcortical nuclei known to connect with the limbic and frontal cortices project to NA and medial caudate nucleus. Those thalamic nuclei connected with the motor system project to lateral caudate nucleus. The hippocampus projects selectively to medial NA. The amygdala, raphe, and other mesencephalic nuclei project only to NA and medial caudate nucleus. The organization of hippocampal, amygdala, and other subcortical afferents suggests that NA and caudate nucleus can be separated into medial "limbic" and lateral nonlimbic "sensory-motor" compartments. A brief review of the distribution pattern of some neurotransmitters, neuropeptides, and their receptors and behavior studies provides additional support to the concept that the striatum can be divided into several subcompartments.

Distinct commissural pathways are involved in the enhanced release of dopamine induced in the contralateral caudate nucleus and substantia nigra by unilateral application of GABA in the cat thalamic motor nuclei

The effects of diencephalic or telencephalic commissural sectioning on the changes in [3H]dopamine ([3H]DA) release from nerve terminals (in the caudate nucleus, CN) and dendrites (in the substantia nigra, SN) of the two nigro-striatal dopaminergic pathways induced by the application of GABA (10(-5) M, 30 min) into the left ventralis medialis (VM) or ventralis lateralis (VL) thalamic nuclei were investigated. Experiments were performed in halothane-anesthetized cats implanted with push-pull cannulae in both CN and SN. In unlesioned cats, GABA application into the left VM-VL increased [3H]DA release in both CN and in the contralateral SN confirming previous results. Sectioning of the thalamic massa intermedia only blocked the GABA-induced increase in [3H]DA release in the contralateral SN, the responses in both CN being preserved. Sectioning of the rostral part of the corpus callosum only prevented the GABA-induced increase in [3H]DA release in the contralateral CN, whereas [3H]DA release in the ipsilateral CN and in the contralateral SN was still enhanced. These results suggest that changes in [3H]DA release evoked in both CN and in the contralateral SN by GABA application into the left VM-VL might involve different mechanisms: those observed in the CN result from potent pre-synaptic influences mediated by the bilateral cortico-striatal projections; those induced in the contralateral SN are due to other types of messages involving or passing through the thalamic massa intermedia.

The thalamostriatal projection in the cat

The organization of the projections from the intralaminar and other thalamic nuclei to the caudate nucleus (CD), putamen (PU), nucleus accumbens (Acc), and olfactory tubercle (TO) were examined in the cat by autoradiography after deposits of 3H-amino acids in individual thalamic nuclei and by retrograde cell labeling after intrastriatal deposits of wheat-germ-conjugated horseradish peroxidase. All of the rostral intralaminar nuclei, here considered to include the central lateral (CL), paracentral (PC), central medial (CeM), and rhomboid nuclei (Rh), project to the striatum. Projections closely associated with those of the rostral intralaminar group arise from cells of the paraventricular nucleus (PV) and a region lateral to the stria medullaris. These nuclei, which roughly form a ring around the mediodorsal nucleus, project in a highly particular, but loosely arranged topographic pattern to all parts of the striatum. The medially located cells in Rh, PV, and those alongside the stria medullaris project mainly to medial parts of Acc and CD; the dorsolaterally located cells of CL project mainly to the dorsolateral parts of CD and PU; cells in PC and CeM project to progressively more ventral and medial parts of CD and PU, and the lateral part of Acc. Superimposed on this projection from the rostral intralaminar region is the projection from the caudal intralaminar group including the centromedian (CM), parafascicular (PF), and subparafascicular nuclei (subPF). Together these nuclei project in a loosely but specifically organized topography to the entire striatum. The lateral and dorsal parts of CD and PU receive fibers mainly from CM. Ventral and medial parts of CD and PU and Acc receive fibers mainly from PF; TO receives fibers from subPF and the ventral part of PF. Several nuclei in the lateral nuclear mass of the thalamus also project to particular parts of the striatum. Thus, cells in the rostromedial part of the ventral anterior nucleus project to the head of CD and some cells in the rostral part of the ventromedial nucleus project to the head of CD and to PU. Several cells scattered in the lateral posterior complex project to lateral parts of the head of CD, and cells in the rostral extension of the medial subdivision of the posterior nuclear complex project to lateral parts of the head and body of CD. Finally, several cells of the paratenial nucleus project selectively to Acc. These data provide a detailed map of the total thalamostriatal projection in the cat and, hence, form a basis for more specific functional questions about this poorly understood system.

