Subdivisions of the dopamine-containing A8-A9-A10 complex identified by their differential mesostriatal innervation of striosomes and extrastriosomal matrix

The mesostriatal projections from the dopamine-containing cells groups A8, A9 and A10 have been studied in the cat in relation to the histochemical compartments known to exist in the striatum. In order to do this, we made stereotaxic injections in the substantia nigra of either [3H]proline-[3H]leucine, [35S]methionine, wheat germ agglutinin-horseradish peroxidase, or the two last tracers combined, and compared the location of anterograde labeling in the striatum to the locations of striosomes and extrastriosomal matrix identified by their low or high content, respectively, of the enzyme acetylcholinesterase. A discrete innervation of dorsolateral striosomes by a caudal densocellular subdivision of the substantia nigra pars compacta was found. This densocellular zone of the pars compacta was readily identifiable in sections stained for tyrosine hydroxylase-like immunoreactivity and corresponded to the uniquely acetylcholinesterase-poor zone detected in the substantia nigra pars compacta in serially adjacent sections stained for this enzyme. Selective anterograde labeling of the extrastriosomal matrix occurred in cases with injection sites centered in cell group A8. Tracer deposits in cell group A10 also elicited a preferential labeling of the extrastriosomal matrix, but this innervation was sparse compared to the prominent labeling of fibers in the ventral striatum. An almost exclusive innervation of caudal and ventral striosomes of the head of the caudate nucleus occurred after a deposit of tracer in the pars lateralis of the substantia nigra. Mixed labeling of striosomes and matrix occurred with injection sites centered in the rostral, cell-sparse part of the pars compacta of the substantia nigra. Clusters of tyrosine hydroxylase-immunoreactive neurons within this zone, most likely representing finger-like extensions of the caudal densocellular zone of the pars compacta, might have accounted for part of the striosomal labeling in these cases. We conclude that different subdivisions of the A8-A9-A10 dopamine-containing cell complex of the cat's mesencephalon project preferentially to striosomes or to extrastriosomal matrix. On this basis we suggest that there may be different functional channels in the mesostriatal projection, including, from cell group A8, a channel providing dopaminergic modulation of sensorimotor processing in the striatal matrix, and, from the densocellular zone of the substantia nigra pars compacta, a channel leading to limbic-related mechanisms represented in the striosomal system.     

Compartmental origins of the striatopallidal projection in the primate.

The organization of striatopallidal projection neurons in the primate was studied by injecting horseradish peroxidase conjugated with wheat germ agglutinin and fluorescent markers (latex microspheres, Fluorogold, Diamidino Yellow or Nuclear Yellow) into the globus pallidus of 20 adult squirrel monkeys (Saimiri sciureus). Single injections of horseradish peroxidase conjugated with wheat germ agglutinin were placed so as to involve predominantly either one or both pallidal segments. In the double-tracer experiments, fluorescent tracer injections were centered in the external pallidum and deposits of horseradish peroxidase conjugated with wheat germ agglutinin were made in the internal pallidum. In control cases, injections were made in nearby parts of the internal capsule or striatum. Distributions of retrogradely labeled neurons in the striatum were analysed in relation to its striosomal architecture as demonstrated by histochemistry and immunohistochemistry. Three principal findings emerged. (1) Both the external and the internal segments of the primate pallidum receive input from both the caudate nucleus and the putamen, but different sets of striatal cells within these nuclei project to the two segments. (2) The striatopallidal projection in the primate originates mainly in the extrastriosomal matrix, although striosomes in the fields of labeling almost always contain some labeled neurons. (3) Heterogeneous groupings of striatopallidal projection neurons exist in the matrix and appear to be parts of three-dimensional projection-neuron arrays. We conclude that in the primate, separate lines of conduction lead from the striatum to the external and the internal pallidal segments, and raise the possibility that the cells of origin of these pathways form a mosaic in the extrastriosomal matrix.     

