N-methyl-D-aspartate acutely increases proenkephalin mRNA in the rat striatum

Studies in which glutamate (GLU) neurotransmission has been reduced at striatal synapses have shown that GLU influences the biosynthesis of certain peptide cotransmitters by striatal neurons. The present experiment was designed to test the effects of direct activation of the NMDA or AMPA types of GLU receptor on the levels of two mRNAs that encode the peptide cotransmitters met5-enkephalin (ME) and substance P (SP). In situ hybridization histochemistry of forebrain tissue sections from rats 8 h after a single intracerebroventricular infusion of NMDA or AMPA revealed a significant and dose-dependent elevation (to a maximum of almost 50%) of striatal ME mRNA when compared to vehicle-injected controls. SP mRNA was not significantly affected. NMDA was more effective than AMPA over the dose range used. Pretreatment with a potent and highly specific AMPA antagonist (NBQX) predictably blocked the AMPA-mediated elevation, and was only slightly effective against the NMDA-induced response. In striking contrast, pretreatment with a potent and highly selective NMDA antagonist (CGP37849) fully opposed both the NMDA- and the AMPA-mediated elevation of ME mRNA. These data further implicate the NMDA receptor in the regulation of peptide cotransmitter gene transcription. They suggest also that the AMPA receptor may play an indirect, synergistic role in the genetic responses of striatal neurons to GLU transmission.

N-methyl-D-aspartate receptor antagonism alters substance P and met5-enkephalin biosynthesis in neurons of the rat striatum

A reduction of striatal excitatory amino acids or of corticostriatal axons alters substance P (SP) and met5-enkephalin (ME) biosynthesis in striatal neurons of the rat. To determine the role of the N-methyl-D-aspartate (NMDA) receptor in this effect, adult rats were treated acutely with a single i.c.v. injection or chronically by 7 days of continuous infusion of an NMDA antagonist. The striatal content of preprotachykinin (PPT) and preproenkephalin (PPE) mRNA was assessed by in situ hybridization histochemistry while the content of SP and ME in, respectively, the substantia nigra and globus pallidus was measured by quantitative radioimmunocytochemistry. Eight hours after a single injection, striatal PPT and PPE mRNA levels were significantly reduced. At 24 hr, the level of PPE had returned to control level whereas that of PPT mRNA remained depressed. Nigral SP and pallidal ME levels were not acutely changed. Chronically, the effect of NMDA antagonist at low doses was to increase the striatal content of PPE mRNA. However, at higher concentrations, the effect was to reduce in a dose-dependent manner the striatal content of PPT and PPE mRNA and the level of pallidal ME. The nigral level of SP did not change significantly at any dose. The results suggest that excitatory amino acid transmission mediated by the NMDA receptor serves as a tonic signal to stimulate neuroactive peptide biosynthesis.

Cortical stimulation induces fos expression in striatal neurons

Electrical stimulation of a broad area of the frontoparietal cortex in the rat brain induces immunocytochemically detectable Fos in striatal neurons normally devoid of the protein. The vividness of labeling within striatal neurons was maximal at 0.5 h after the cessation of a 15-min-long stimulation period and became weaker by 3 h. Although Fos-reactive neurons were widely distributed in the striata of both hemispheres in an uneven pattern, those on the stimulated side were more numerous and more darkly stained. At no time-point were labeled neurons found in the globus pallidus, entopeduncular nucleus or substantia nigra. Destruction of the nigrostriatal dopamine projection with 6-hydroxydopamine did not induce Fos production and failed to prevent the induction of Fos by cortical stimulation. That many of the Fos-positive neurons project to the substantia nigra was confirmed by retrograde labeling with Fluoro-Gold. The data suggest that corticostriatal excitatory transmission may directly influence the genomic activity of striatal neurons by way of Fos.

Chronic methionine sulfoximine administration reduces synaptosomal aspartate and glutamate in rat striatum

Methionine sulfoxime (MS) is an inhibitor of glutamine synthetase, an astroglial enzyme believed to be involved in the maintenance of glutamine, a major precursor for neurotransmitter pools of the excitatory amino acids aspartate and glutamate in striatal afferent axon terminals. MS was infused for 7 days (24 micrograms/day) into the lateral cerebral ventricle of rats. On the side of MS infusion, there was a decrease of striatal synaptosomal aspartate (61%), glutamine (63%), and glutamate (48%), while taurine and gamma-aminobutyrate were unaltered when compared to vehicle-treated rats. The results indicate that chronic MS infusion is an effective means by which neurotransmitter aspartate and glutamate levels can be selectively reduced in the striatum.

Striatal preprotachykinin and preproenkephalin mRNA levels and the levels of nigral substance P and pallidal Met5-enkephalin depend on corticostriatal axons that use the excitatory amino acid neurotransmitters aspartate and glutamate: quantitative radioimmunocytochemical and in situ hybridization evidence