GABA in the intralaminar thalamic nuclei modulates dopamine release from the two dopaminergic nigro-striatal pathways in the cat

Halothane-anaesthetized cats implanted with several push-pull cannulae were used to study the effects of the unilateral application of GABA (10(-5) M, 30 min) into thalamic intralaminar nuclei on the in vivo release of (3H)-dopamine [3H)-DA) newly synthesized from (3H)-tyrosine in both caudate nuclei (CN) and substantiae nigrae (SN). GABA applied into the left centralis lateralis nucleus (CL) elicited symmetric changes in the two CN, (3H)-DA release being initially reduced and thereafter markedly increased. On the contrary, an asymmetric pattern of responses was observed in the two CN during and after GABA application into the left centrum medianum parafascicular complex (CM/PF) since (3H)-DA release was decreased ipsilaterally and enhanced contralaterally. Changes in (3H)-DA release intervening in the two SN appeared to be triggered by processes independant from those operating in the CN. Hence, an immediate increase in (3H)-DA release with a time course distinct from that observed in other structures occurred in the contralateral SN after the application of GABA either into the left CL or the left CM/Pf. Furthermore in both cases, a biphasic response (decrease followed by an increase) similar to that intervening in the CN following GABA application into the CL was seen in the ipsilateral SN. Autoradiographic studies performed with (14C)-GABA (10(-5) M) revealed that the amino-acid did not spread out from the site of application. During and after GABA application (10(-5) M, 30 min) into the CL or the CM/Pf neuronal firing was markedly enhanced not only locally but also into respective contralateral homologous structures. These results further confirm the important and specific roles of distinct thalamic nuclei in the bilateral regulation of DA release from dendrites and nerve terminals of the nigro-striatal dopaminergic neurons.

Effects of unilateral electrical stimulation of various thalamic nuclei on the release of dopamine from dendrites and nerve terminals of neurons of the two nigrostriatal dopaminergic pathways

The role of several motor and intralaminar thalamic nuclei in the regulation of dopamine release from terminals and dendrites of the nigrostriatal dopaminergic neurons was investigated in halothane-anaesthetized cats. For this purpose, the effects of the unilateral electrical stimulation of various thalamic nuclei on the release of newly synthesized [3H]dopamine were simultaneously determined in both substantiae nigrae and caudate nuclei using the push-pull cannula method. The electrical stimulation of the motor nuclei was the only one to induce asymmetric changes in the four structures since [3H]dopamine release was enhanced in the ipsilateral caudate nucleus and reduced in the contralateral structure while opposite responses were observed in the corresponding substantiae nigrae. A reduction of [3H]dopamine release occurred in the four structures or only in the contralateral substantia nigra and caudate nucleus following the stimulation of the parafascicularis nucleus and the adjacent posterior part of the nucleus centrum medianum or of the nucleus centralis lateralis and the adjacent paralaminar part of the nucleus medialis dorsalis, respectively. The stimulation of the anterior part of the nucleus centrum medianum, which in contrast to other thalamic nuclei examined, receives few nigral inputs, selectively enhanced [3H]dopamine release in the contralateral substantia nigra. No significant changes in [3H]dopamine release were seen either in the substantiae nigrae or in the caudate nuclei following the stimulation of midline thalamic nuclei. These results indicate that the motor and intralaminar thalamic nuclei exert multiple and selective influences on the release of dopamine from terminals and/or dendrites of the dopaminergic neurons. They also further support a role of thalamic nuclei in the transfer of information from one substantia nigra to the contralateral dopaminergic neurons. The possible involvement of connections between paired thalamic nuclei was underlined by the observations of evoked potentials in contralateral homologous nuclei following unilateral stimulation of motor, or some intralaminar, nuclei. The present report provides new insights on the mechanisms contributing to the reciprocal and/or bilateral regulations of nigrostriatal dopaminergic pathways.