Three-dimensional organization of the striosomal compartment and patchy distribution of striatonigral projections in the matrix of the cat caudate nucleus

Acetylcholinesterase staining on successive frontal or sagittal sections was used to determine the three-dimensional organization of the striosomal and matrix compartments in the adult cat caudate nucleus. Reconstruction drawings of the acetylcholinesterase-poor zones (striosomes) indicated that the striosomal compartment is a labyrinthine network organized in the rostrocaudal and mediolateral axis which is reproducible from one animal to another. Four main anteroposterior channels converging in the mediorostral pole of the caudate nucleus were distinguished. Seven to eight diagonally oriented channels crossing the previous ones were seen also in the mediolateral axis on the central core of the caudate nucleus. The pattern of organization of the numerous and tortuous striosomal channels was more complicated medially, while the lateral part of the caudate nucleus was represented mainly by the matrix compartment. In addition, a sub-compartmentation of the matrix was demonstrated by retrograde tracing studies made by injecting either horseradish peroxidase-wheat germ agglutinin, [14C]amino acids or a mixture of horseradish peroxidase-wheat germ agglutinin and [14C]amino acids in several areas of the substantia nigra pars reticulata. Labelled patches were seen with both tracers, their topographical localization depended on the nigral injection site but reconstruction analysis indicated that the populations of cells which innervate the substantia nigra pars reticulata originate in the two third lateral parts of the caudate nucleus all along its rostrocaudal extension. Examination of horseradish peroxidase-wheat germ agglutinin labelled cells indicated that not all cells were labelled in patches suggesting a further sub-compartmentation of these patches. Finally, a comparison of the topographical distributions of labelled patches and of striosomes revealed that most patches were located in the extrastriosomal matrix.     

Heterogeneous distribution of the limbic system-associated membrane protein in the caudate nucleus and substantia nigra of the cat

The limbic system-associated membrane protein is a glycoprotein selectively associated, in the adult, with dendrites and cell bodies of neurons of the limbic system and related brain regions. In the present study, the distribution of the limbic system-associated membrane protein was studied by immunohistochemistry in the caudate nucleus and substantia nigra of the cat to determine how its expression relates to the compartmentalization of these areas. In all areas of the caudate nucleus, the pattern of limbic system-associated membrane protein immunoreactivity was highly heterogeneous, labeling zones that were in register with areas expressing neurochemical markers that classically identify striosomes. The extrastriosomal matrix exhibited low levels of staining. The results show that the limbic system-associated membrane protein is expressed by neurons within the target areas (striosomes) of subsets of limbic afferents (originating mainly from the basolateral nucleus of the amygdala and the prefrontal cortex), whereas regions of the caudate nucleus (extrastriosomal matrix) receiving inputs from other subdivisions of the limbic system, such as the cingulate cortex and the ventral tegmental area, contain relatively low levels of limbic system-associated membrane protein immunoreactivity. Thus the expression of this antigen may reflect the targeting of specific groups of limbic afferents to regions that are intimately associated with distinct components of the limbic system.

The presence of limbic system-associated membrane protein in neurons of the substantia nigra pars compacta does not appear to be related to the presence or absence of the protein in their striatal target areas. In the substantia nigra, immunoreactivity to the limbic system-associated membrane protein was intense in the cell-sparse zone of the pars compacta, an area known to project to the extrastriosomal matrix of the caudate nucleus. This contrasted with the absence of immunostaining in areas containing dense clusters of dopaminergic neurons (densocellular zone), which project to the limbic system-associated protein-rich striosomes. By analogy to findings in the caudate nucleus and in other brain areas, the results suggest that subgroups of nigral dopaminergic neurons identified on the basis of their terminal fields in the caudate nucleus, may also differ in their limbic afferents.     

Cellular substrate of the histochemically defined striosome/matrix system of the caudate nucleus: a combined Golgi and immunocytochemical study in cat and ferret

In order to learn what morphological substrate might underly the histochemical compartments of the neostriatum, sections of the caudate nucleus and the putamen of cats and ferrets were stained immunocytochemically with antisera directed against several neuropeptides and transmitter-related enzymes and were then Golgi-impregnated. Adjacent sections were stained to reveal acetylcholinesterase activity to identify the acetylcholinesterase-poor striosomes. The immunostaining produced by several of the antibody preparations was in register with the acetylcholinesterase-poor striosomes but the most prominent staining of these zones occurred with the antibodies directed against substance P. The striosomes were delineated by intense substance P-immunostaining of neuronal perikarya and dendrites, and in the rostral and dorsal caudate nucleus the boundary between substance P-immunostained and extrastriosomal matrix was abrupt. For these reasons we analysed Golgi-impregnated neurons in sections immunostained for substance P in order to assess the influence of the chemically defined striosomal architecture on the position and dendritic arborization of neurons located both within the striosomes and within the extrastriosomal matrix. The most commonly impregnated neurons were of the medium-size densely spiny class. Those that were present within the striosomes and lay within one dendritic radius of the boundary were divided into two types: (1) neurons whose dendritic arborization was apparently not influenced by the boundary and (2) neurons whose dendritic arborization was markedly influenced by the boundary. For neurons of the latter type, dendrites either emerged from the parts of the perikaryon away from the boundary, so avoiding crossing it, or they exhibited abrupt changes in their course, apparently to avoid crossing the boundary. Spiny neurons located in the extrastriosomal matrix but close to the striosomal boundary had dendrites that were either influenced by, or not influenced by the compartmental boundary. We conclude that there is a specific cytoarchitecture underlying the histochemical compartments of the neostriatum and that different sub-populations of medium-size spiny neurons underly (1) the segregation of information flow in striosomes and the extrastriosomal matrix and (2) communication between striosomes and the extrastriosomal matrix.     