Because excitatory amino acid (EAA) neurotransmission has been implicated in long-term postsynaptic events, we conducted an initial study to determine whether or not the EAA-utilizing corticostriatal projection might influence peptide biosynthesis in neurons of the rat's basal ganglia. The content of EAAs in the caudatoputamen was reduced by frontal cortical ablation or by chronic intracerebroventricular infusion of methionine sulfoximine (MS). At 7 days following cortical ablation striatal Asp and Glu were reduced by 15% and 24%, respectively, while MS infusion (24 micrograms/day) for 7 days reduced synaptosomal levels of Asp by 61% and Glu by 48%. With either treatment, quantitative radioimmunocytochemistry revealed that substance P (SP) in the substantia nigra was increased by approximately 38%, while Met5-enkephalin (ME) in the globus pallidus was not changed. In situ hybridization with oligonucleotide probes revealed changes in the rostral striatum of preprotachykinin (PPT) and preproenkephalin (PPE) mRNA levels: cortical ablation reduced PPT mRNA by 17% and PPE mRNA by 20% dorsally, while it increased PPE mRNA (but not PPT mRNA) by 23% ventrally. Likewise, the infusion of MS decreased PPT (32%) and PPE mRNA (28%) dorsally, and increased PPE mRNA (50%) ventrally. In addition to the 7 day time point, the same measurements of EAAs, peptides and mRNAs were made at 14, 21 and 28 days after cortical excisions. At 14 days, the level of striatal Asp had returned to control value, but Glu remained depressed by 21%; nigral SP remained increased by 24%, and pallidal ME decreased by 15%. PPT and PPE mRNA remained depressed dorsally by 15% and 25%, respectively, while the increase in PPE mRNA noted ventrally at 7 days had returned to control values by 14 days. With the exception of Glu, which remained depressed by 18% at 21 and 28 days, all other values had returned to control levels by 21 days. The results indicate that a large reduction in EAA neurotransmission can influence differentially the steady-state levels of neuropeptides in striatal neurons and this change is brought about, at least in part, by an alteration in gene transcription.

Thalamocortical connections of the rostral intralaminar nuclei: an autoradiographic analysis in the cat

In this study the pattern of projections from the rostral intralaminar thalamic nuclei to the cerebral cortex was examined in the cat by autoradiography. Injections of tritiated proline and leucine were placed into the central lateral, paracentral, central medial, and para-stria medullaris nuclei. After injections into the central lateral nucleus, label is present on the lateral side within the presylvian sulcus, in most of the suprasylvian gyrus, including the adjacent lateral and suprasylvian sulci, and in the posterior corner of the ectosylvian gyrus. On the medial side, label is present in the orbitofrontal (Of), precentral agranular (Prag), anterior limbic (La), retrosplenial (Rs), and postsubicular (Ps) areas, as defined by Rose and Woolsey ('48a). The cingulate gyrus also contains label throughout (part of which was defined as the "cingular area," Cg, by Rose and Woolsey, '48a). Label is also found on both banks of the splenial and cruciate sulci. In addition, label is present within the lateral gyrus, on both its lateral and medial sides. The paracentral projections are similar to the central lateral input. On the lateral side, label is found within the presylvian sulcus, suprasylvian gyrus and adjacent lateral and suprasylvian sulci, and posterior ectosylvian gyrus. Medially, label is present in the Of, Prag, La, Cg, Rs, and Ps areas, and within the cruciate and splenial sulci, and in portions of the lateral gyrus. Following injections of the central medial nucleus, label is present in the presylvian sulcus; but in contrast to the central lateral and paracentral projections, the suprasylvian gyrus is labeled only in its posterior part. The central medial nucleus also projects to the posterior lateral gyrus, both laterally and medially. Also, the central medial nucleus projects heavily to rostral cortical zones, which include the Of, Prag and La areas, cruciate sulcus, and the rostral cingulate gyrus. The para-stria medullaris nucleus projects only to the presylvian sulcus and orbitofrontal cortex laterally, but, medially, has an extensive input similar to the central lateral and paracentral projections in that label is present in the Of, Prag, La, Cg, Rs, and Ps areas, in the cruciate and splenial sulci, and in the posterior lateral gyrus. The laminar distribution of label is as follows: the central lateral, paracentral and para-stria medullaris nuclei project primarily to layers I and III, whereas the central medial nucleus projects to layers I and VI. In addition, the central lateral projection has a patchy appearance in the retrosplenial and postsubicular cortices.

Distribution of corticotectal axons from the caudal part of the anterior ectosylvian sulcus in the cat

Axonal projections from cells in cortex surrounding the caudal part of the anterior ectosylvian sulcus (AES) to the superior colliculus (SC) were examined using anterograde tracers. The projection terminates in the medial two-thirds of the deep layers of SC bilaterally, and appears to be topographically organized, perhaps according to the sensory modality (auditory and visual) represented in the caudal part of AES.

Nigrostriatal dopamine neurons are required to maintain basal levels of substance P in the rat substantia nigra

Striatal dopamine was depleted in adult rats by unilateral infusion of 6-hydroxydopamine near the dopamine neurons of the pars compacta of the substantia nigra. Following survival periods of 1, 3, 4, 6 or 12 weeks, changes in levels of the tachykinin neuropeptide, substance P, in striatonigral axon terminals were assessed by quantitative radioimmunocytochemistry. Substance P levels in the ipsilateral substantia nigra were consistently lower than levels on the control (non-lesion) side at every time point examined, reaching a maximum decline of about 30% at 3 weeks after the lesion. These data show that there is no recovery of nigral substance P content to basal levels up to 3 months post-lesion, and suggest strongly that intact striatal dopamine innervation is required for the maintenance of basal substance P levels in the terminals of striatonigral substance P neurons.