Single thalamic neurons which project to both the rostral cortex and caudate nucleus studied with the fluorescent double labeling method

After injections of fast blue into the rostral cortex and Evans blue into the caudate nucleus in cats, doubly labeled neurons were present in the ventral anterior, ventral lateral, rhomboid, and mediodorsal thalamic nuclei. Doubly labeled cells were also found in most members of the intralaminar group, including the central medial, paracentral, central lateral, and parafascicular nuclei. Although the centromedian nucleus contained large numbers of cells labeled with Evans blue which project to the caudate nucleus, and a few fast-blue labeled cells which projected to the cortex, doubly labeled neurons were absent from this posterior intralaminar nucleus in this study.

Double labelling of blanched neurons in the central nervous system of the rat by retrograde axonal transport of horseradish peroxidase and iron dextran complex

The retrograde axonal transport of an iron-dextran complex leads to a labelling of neural cell bodies in the central nervous system (CNS) of the rat. This tracer and horseradish peroxidase (HRP) can both be demonstrated histochemically in same cell bodies of intralaminar thalamic neurons in the central lateral nucleus, after injection of iron-dextran in the striatum and injection of HRP in the motor cortex. This is made possible by processing the sections first for HRP and then for ferric ions by Perl's reaction. This method allows an accurate demonstration of divergent axonal projections and is compatible with cytoarchitectonic studies on the same sections.

A new aspect of the collision test principle: cell body distance from recording site

A theoretical method is described for estimating the distance between a spike recording-site, possibly axonal, and the corresponding cell body of unknown location. The method requires that an orthodromic spike be recorded following an antidromic spike, with estimation of a collision interval analogous to that used for establishing antidromicity. To calculate the distance between recording-site and cell body, values are needed for the collision interval between antidromic and succeeding orthodromic spikes, the refractory period of the spike, and the antidromic conduction speed. Problems may arise in determining the last value. The method is illustrated with antidromic spikes recorded in the medial thalamus of the cat upon stimulating the caudate nucleus.

Retrograde axonal transport of 125I-tetanus toxin as a tool for tracing fiber connections in the central nervous system; connections of the rostral part of the rat neostriatum

After previous studies had shown that 125I-tetanus toxin is taken up with high efficiency by all (adrenergic, sensory and motor)peripheral nerve terminals and that it is transported retrogradely by intraaxonal transport to the corresponding cell bodies, the present experiments were designed to investigate whether 125I-tetanus toxin could be used as a tool for retrograde tracing of fiber connections in the central nervous system and how the results obtained compared with other available retrograde tracing methods. Three to 12 h after injection of 125I-tetanus toxin into the rostral part of the nucleus caudatus of the rat, heavily labeled nerve cells were found in the substantia nigra zona compacta, in Forel field H2 and parts of the zona incerta, and in specific thalamic intralaminar nuclei (nucleus medialis pars lateralis and nucleus parafascicularis). Moderately labeled neurons were observed in the nucleus ventralis thalami and its dorsomedial part, in the nucleus raphe dorsalis and in the frontal, cingular and occipital cortex. Besides the labeling by retrograde transport, orthograde transport of radioactivity occurred in a striatonigral system. The high sensitivity and reliability of this method, even after injection of very small amounts of protein in a very small volume, represent important advantages over most of the commonly used tracing methods.

Bilateral projections from precentral motor cortex to the putamen and other parts of the basal ganglia. An autoradiographic study in Macaca fascicularis

By tracing radioactively labeled proteins transported by axonal flow, projections from area 4 to the ipsi- and contralateral neostriatum and claustrum were demonstrated in 7 monkeys. A reversed topographic organization was found on both sides for the corticoneostriatal and corticoclaustral projections. The most extensive terminal field could be observed in the putamen. In contrast, very few area 4 efferents seemed to terminate in the caudate nucleus. This suggests differential functions for the two striatal components in sensorimotor mechanisms. These unexpected results give further evidence for the superior sensitivity of the autoradiographic technique, although the limitations of the new method in delineating the injection field were noted.