Laminar organization of the substantia nigra pars reticulata in the cat

Using a semihorizontal section plane tangential to the ventral surface of the cerebral peduncle, the authors re-examined cyto-, myelo- and dendroarchitecture, acetylcholinesterase activity, afferent fibers, and efferent projection neurons of the substantia nigra pars reticulata. In the semihorizontal section plane, the substantia nigra pars reticulata was a disc-shaped nucleus and contained two to three myelinated fiber bundles running from anteromedial to posterolateral. Bands of high acetylcholinesterase activity existed parallel to the anteromedial-posterolateral direction. The Golgi silver impregnation study revealed that many nigral neurons extended their varicose dendrites anteromedially and posterolaterally. In cases with injections of wheat germ agglutinated horseradish peroxidase into the neostriatum or injections of tritiated leucine into the subthalamic nucleus, anterogradely labeled afferent fibers and axon terminals in the substantia nigra pars reticulata were organized into bands in the same anteromedial-posterolateral direction. In cases with injections of wheat germ agglutinated horseradish peroxidase into either the superior colliculus, the pedunculopontine tegmental nucleus or the ventromedial nucleus of the thalamus, retrogradely labeled neurons were also clustered along the anteromedial-posterolateral direction with their dendrites extending anteromedially and posterolaterally. The present findings strongly suggest that the substantia nigra pars reticulata has a laminar organization.     

Projections from the intracerebellar nuclei to the ventral midbrain tegmentum in the rat

The present study was undertaken to provide anatomical evidence, in the rat, for a direct projection from the cerebellum towards structures, other than the red nucleus, which belong to the ventral midbrain tegmentum, by using the retrograde as well as the anterograde horseradish peroxidase transport method. Following unilateral injection in the ventral midbrain tegmentum of horseradish peroxidase, free or conjugated to wheat germ agglutinin, sparing the red nucleus, retrogradely labeled neurons were found in the contralateral cerebellar lateral nucleus and, at lower density, in the interpositus nucleus. No labeled neurons were found in the fastigial nucleus of either side. Anterogradely labeled axons from lectin coupled horseradish peroxidase injection sites in the lateral and interpositus nuclei reached the contralateral ventral midbrain tegmentum. Terminal labeling was observed in the entire red nucleus as well as in the lateral division of the ventral tegmental area of Tsai, in the dorsal region of the substantia nigra pars compacta, and in the medial part of the retrorubral field. No terminal labeling was found in the caudal linear nucleus, interfascicular nucleus, peripeduncular nucleus, rostral linear nucleus of the raphe, substantia nigra pars lateralis and the substantia nigra pars reticulata. Terminal labeling was also not observed in the ventral midbrain tegmentum following horseradish peroxidase injection in lateral and interpositus nuclei of rats pretreated with kainic acid. In conclusion, it is noteworthy that, besides the red nucleus, the sole structures of ventral midbrain tegmentum receiving cerebellar efferents are those with a higher density of dopaminergic cells.     

Striatal neurons expressing somatostatin-like immunoreactivity: evidence for a peptidergic interneuronal system in the cat