Association of dopamine D1 and D2 receptors with specific cellular elements in the basal ganglia of the cat: the uneven topography of dopamine receptors in the striatum is determined by intrinsic striatal cells, not nigrostriatal axons

To ascertain the cellular associations of the D1 and D2 dopamine receptor subtypes in components of the basal ganglia, cats were prepared with unilateral, axon-sparing, ibotenic acid lesions of the striatum (n = 6) or lesions of the nigrostriatal dopamine system by intranigral infusion of 6-hydroxydopamine (n = 8). After 42 days survival, tissue sections from the brains were processed for quantitative, in vitro receptor autoradiography with [3H]SCH23390 (D1 radioligand) or [3H]spiroperidol (D2 radioligand). Lesion-induced changes in basal ganglia nuclei were assessed by comparing them to the corresponding nuclei on the intact side and in naive brains. Ibotenate lesions cause a decline in specific D1 and D2 receptor-binding in the area of the striatal lesion of 94% and 85%, respectively, and completely eliminate the uneven patterns of high- and low-density binding that are characteristic of the cat's caudate nucleus. The globus pallidus, entopeduncular nucleus and pars reticulata of the substantia nigra also show marked reductions in binding after striatal ibotenate lesions. Thus, after caudate nucleus lesions, D2 binding in the two pallidal segments declines by approximately 50%, but remains unchanged in the substantia nigra. Binding of the D1 radioligand (which is not measurable in the globus pallidus) declines by about 75% in the affected regions of the entopeduncular nucleus and pars reticulata, and by about 30% in the pars compacta. Lesions of the nigral dopamine neurons reduce D2 receptor-binding by 95% in the pars compacta and 40% in the pars reticulata, but have no effect on the concentration of D1 or D2 radioligand-binding in the striatum or pallidum. Moreover, such lesions failed to alter the uneven patterns of binding in the striatum. These data suggest that most, if not all, D1 receptors in the basal ganglia are associated with cells of the striatum and their axons in the entopeduncular nucleus and substantia nigra, and likewise, a large majority of D2 receptors are associated with striatal cells and their axons in pallidal structures. Nearly all D2 receptors in the substantia nigra are associated with dopamine neurons (autoreceptors). Finally, the heterogeneous patterns of D1 and D2 receptors in the striatum are a consequence of intrinsic neuronal distributions.

Quantitative radioimmunocytochemical evidence that haloperidol and SCH 23390 induce opposite changes in substance P levels of rat substantia nigra

Chronic blockade of the dopamine (DA) D2 receptor by repeated systemic administration of the butyrophenone neuroleptic, haloperidol (HAL), is known to lead to a decrease in levels of the neuroactive peptide, substance P (SP), in the rat striatum and substantia nigra (SN). Using a high-resolution, quantitative radioimmunocytochemistry (RIC) technique, we have shown the HAL-induced decrease in rat nigral SP to be both dose- and time-dependent. In addition, chronic administration of the highly selective D2 antagonist, S(-)-sulpiride, also decreased nigral SP. Following blockade of the dopamine D1 receptor by chronic administration of the selective D1 antagonist, SCH 23390, we found, in contrast, that levels of SP in SN were increased in a dose- and time-dependent fashion. The magnitude of the maximum SCH 23390-induced elevation (20-30%) of nigral SP was approximately equal to that of the maximum HAL-induced decrease. The opposite response of nigral SP levels to repeated injections of a D1 or D2 antagonist suggests that the two DA receptor subtypes exert tonic, opposing, modulatory influences on the SP content of the striatonigral pathway.

Distribution of D1 and D2 dopamine receptors in the basal ganglia of the cat determined by quantitative autoradiography

The patterns of dopamine D1 and D2 receptors were examined in the corpus striatum and related structures in the cat brain by quantitative autoradiography after in vitro radioligand binding with [3H]SCH23390 (D1 antagonist) and [3H]spiperone (D2 antagonist). Highly specific binding for both radioligands occurs in striatal structures known to receive dopaminergic input: the caudate nucleus, putamen, nucleus accumbens, and olfactory tubercle. However, the density of binding varies from one structure to another, and the density distribution within striatal nuclei is heterogeneous. In all but one portion of the striatum, the concentration of bound D1 radioligand ranges from 46 to 230% more than that of the D2 radioligand. The exception to this difference occurs at caudal putamenal levels where the two radioligands bind in equal concentrations (approximately equal to 220 fmol/mg tissue wet-weight). The highest density of both D1 and D2 radioligand binding occurs in irregular zones in the head and body of the caudate nucleus. Such high-density zones of D2 radioligand binding appear mainly in the dorsolateral part of the caudate's head. For the D1 radioligand, the high-density zones are more widespread throughout the caudate nucleus, nucleus accumbens, and putamen. The D2 radioligand binding (but not the D1) also exhibits low-density zones at more caudal levels of the caudate nucleus, and these are often in register with the high-density zones of D1 radioligand binding. In the putamen, inverted concentration gradients exist for the two radioligands: the [3H]SCH23390 gradient runs from higher levels rostrally to lower levels caudally. The lowest levels of bound [3H]spiperone in the striatum occur in the nucleus accumbens-olfactory tubercle area, whereas the lowest binding of [3H]SCH23390 occurs in the caudal putamen. Pallidal and nigral structures show marked disparities in binding of the two different radioligands. The D2 radioligand binding in the globus pallidus (80 +/- 8 fmol/mg tissue wet-weight) is about twice that in the entopedunuclear nucleus and pars reticulata of the substantia nigra, the latter two having equal levels (35 +/- 3 fmol/mg). No specific binding of the D2 radioligand occurs in the ventral pallidum. In contrast, D1 radioligand binding is highest in the entopeduncular nucleus (217 +/- 6 fmol/mg) and in the pars reticulata of the substantia nigra (198 +/- 2 fmol/mg) and moderate in the ventral pallidum (135 +/- 15 fmol/mg). In the globus pallidus, no detectable D1 radioligand binding occurs.(ABSTRACT TRUNCATED AT 400 WORDS)

Striatal substance P cell clusters coincide with the high density terminal zones of the discontinuous nigrostriatal dopaminergic projection system in the cat: a study by combined immunohistochemistry and autoradiographic axon-tracing

A portion of the nigrostriatal projection that originates from presumably dopaminergic neurons in the caudal pars compacta of the substantia nigra and the suprajacent pars dorsalis (retrorubral area), was shown by [3H]amino acid autoradiographic tracing to distribute nonhomogeneously in the head of the caudate nucleus, such that zones of high density termination are in register with the archipelago of substance P cell clusters revealed immunohistochemically in the same and adjacent tissue sections of the cat's brain. Axons from this same portion of the substantia nigra distribute densely at caudal levels of the putamen where again substance P-immunoreactive striatal cells are numerous. In nearby tissue sections from the same cases, tyrosine hydroxylase-like immunoreactivity suggested only subtle variations in the density of the catecholamine axon network within the striatum. Thus, whereas dopamine axons are distributed densely throughout the striatum, those originating from cells in the caudal pars compacta et dorsalis of the substantia nigra and ending in the head of the caudate nucleus appear to terminate preferentially within the substance P cell clusters. These data suggest that the striatal substance P cells, which send their axons selectively to the entopeduncular nucleus and substantia nigra, but much less so the globus pallidus, are a major target of nigrostriatal dopamine transmission. This result is discussed with respect to the anatomical, neurochemical and functional organization of the striatifugal projection system.

Striatal axons to the globus pallidus, entopeduncular nucleus and substantia nigra come mainly from separate cell populations in cat

The extent to which individual striatal neurons send collaterals to the globus pallidus, entopeduncular nucleus and substantia nigra in the cat brain was determined by double-retrograde tracing with rhodamine fluorescent latex microspheres in combination with either horseradish peroxidase or the fluorescent nuclear dye Diamidino Yellow. In each case, two of the three target nuclei were injected, each with a different tracer, until all three possible combinations of two had been obtained several times. In all cases in which the tracer encroaches upon a striatal target, there are cells labeled in the striatum of a size and shape that is consistent with the observation that they mainly belong to the category of medium striatal cells. Since the striatal projections to the globus pallidus, entopeduncular nucleus and substantia nigra are each topographically organized, the zones of cell-labeling within the striatum vary depending upon the portion of the target nucleus involved by the deposit. Thus, in many cases the fields of striatal cells containing one label overlap only slightly with those in which cells containing the other label occur. In other cases, however, there is extensive overlap of the striatal zones containing cells marked with either tracer. In all cases, very few double-labeled cells can be found, even where hundreds of cells labeled with either tracer are freshly intermingled. Doubly labeled cells occur somewhat more frequently in those cases where the tracers are placed in the entopeduncular nucleus and substantia nigra than in those with the other two combinations, suggesting that striatal axons branch more often to the entopeduncular nucleus and substantia nigra than to the globus pallidus and nigra or globus pallidus and entopeduncular nucleus. These findings confirm, that, in the cat as in the primate, the striatal axons to the substantia nigra arise from cells that are largely separate from the striatopallidal population, and further show that the axons to the globus pallidus and entopeduncular nucleus also emanate mainly from different cells.

Complementary mosaic distributions of thalamic and nigral axons in the caudate nucleus of the cat: double anterograde labeling combining autoradiography and wheat germ-HRP histochemistry

The discontinuous terminal distributions of thalamo- and nigrostriatal axons were examined in adjacent tissue sections from single cat brains by combined anterograde labeling with tritiated proline autoradiography and wheat germ-horseradish peroxidase histochemistry. Injection of one tracer into the centromedian-parafascicular complex of the thalamus and the other into the substantia nigra reveals that, to a large extent, the patches of high density terminations within the caudate nucleus from these two structures interdigitate with each other in a complementary pattern.

Immunohistochemical demonstration of differential substance P-, met-enkephalin-, and glutamic-acid-decarboxylase-containing cell body and axon distributions in the corpus striatum of the cat