Neurons expressing immunoreactivity to antisera against somatostatin 14 and other somatostatin-related peptides were identified in the striatum of cats and nonhuman primates. In each species, immunoreactive neurons were distributed singly and in small groups in the caudate nucleus, putamen and ventral striatum. A detailed study was made of somatostatin-positive neurons and neuropil in the caudate nucleus of the cat. First, the mean diameters and surface areas of neurons expressing immunoreactivity to somatostatin 14 were made from peroxidase-antiperoxidase stained material. Second, fluorescence immunohistochemistry was combined with retrograde labeling of striatal neurons to determine whether such somatostatin 14-positive neurons emit axons projecting out of the striatum. Third, the distributions of neurons and neuropil expressing immunoreactivity to somatostatin 14 or somatostatin 28 (1-12) were plotted in relation to the locations of acetylcholinesterase-poor zones ("striosomes") visible in adjoining sections. The morphometric analysis suggested that somatostatin 14-positive neurons in the caudate nucleus form a single population of medium to medium-large neurons having mean diameters of 20 micron and mean surface areas of 154 micron2. The retrograde tracer study suggested that these somatostatin 14-positive neurons are interneurons. Injections of fast blue into all of the known targets of striatofugal fiber projections failed to label somatostatin 14-positive neurons save in a few instances (less than 0.3% of more than 4000 neurons) in each of which labeling was equivocal. Analysis of the distribution of somatostatin-positive neurons and neuropil in the striatum demonstrated that both observe striosomal ordering. Somatostatin immunoreactive neuropil was dense outside and weak inside identified striosomes, and most immunoreactive neurons lay outside. Often somatostatin-positive neurons lay beside, and sometimes striosomes partly rimmed them. The processes of such neurons tended to run along the borders of the striosomes without crossing them, but occasionally single processes and rarely entire dendritic trees crossed from one compartment to the other. These results suggest that, in the striatum of the cat, somatostatin is present: (1) in fibers organized according to the compartmental distribution already recognized for other neurochemical compounds in the striatum as well as for its afferent and efferent systems, and (2) in interneurons, mostly present in the extrastriosomal matrix, but also located near striosomes, where they could serve as interfaces between the striosomes and extrastriosomal matrix.     

In situ hybridization histochemical and immunohistochemical evidence that striatal projection neurons co-containing substance P and enkephalin are overrepresented in the striosomal compartment of striatum in rats

In a prior study, we showed that the few striatal projection neurons that contain both substance P (SP) and enkephalin (ENK) in rats may preferentially project to the substantia nigra pars compacta. Since striatal neurons that project to the pars compacta are thought to preferentially reside in the striosomal compartment, we investigated if striatal neurons that contain both SP and ENK are preferentially localized to the patch compartment. We used in situ hybridization histochemistry to double-label sections for SP and ENK to identify SP/ENK co-containing neurons, and immunolabeling of adjacent sections for the mu opiate receptor (MOR) to define the striosomal compartment. We found that 32.3% of neurons containing both SP and ENK were localized to the striosomal compartment, which itself only made up 12.8% of the striatum. Our results further showed that the density of neurons co-containing SP and ENK was three-fold higher in striosomes than in the matrix compartment. These results are consistent with the notion that SP/ENK colocalizing neurons preferentially project to pars compacta, and these and our prior results additionally raise the possibility that neurons of this type in the striatal matrix may also project to the pars compacta.     

Collateral projection from the substantia nigra to the striatum and superior colliculus in the rat

Our retrograde fluorescent double labeling study demonstrated the existence of divergent collateral projections from the substantia nigra to the striatum and superior colliculus in the rat. These bifurcating projection neurons were located predominantly in the ventrolateral portions of the substantia nigra pars reticulata at its rostral level, where they formed a narrow band along the boundary between the substantia nigra and cerebral peduncle. Such specific projection cells were also seen in the substantia nigra pars lateralis. However, nigral neurons did not give off axonal branches to the striatum and ventromedial thalamic nucleus. The new nigral cell population proposed here might constitute a neuroanatomical substrate for abnormal saccadic eye movements clinically manifested by many parkinsonian patients.     

Intrapallidal lipopolysaccharide injection increases iron and ferritin levels in glia of the rat substantia nigra and induces locomotor deficits

Increasing evidence suggests that abnormal iron handling may be involved in the pathogenesis of Parkinson's disease. The present study investigates the role of iron and the iron-storage protein ferritin in inflammation-induced degeneration of dopaminergic neurons of the substantia nigra pars compacta. Injection of lipopolysaccharide into the globus pallidus of young and middle-aged rats substantially decreased tyrosine hydroxylase immunostaining in substantia nigra pars compacta four weeks after injection. Loss of tyrosine hydroxylase expression was accompanied by increased iron and ferritin levels in glial cells of the substantia nigra pars reticulata. Despite greater increases in nigral iron levels, ferritin induction was less pronounced in older rats, suggesting the regulation of ferritin was compromised with age. Automated movement tracking analyses showed that young rats recovered from LPS-induced locomotor deficits within four weeks, yet older rats failed to improve on measures of speed and total distance moved. Intrapallidal lipopolysaccharide injection also increased expression of alpha-synuclein and ubiquitin in tyrosine hydroxylase-positive neurons of the substantia nigra pars compacta. These results suggest that pallidal inflammation significantly increases stress on dopamine-containing neurons in the substantia nigra pars compacta. Alterations in nigral iron levels and protein handing may increase the vulnerability of nigral neurons to degenerative processes.     