The immunohistochemical localization of neuronal cell bodies and axons reactive for substance P (SP) and methionine-enkephalin (ME) was investigated in the corpus striatum of the adult cat brain and compared with that of glutamate decarboxylase (GAD), synthetic enzyme for gamma-aminobutyric acid. Striatal cell bodies reactive for ME could be identified only in colchicine treated cats, are medium size, ovoid striatal cells, and are found in large numbers in a more or less even distribution throughout the caudate nucleus, putamen, and nucleus accumbens. The striatal region most densely occupied by ME-immunoreactive cells is the ventral and central part of the caudate head. Modest numbers of larger ME-reactive neurons are dispersed throughout the entopeduncular nucleus and the pars reticulata of the substantia nigra. Striatal cells of medium size reactive for SP could be identified, with or without colchicine, in largest numbers in the medial half of the caudal three-fourths of the putamen and in clusters of irregular size and shape in the head of the caudate nucleus. Cells reactive for SP are also common in layer II and the islands of Calleja of the olfactory tubercle. We could not reliably visualize GAD-positive cell bodies in the striatum, even with colchicine treatment; however, they could be seen readily in all pallidal structures such as the globus pallidus, ventral pallidum, entopeduncular nucleus, and substantia nigra. Axons reactive for ME are found mainly in the globus pallidus where they form a dense and even network throughout the nucleus. The globus pallidus is almost devoid of SP reactivity except near its extreme caudal pole. Conversely, SP-immunoreactive axons form dense meshworks in the entopeduncular nucleus and substantia nigra where ME immunoreactivity is minimal. Fewer, but still ample numbers, of SP-reactive axons are present also in the ventral tegmental and retrorubral areas of the midbrain tegmentum and in the ventral pallidum of the basal forebrain, but only sparse ME-reactive axons are present in these areas. This differential distribution of SP- and ME-containing axons in the pallidal and nigral structures stands in contrast to the relatively homogeneous and dense distribution of GAD-containing axons throughout the dorsal and ventral pallidum, entopeduncular nucleus, and substantia nigra.(ABSTRACT TRUNCATED AT 400 WORDS)

A projection to the striatum from the medial subdivision of the posterior group of the thalamus in the cat

Injections of wheat germ agglutinin-conjugated horseradish peroxidase in the lateral part of the caudate nucleus or the putamen of the cat result in retrograde thalamic cell-labeling in the rostral extension of the medial subdivision of the posterior group (POM). Autoradiography after [3H]amino acid injection of POM reveals a dense and discontinuous distribution of axons in the lateral half of the caudate and putamen concentrated at their middle rostrocaudal levels. This newly discovered thalamostriatal projection of POM may account for somatosensory activity observed in striatal cells.

The lateral suprasylvian corticotectal projection in cats

The projection from the lateral suprasylvian visual areas to the superior colliculus was investigated in cats using both anterograde and retrograde tracing techniques. The retrograde transport of horseradish peroxidase (HRP) or wheat germ agglutinin-HRP (WGA-HRP) from their site of deposit in the superior colliculus indicates that all divisions of the lateral suprasylvian visual areas project to both the superficial and deep layers of the superior colliculus. However, following tracer deposits in the superior colliculus that are confined to the layers below the stratum opticum (deep layers), more neurons are labeled along the lateral bank than along the medial bank of the middle suprasylvian sulcus. Conversely, tracer deposits in the superior colliculus dorsal to and including the stratum opticum label more cells in the medial than the lateral bank. These retrograde experiments also confirm that the visual cortex along the lateral gyrus (areas 17 and 18) projects to the superficial, but apparently not to the deep layers. The visual area in the cortex surrounding the caudal two-thirds of the anterior ectosylvian sulcus projects to the deep, but not to the superficial layers. The laminar and areal patterns of anterograde axon labeling in the superior colliculus were examined after single deposits of 3H-amino acids (autoradiography), HRP, or WGA-HRP in the lateral suprasylvian cortical regions, or combined isotope and WGA-HRP deposits. Axon labeling in the superior colliculus is generally densest in the stratum opticum and extends either dorsally into the superficial layers or ventrally into the intermediate gray layer. Specifically, the anterior divisions of the lateral suprasylvian cortex project primarily to the lateral portion of the superior colliculus, with the projection from the medial bank biased toward the superficial layers and axons from the lateral bank aimed mainly at the intermediate gray layer with some axons even reaching the deepest gray layer of the superior colliculus. Both the posteromedial and posterolateral divisions of the lateral suprasylvian cortex project to more extensive portions of the mediolateral and rostrocaudal dimensions of the superior colliculus than the anterior divisions. However, the posterolateral division projects more heavily to the intermediate gray layer than the posteromedial division; from the latter, axons distribute more superficially in the superior colliculus. Finally, the cortex surrounding the posterior suprasylvian sulcus projects primarily to the medial part of the superficial layers of the superior colliculus.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Ascending and descending projections from nucleus reticularis magnocellularis and nucleus reticularis gigantocellularis: an autoradiographic and horseradish peroxidase study in the rat

The projections of the rostral medulla were studied using retrograde and orthograde transport techniques in the rat. The present horseradish peroxidase (HRP) studies indicate that the ventral portion of nucleus reticularis gigantocellularis (NGC) and nucleus reticularis magnocellularis (NMC) project to both rostral and caudal levels of the spinal cord, while dorsal NGC projects only to the rostral cord. A differential density distribution of labeled cells was observed, with the greatest density of NGC-spinal neurons located rostral to the level of the inferior olive; and the greatest density of NMC-spinal neurons located caudally. This differential density distribution, when coupled with microiontophoretic application of [3H]amino acids allowed relatively independent labeling of the adjacent NGC- and NMC-spinal systems. On the basis of the HRP and autoradiographic studies 3 separate regions were delineated: dorsal NGC, ventral NGC and NMC. Descending projections from NGC were observed to the lateral vestibular nucleus, facial nucleus, hypoglossal nucleus and nucleus cuneatus. At cervical levels NGC fibers projected through the ventral and ventrolateral columns. Terminal fields were observed in laminae VII, VIII and to a lesser extent in IX. Labeled NGC fibers became difficult to follow by thoracic levels, which is consistent with the present HRP results. A continuum of descending NGC projections was observed with dorsally located NGC neurons projecting bilaterally through the ventral columns, and ventrally located NGC cells projecting through the ipsilateral ventrolateral columns. Ascending projections from NGC to the motor nucleus of V, trochlear nucleus, oculomotor nucleus, Edinger-Westphal nucleus, the ventral aspect of the periaqueductal gray, the deep and intermediate layers of the superior colliculus, nucleus parafasicularis and centromedianus, the Fields of Forel and the dorsal and lateral hypothalamic nuclei were observed. Descending projections from NMC to the dorsal nucleus of the vagus, hypoglossal nucleus, nucleus commissuralis and intercalatus were observed. At cervical levels, fibers project through the ipsilateral lateral columns, particularly its dorsal aspect. Terminal fields are located ipsilaterally in laminae IV, V and VI, and bilaterally in VII, VIII and X. NMC projections continue through caudal levels of the spinal cord including a projection to the ipsilateral intermediolateral columns. Ascending NMC projections are limited to the ventral pontine reticular formation.(ABSTRACT TRUNCATED AT 400 WORDS)

A pallidostriatal projection in the cat and monkey

Using the retrograde transport of horseradish peroxidase-labeled wheat germ agglutinin, a direct projection from the globus pallidus to the caudate nucleus and putamen was shown in the cat. The retrograde transport of the fluorescent dye Granular blue was used in a squirrel monkey to demonstrate a similar projection from the external pallidal segment to the putamen. No cell-labeling occurs in the cat's entopeduncular nucleus or the monkey's internal pallidal segment. In the cat, the pallidostriatal neurons are found in all parts of the globus pallidus and project throughout the striatum. However, the pallidostriatal projection is topographically organized such that it reciprocates the topography of the striatopallidal projection.

Long collateral branches of substantia nigra pars reticulata axons to thalamus, superior colliculus and reticular formation in monkey and cat. Multiple retrograde neuronal labeling with fluorescent dyes

In order to gain some impressions about the degree to which individual neurons of the pars reticulata of the substantia nigra send long collateral branches to more than one of its three major targets (thalamus, superior colliculus, reticular formation), two, or all three targets were injected with fluorescent dyes (Evan's blue, granular blue, nuclear yellow, propidium iodide) in six squirrel monkeys and four cats. The best results were obtained in the monkey brain with injections of Evan's blue in the thalamus, granular blue in the colliculus and nuclear yellow in the reticular formation. Whereas nigrothalamic and nigroreticular neurons are numerous and widely scattered throughout all parts of the pars reticulata, cells projecting only to the superior colliculus are fewer in number and restricted to a rostral-lateral zone. These results are consistent with earlier data obtained with the horseradish peroxidase method. Although double-labeled cells with projections to both the thalamus and reticular formation occur throughout the pars reticulata, such cells are somewhat more abundant at caudal levels of the nucleus. Cells containing dyes from both the superior colliculus and reticular formation are less common and restricted to the lateral part of the pars reticulata. A small number of cells near the rostral pole of the pars reticulata contain dye from both the tectal and thalamic injection. Typically, less than two dozen cells in any case can be confidently identified as containing all three dyes and these cells are located in the rostrolateral half of the pars reticulata. Fewer than 20% of the labeled nigral cells contain more than one dye. In the cat, thalamic injection of granular blue and tectal injection of nuclear yellow indicate that most nigrotectal cells are located in the middle of the mediolateral expanse of the pars reticulata in its rostral half. Nigrothalamic cells flank the nigrotectal group medially, laterally and caudally. Where these groups border one another, several cells contain both dyes indicating that they project to both the thalamus and colliculus. In both the cats and monkeys, a less extensive cell-labeling occurs in the contralateral nigra with a pattern similar to that in the ipsilateral substantia nigra. The results indicate that several neurons of the substantia nigra's pars reticulata send long collateral branches to two or even all three of the major targets. Many reticulata cells, however, appear to project either to the thalamus, or to the superior colliculus or to the reticular formation.

A direct projection from the retina to the intermediate gray layer of the superior colliculus demonstrated by anterograde transport of horseradish peroxidase in monkey, cat and rat

The anterograde transport of horseradish peroxidase (HRP) was used to re-examine the retinal projection to the superior colliculus in the monkey, cat and rat. By a somewhat novel application of the HRP in which the enzyme is deposited intravitreally in two or three sequential installments at 24 h intervals and by modifications that increase the sensitivity of the tetramethylbenzidine reaction procedure, we have successfully mapped the distribution of a significant number of retinal ganglion cell axons below the stratum opticum in the intermediate gray layer of the superior colliculus. Although the deep retinotectal axons project to the contralateral colliculus in all animals used, such axons can be followed as well, but in lesser numbers, to the ipsilateral intermediate gray layer in the cat and even more so in the monkey. The deep retinotectal axons here demonstrated may mediate the short latency responses of deep tectal neurons observed in earlier physiological studies and can no longer be considered as inconsequential to the visuo-oculomotor functions of the deep collicular layers.

A reciprocal axonal connection between the subthalamic nucleus and the neostriatum in the cat

Injections of wheatgerm agglutinin conjugated to horseradish peroxidase (WGA-HRP) into several small regions of the head and body of the caudate nucleus and the putamen of the cat result in retrograde cell-labeling of neurons in the ipsilateral subthalamic nucleus. A mediolateral but no rostrocaudal or dorsoventral topography is apparent in the subthalamostriatal projection. Anterograde transport of WGA-HRP and autoradiography after [3H]amino acid injection of the caudate suggest also a reciprocal striatosubthalamic projection.