Evidence that histochemically distinct zones of the primate substantia nigra pars compacta are related to patterned distributions of nigrostriatal projection neurons and striatonigral fibers

Summary A marked histochemical compartmentalization is visible in the substantia nigra of the squirrel monkey in sections stained for acetylcholinesterase (AChE). In nigral regions containing tyrosine hydroxylase-positive neurons, there are AChE-poor and AChE-rich zones, and many of the AChE-poor zones have the form of narrow fingers extending ventrally into an AChE-rich matrix (Jimenez-Castellanos and Graybiel 1987b). The study reported here was carried out to determine whether this histochemical heterogeneity of the primate's substantia nigra is related to the known differentiation within its pars compacta of subdivisions projecting respectively to the caudate nucleus and to the putamen. Retrograde and anterograde labeling in the substantia nigra was elicited by tracer injections placed in the caudate nucleus or putamen and was plotted in relation to patterns of AChE staining and tyrosine hydroxylase immunostaining. Much of the labeling observed was organized according to borders visible with AChE histochemistry: labeled nigral neurons (and afferent fibers) tended to be clustered precisely within the AChE-poor ventrally-extending fingers or to be situated outside these zones. However, projection neurons in these ventrally-extending fingers were not exclusively related either to the caudate nucleus or to the putamen. After injections in the caudate nucleus, labeled neurons were predominantly in the AChE-poor fingers in some cases, but predominantly in AChE-rich nigral zones outside them in other cases. Labeling in and out of the ventrally-extending fingers, and along the edges of the fingers, also occurred following different tracer injections in the putamen. These findings confirm the independent clustering of nigrostriatal neurons projecting respectively to the caudate nucleus and to the putamen. The plan of nigrostriatal connections additionally appears concordant with the histochemical compartmentalization of the substantia nigra that can be detected with acetylthiocholinesterase histochemistry.     

Three-dimensional distribution of nigrostriatal neurons in the rat: relation to the topography of striatonigral projections.

Functional regions of the rat striatum related to identified cortical territories were injected ionophoretically with wheat germ agglutinin coupled to horseradish peroxidase. Coronal serial sections were cut throughout the substantia nigra. The distributions of labelled striatal projections and nigrostriatal neurons were studied. Using software developed in our laboratory, three-dimensional reconstructions were calculated which confirmed and extended the organizational scheme of striatonigral projections already reported by our group. These projections were organized as a set of longitudinal lamellae spatially organized so as to segregate the flow of information emanating from striatal regions affiliated to sensorimotor and associative-limbic cortical areas. In addition, the relationship between the striatonigral projections and the nigrostriatal neurons was studied by three-dimensional reconstruction. For each striatal injection site, two populations of retrogradely labelled nigral neurons could be discriminated by their position with respect to the striatal projection field. The first one occupied a proximal position, in register with the labelled striatal projections, while the second was more distal. The populations of proximal neurons which innervate different functional striatal sectors were segregated both mediolaterally, dorsoventrally and rostrocaudally, while the populations of distal neurons were more scattered and showed a lesser degree of spatial segregation. The organization of these two populations with respect to the striatal projection fields suggests that the substantia nigra might control the flow of cortical information through the striatum via two different modalities, based respectively on a closed nigrostriatal loop involving the proximal neurons, and an open loop involving the distal ones.     

6-Hydroxydopamine lesions of the nigrostriatal pathway alter the expression of glutamate decarboxylase messenger RNA in rat globus pallidus projection neurons.

In situ hybridization was used to study the effect of 6-hydroxydopamine-induced damage to the midbrain dopaminergic neurons on the level of glutamate decarboxylase mRNA in globus pallidus neurons in the rat. Some animals received an injection of Fluoro-gold in the entopeduncular nucleus or the substantia nigra prior to the 6-hydroxydopamine lesion in order to identify glutamic acid decarboxylase mRNA levels in pallidal neurons that project to one of these targets. Analysis was carried out on a sample of all pallidal neurons as well as neurons that were identified as projection neurons in control and lesioned groups. The loss of the dopamine-containing neurons in the substantia nigra resulted in significant increases in the percentage of globus pallidus neurons that expressed glutamate decarboxylase mRNA and in the amount of glutamate decarboxylase mRNA per globus pallidus neuron. These increases were noted in a sample of all pallidal neurons, as well as pallidal neurons that were identified as projecting to either the entopeduncular nucleus or the substantia nigra. In control animals, glutamate decarboxylase mRNA was clearly identified in globus pallidus neurons projecting to the entopeduncular nucleus, indicating that this recently reported projection is at least partially GABAergic. The results of this study indicate that substantia nigra dopaminergic neurons regulate globus pallidus neurons in the rat, and that removal of the dopaminergic input to the corpus striatum results in a significant increase in the amount of glutamate decarboxylase mRNA in pallidal neurons. The decreased firing rate of pallidal neurons that is seen following the loss of dopamine input appears to be accompanied by an increase in the level of glutamate decarboxylase mRNA in these neurons.     