The central projections of the trigeminal, facial, glossopharyngeal and vagus nerves: an autoradiographic study in the rat

The central distributions of primary afferent axons in the facial, trigeminal (mandibular branch), glossopharyngeal, and vagal nerves of the rat have been re-examined using the autoradiographic tracing technique after injections of [3H]proline or [3H]leucine into their peripheral ganglia. Within the nucleus of the solitary tract (NST), the labeled terminals from VII, V, IX and X form a continuous distribution that spans the length of this nucleus. Sensory axons in VII terminate mainly within the lateral division of the rostral NST, although some of the terminals extend further caudally within the nucleus. Immediately caudal to the rostral NST, the distribution continues with major contributions from V and IX. Both are confined mainly to the lateral division of the NST, although some of the fibers in IX terminate within the medial division. Injections into the inferior ganglion of X confirm the extensive distribution of vagal axons as they ramify significantly within the lateral division, and virtually monopolize the medial division of the NST. Thus, the major zone of convergency for these 4 cranial nerves is the lateral division of the nucleus from the level of the entering fascicles of IX caudally to the level of the area postrema. Furthermore, only X has a crossed projection as vagal axons invade the commissural nucleus and the medial division of the contralateral NST. Vagal fibers also enter the area postrema bilaterally. Finally, some afferent fibers from VII, IX and X descend in the dorsal part of the spinal trigeminal tract and terminate within the marginal subdivision of the spinal trigeminal nucleus pars caudalis, as well as the dorsal horn of the cervical spinal cord.

The distribution and some morphological features of substantia nigra neurons that project to the thalamus, superior colliculus and pedunculopontine nucleus in the monkey

Neurons of the substantia nigra's pars reticulata that send axons to the thalamus, superior colliculus and midbrain reticular formation (including the pedunculopontine nucleus) have been revealed in monkeys by the technique of retrograde transport of horseradish peroxidase. The populations of nigrothalamic, nigrotectal and nigroreticular neurons differ from one another in their number, intranigral distribution and somatodendritic size and shape. Nigrothalamic cells are the most abundant and, although scattered throughout the mediolateral expanse of the pars reticulata, their numbers progressively diminish from rostral to caudal levels. Nigrotectal cells are least numerous and are restricted almost exclusively to the lateral margin of the rostral one-half of the pars reticulata. Nigroreticular cells, like nigrothalamic, are scattered throughout the mediolateral dimension of the nucleus, but are more commonly located at middle to caudal levels. In addition to their restricted intranigral location, the nigrotectal cells are larger, polygonal and have more major dendritic processes than the smaller nigrothalamic and nigroreticular cells which are usually triangular or fusiform. A small proportion of cells of all three types appears to project contralaterally. These findings indicate that the efferent organization of the primate pars reticulata differs markedly from that of the rodent and the monkey's nigrotectal cells constitute a spatially and morphologically distinct subpopulation within the pars reticulata. These data should be useful in understanding the functional organization of topographic inputs to the pars reticulata such as that from the neostriatum.

A comparison of the intranigral distribution of nigrotectal neurons labeled with horseradish peroxidase in the monkey, cat, and rat

The location of neurons in the substantia nigra's pars reticulata (SNR) that send their axons to the superior colliculus was compared in the monkey, cat, and rat using the horseradish peroxidase (HRP) retrograde cell-labeling method. Although several cases of large, unilateral HRP deposits in the superior colliculus show that in all three species, the nigrotectal cells are confined, for the most part, to the rostral one-half of SNR, the following differences were noted in the precise location of the nigrotectal neurons and in the degree of bilaterality of the nigrotectal projection. In the monkey, labeled nigrotectal cells were particularly numerous in the extreme rostrolateral portion of SNR. From this region of high concentration, a progressively decreasing number of cells spreads medially in a ventral stratum immediately dorsal to the pes pedunculi. No labeled cells were found in the extreme medial part of SNR. A substantial number of HRP-positive cells were present in the contralateral SNR in a similar distribution. In the cat, labeled cells were less selectively localized in SNR's mediolateral expanse, being distributed more or less randomly in its middle portion with a scattering of cells in both medial and lateral parts of SNR. Although some cell labeling occurred in the contralateral SNR, it was less substantial than in the monkey. In the rat, the HRP-positive cells were especially concentrated throughout the mediolateral extent of a ventral stratum of SNR immediately dorsal to the pes pedunculi. Although some cells were located more dorsally, they were far fewer in number and consistently less heavily labeled. Only one or two labeled cells could be detected in the contralateral SNR of the rat. These anatomical differences suggest that the influence of the corpus striatum on the tectal control of orienting responses may vary considerably from one mammalian species to the next.