Differential connections of caudate nucleus and putamen in the squirrel monkey (Saimiri sciureus)

The organization of the subcortical connections of caudate nucleus and putamen in the squirrel monkey was studied using horseradish peroxidase conjugated to wheat germ agglutinin as anterograde and retrograde neuronal tracer. The tracer was injected in similar quantities in the putamen on the left side and in the caudate nucleus on the right side in 10 monkeys, and its presence was revealed by means of the tetramethylbenzidine method. The study of anterogradely labeled fibers visualized after such injections shows that putaminofugal fibers terminate massively in the ventral two-thirds of the globus pallidus, where they display a band-like arrangement, and much less abundantly in the caudal third of the substantia nigra. In contrast, caudatofugal fibers occupy only the dorsal third of globus pallidus but arborize profusely in the rostral two-thirds of substantia nigra. In the pars reticulata of the substantia nigra the caudatonigral fibers form a highly complex network composed of fiber trabeculae while the putaminonigral fibers occur as more discrete fascicles confined to the dorsolateral region of the structure. In the pars compacta of the substantia nigra the retrogradely labeled cells occur in the form of clusters that are closely intermingled with clusters of unlabeled neurons. The labeled-cell clusters are particularly dense on the putamen-injected side and more loosely organized on the caudate-injected side. On both sides, however, the striatonigral fibers that reach the substantia nigra pars compacta can be seen to terminate almost exclusively upon clusters composed of retrogradely labeled cells, suggesting the existence of a precise reciprocal link between nigral and striatal neuronal aggregates. At thalamic levels the retrogradely labeled cells are distributed according to a strikingly asymmetric pattern. For instance, a prominent labeling of neurons in the central superior lateral nucleus is seen only on the caudate-injected side. Furthermore, in the centromedian/parafascicular complex retrograde cell labeling is seen exclusively in parafascicular nucleus on the caudate-injected side and only in the centromedian nucleus, except its lateralmost portion, on the putamen-injected side. Control experiments involving injection of the tracer in cerebral cortex overlying the striatum reveal that the neurons in the lateral segment of the centromedian, which do not project to striatum, are in fact reciprocally connected with the cerebral cortex. In addition, our data show that some of the so-called "specific" thalamic nuclei contribute significantly to the thalamostriatal projection in monkey.(ABSTRACT TRUNCATED AT 400 WORDS)     

Synaptic organization of GABAergic inputs from the striatum and the globus pallidus onto neurons in the substantia nigra and retrorubral field which project to the medullary reticular formation.

Anatomical tract-tracing and immunohistochemical techniques involving correlated light and electron microscopy were used to determine whether the descending striatal and pallidal afferents to the substantia nigra pars reticulata converge onto individual neurons projecting to the pontomedullary and medullary reticular formation in the rat. Injections of biocytin into the ventrolateral region of the striatum and Phaseolus vulgaris-leucoagglutinin into the ventrolateral and caudal regions of the globus pallidus led to overlapping anterogradely labelled terminal fields within the dorsolateral substantia nigra pars reticulata. These terminal fields were punctuated by neurons which had been retrogradely labelled following injections of wheatgerm agglutinin conjugated to horseradish peroxidase into the lateral pontomedullary reticular formation. The anterogradely labelled striatal and pallidal terminals displayed different morphological characteristics; the striatal terminals were small and diffusely distributed throughout the neuropil without any particular neuronal association whereas the pallidal terminals were large and formed pericellular baskets around the perikarya of retrogradely and non-retrogradely labelled nigral neurons. In areas of the substantia nigra where there was an overlap between the two terminal fields, individual retrogradely labelled nigroreticular neurons were found to be apposed by both sets of anterogradely labelled terminals. Electron microscopic analysis revealed that the striatonigral and pallidonigral terminals displayed different ultrastructural features, the striatal terminals were small, contained few mitochondria and formed symmetric synaptic contacts predominantly with the distal dendrites of nigroreticular neurons whereas the pallidal terminals were large, contained numerous mitochondria and formed symmetric synaptic contacts preferentially with perikarya and proximal dendrites of nigroreticular neurons. Post-embedding immunohistochemical staining revealed that both striatonigral and pallidonigral terminals, some which formed synaptic contact with nigroreticular neurons, displayed GABA immunoreactivity. Examination of twelve retrogradely labelled neurons in the electron microscope revealed that all received synaptic inputs from both sets of anterogradely labelled terminals. In addition to the substantia nigra pars reticulata, neurons of the retrorubral field were also retrogradely labelled following injections of wheatgerm agglutinin conjugated to horseradish peroxidase into pontomedullary reticular formation. These retrorubroreticular neurons were part of a continuum of labelled cells which extended from the dorsolateral substantia nigra pars reticulata caudally into the retrorubral field. When combined with anterograde tracing methods it was found that the retrorubroreticular neurons received synaptic inputs from pallidal terminals which were morphologically similar to the pallidonigral terminals and formed symmetric synapses with the neuronal somata and proximal dendrites. In contrast to nigroreticular neurons, the stratonigral terminals were not seen in contact with retrorubroreticular cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Topographic projections from the basal ganglia to the nucleus tegmenti pedunculopontinus pars compacta of the cat with special reference to pallidal projections

Summary Projections from the basal ganglia to the nucleus tegmenti pedunculopontinus pars compacta (TPC) were studied by using anterograde and retrograde tracing techniques with horseradish peroxidase conjugated with wheat germ agglutinin (WGA-HRP) in the cat. Following WGA-HRP injections into the medial TPC area, a substantial number of retrogradely labeled cells were seen in the entopeduncular nucleus (EP) and medial half of the substantia nigra pars reticulata (SNr), whereas following WGA-HRP injections into the lateral TPC area, labeled cells were marked in the caudal half of the globus pallidus (GP) and lateral half of the SNr. To confirm the retrograde tracing study, WGA-HRP was injected into the EP or the caudal GP, and anterograde labeling was observed in the TPC areas. Terminal labeling was located in the medail TPC area in the EP injection case, while terminal labeling was observed in the lateral TPC area in the caudal GP injection case. Projections from the striatum to the pallidal complex (the EP and the caudal GP) were also studied autoradiographically by injecting amino acids into various parts of the caudate nucleus and the putamen. Terminal labeling was distributed over the whole extent of the EP and the rostral GP following injections into the rostral striatum (the head of the caudate nucleus or the rostral part of the putamen), while terminal labeling was distributed over the caudal GP following injections into the caudal striatum (the body of the caudate nucleus or the caudal part of the putamen). From these findings, we conclude that there exists a medio-lateral topography in the projection from the basal ganglia to the TPC: The EP receives afferent projections from the rostral striatum and projects to the medial TPC area, whereas the caudal GP receives projections from the caudal striatum and sends fibers to the lateral TPC area.Abbreviations BC brachium conjunctivum - CD caudate nucleus - CP cerebral peduncle - DBC decussation of the brachium conjunctivum - EP entopeduncular nucleus - GP globus pallidus - IC internal capsule - ICo inferior colliculus - LH lateral habenular nucleus - ML medial lemniscus - PN pontine nuclei - PUT putamen - SCo superior colliculus - SI substantia innominata - SN substantia nigra - SNc substantia nigra pars compacta - SNr substantia nigra pars reticulata - STN subthalamic nucleus - TH thalamus - TPC nucleus tegmenti pedunculopontinus pars compacta     

The striatonigral projection and nigrotectal neurons in the rat. A correlated light and electron microscopic study demonstrating a monosynaptic striatal input to identified nigrotectal neurons using a combined degeneration and horseradish peroxidase procedure

In a light and electron microscopic study of the substantia nigra of the rat, the distribution and morphology of nigrotectal neurons and the pattern of termination of striatonigral fibres have been examined following the placement of horseradish peroxidase injections in the superior colliculus and kainic acid lesions in the dorsal striatum. In confirmation of previous findings, nigrotectal neurons which had been identified by the retrograde transport of horseradish peroxidase from the superior colliculus had mainly medium sized somata, varied from fusiform to stellate in shape and were found in mainly ventral regions of the rostral two-thirds of the substantia nigra pars reticulata. On electron microscopic examination, single and multiple (from two to six) degenerating striatonigral boutons were found in synaptic contact with the soma, proximal mainstem dendrites and small dendrites (but mainly on small dendrites) of labelled nigrotectal and unlabelled nigral neurons in the ventral region of the pars reticulata. In addition, a small number of degenerating striatonigral boutons formed axoaxonic synapses with degenerating or normal boutons which were presynaptic to nigral dendrites. Almost all of the identified striatonigral synapses were of the symmetrical type, although a few degenerating boutons established asymmetrical synaptic contacts on unlabelled dendrites. These findings provide evidence of a monosynaptic input from the dorsal striatum to nigrotectal projection neurons in the substantia nigra and thus demonstrate the existence of a bineuronal pathway from the striatum through the substantia nigra to the superior colliculus. The possible significance of the pattern of termination of striatonigral fibres in the substantia nigra is discussed with reference to the known dendritic arborization of nigral neurons.     

Co-expression of neuropeptides in the cat's striatum: an immunohistochemical study of substance P, dynorphin B and enkephalin.

The expression of tachykinin-like and opioid-like peptides was studied in medium-sized neurons of the caudate nucleus in tissue from adult cats pretreated with colchicine. Two methods, a serial thin-section peroxidase-antiperoxidase technique and a two-fluorochrome single-section technique, were applied. Quantitative estimates were made mainly with the peroxidase-antiperoxidase method. The numbers of neurons expressing substance P-like, dynorphin B-like, and enkephalin-like immunoreactivity were recorded in regions identified, respectively, as striosomes and extrastriosomal matrix. Striosomes were defined by the presence of clustered substance P-positive and dynorphin B-positive neurons and neuropil. Tests for the co-existence of enkephalin-like peptide and glutamate decarboxylase-like immunoreactivity were also made with the peroxidase-antiperoxidase method. Co-expression of substance P-like and dynorphin B-like immunoreactivities was the rule both in striosomes and in the matrix. In striosomes, substance P-like immunoreactivity was found in 96% of dynorphin B-immunoreactive neurons, and in the matrix 89% of dynorphin B-positive cells contained substance P-like immunoreactivity. Substance P/dynorphin B-positive neurons corresponded to over half (57%) of the neurons in striosomes but only 39% of the neurons in the matrix. Both in the matrix and in striosomes, about two-thirds of all neurons (63% and 65%, respectively) were identified as enkephalin-positive. Among all substance P/dynorphin B-positive medium-sized neurons, 76% also contained enkephalin-like antigen. The enkephalin-positive neurons characterized by triple peptide co-existence (enkephalin/substance P/dynorphin B) represented a mean of 63% of striosomal enkephalin-positive neurons (41% of all striosomal neurons) and 35% of matrical enkephalin-positive neurons (26% of all matrical neurons). Finally, nearly all enkephalin-positive neurons were immunoreactive for glutamate decarboxylase, and therefore probably GABAergic, but only about half the glutamate decarboxylase-positive population was enkephalin-immunoreactive. These findings suggest that neuropeptides from three distinct precursors may be co-localized in single medium-sized neurons in the striatum, and that the differential patterns of co-expression of substance P-like, dynorphin B-like, and enkephalin-like peptides may confer functional specializations upon subpopulations of GABAergic neurons giving rise to the efferent projections of the striatum. The linked expression of substance P-like and dynorphin B-like peptides in single neurons both in striosomes and matrix suggests that some regulatory mechanisms controlling peptide expression apply regardless of compartment.(ABSTRACT TRUNCATED AT 400 WORDS)     

Topographic distribution of the axonal endings from the sensorimotor and associative striatum in the macaque pallidum and substantia nigra

The striatopallidonigral connection was studied by injecting anterograde tracers into either the associative or the sensorimotor striatum in ten macaques. The results were analyzed using a precise cartographic method. Injections into various parts of the associative striatum (caudate nucleus and ventromedial putamen) produced a labeling of axons in the dorsomedial and ventral pallidal regions. These associative regions occupied two-thirds of the lateral pallidum and one-third of the medial pallidum. Bands of labeled axons from the sensorimotor striatum (dorsolateral putamen) were found in the remaining, central part of the two pallidal nuclei. In the substantia nigra, the rostral associative striatum projected medially to the pars reticulata, while the caudal parts projected laterally. The whole pars reticulata and lateralis thus appeared to receive associative striatal inputs. The sensorimotor striatal territory projected to the central part of the pars reticulata/lateralis. It was concluded that the two functional territories remain separate in the two pallidal nuclei but overlap in the middle third of the substantia nigra. However, due to their great size, the pallidal neurons located at the border of the two territories may receive striatal inputs from both the associative and the sensorimotor components in the same way that nigral neurons do.