The nucleus of the solitary tract in the monkey: projections to the thalamus and brain stem nuclei

The projections of the nucleus of the solitary tract (NST) were studied by autoradiographic anterograde fiber-tracing and horseradish peroxidase (HRP) retrograde cell-labeling. Tritiated proline and leucine were deposited in electrophysiologically identified regions of NST. Injections of NST at levels caudal to where the vagus enters the nucleus, from which responses were evoked by stimulation of cranial nerves IX and X, revealed topographically organized bilateral projections to, most prominently, the ventrolateral medullary reticular formation which contains neurons of the ambiguus complex, and to the lateral and medial parabrachial nuclei, including a small portion of the medially adjacent central gray substance. Labeled fibers in the ventrolateral reticular formation were present from the nucleus retroambigualis rostralward to the retrofacial nucleus, with the densest concentration located over the nucleus ambiguus proper. The parabrachial projection was confirmed using HRP and shown to originate from cells in the medial subdivision of NST. Due to the problem of fibers en passant, it was not possible to interpret conclusively the cell-labeling seen around the solitary tract after HRP injections made in the region of the nucleus ambiguus. Labeled fibers were also traced from caudal NST to the dorsal motor nucleus of the vagus, but their origin could not be determined with certainty. Other labeled axons, traced to circumscribed parts of the inferior olivary complex and via the contralateral medial lemniscus to VPL of the thalamus, were shown in HRP experiments to originate from the dorsal column nuclei rather than NST. No labeled fibers were traced into the spinal cord, nor were any cells labeled in NST after large HRP deposits in upper cervical segments. Isotope deposits at levels of NST rostral to the entrance of the vagus, from which responses were evoked by rapid stimulation of the tongue, revealed an ipsilateral projection which ascends as a component of the central tegmental tract to the parvicellular part of the ventral posteromedial thalamic nucleus (VPMpc). After small HRP deposits in VPMpc, labeled cells in NST were restricted to the rostral part of the lateral subdivision. No labeled axons were traced from rostral NST to the ambiguus complex or parabrachial area. Injections of 3H-amino acids at intermediate levels of NST resulted in fiber-labeling in VPMpc, the parabrachial area, and the ambiguus complex.

Efferent connections of the substantia nigra and ventral tegmental area in the rat

Small injections of tritiated leucine and proline confined to the ventral tegmental area (AVT) were found to label fibers ascending: (a) to the entire ventromedial half of the striatum, but most massively to the ventral striatal zone that includes the nucleus accumbens; (b) to the thalamus: lateral habenular nucleus, nuclei reuniens and centralis medius, and the most medial zone of the mediodorsal nucleus; (c) to the posterior hypothalamic nucleus and possibly the lateral hypothalamic and preoptic region; (d) to the nuclei amygdalae centralis, lateralis and medialis; (e) to the bed nucleus of the stria terminalis, the nucleus of the diagonal band, and the medial half of the lateral septal nucleus; (f) to the anteromedial (frontocingulate) cortex; and (g) to the entorhinal area. Further AVT efferents descend to the medial half of the midbrain tegmentum including an anterior region of the median raphe nucleus, to the ventral half of the central grey substance including the dorsal raphe nucleus, to the parabrachial nuclei, and to the locus coeruleus. Similar injections centered in the pars compacta of the substantia nigra (SNC) label fibers that are distributed in the striatum in an orderly medial-to-lateral arrangement, and almost entirely avoid the nucleus accumbens and olfactory tubercle. With the exception of the lateral quarter of the substantia nigra, which apparently does not project to the extreme rostral pole of the striatum, each small SNC locus, regardless of its anteroposterior localization, distributes nigrostriatal fibers throughout the length of the striatum. Descending SNC efferents are distributed to the same general regions that receive descending AVT projections, except that no SNC fibers appear to enter the locus coeruleus. Isotope injections confined to the pars reticulata (SNR) label sparse nigrostriatal fibers, and numerous nigrothalamic fibers ascending mainly to the nucleus ventromedialis and in lesser number to the parafascicular nucleus and the paralamellar zone of the nucleus mediodorsalis. Descending SNR fibers leave the nigra as a voluminous fiber bundle that bifurcates into a large nigrotectal and a smaller nigrotegmental component, the latter terminating largely in the pedunculopontine nucleus of the pontomesencephalic tegmentum.

An autoradiographic examination of the central distribution of the trigeminal, facial, glossopharyngeal, and vagal nerves in the monkey

The central distributions of primary afferent axons in cranial nerves V, VII, IX, and X have been re-examined autoradiographically after 3H-proline injections into their peripheral ganglia. Fiber-labeling after subtotal injections of the trigeminal ganglion, besides confirming earlier classical descriptions, suggests that trigeminal fibers of the ophthalmic and mandibular (but not maxillary) branches enter the ventrolateral part of the nucleus of the solitary tract (NST). Injection of VII's geniculate ganglion labels fibers which both ascend and descend upon reaching NST. The ascending fibers distribute in a compact and circumscribed zone immediately dorsal to the spinal V nucleus as far rostral as the caudal pole of the principal trigeminal nucleus. The descending fibers distribute to the lateral NST rostral to the level at which X joins the solitary tract. For a short distance caudal to this level, sparse label is confined to a small part of lateral NST ventral to the solitary tract, which corresponds to the zone receiving direct trigeminal afferents. Fiber-labeling after injections of the ganglia of nerves IX and X suggest the following. Although, upon reaching NST, a few fibers of either IX or X ascend as far rostrally as had those of VII, both have a much larger descending component which distributes to more caudal levels of NST. Most of IX's axons appear to end in the lateral NST; only a few travel as far as the obex. Fibers of X, on the other hand, are abundant in the medial and commissural parts of NST. Moreover, only X appears to have a crossed projection in the commissural nucleus and caudal portion of the contralateral NST. A few fibers of vagal origin also appear to enter the area postrema. Whereas fibers of X appear to constitute the solitary tract, few if any fibers of VII or IX travel within that fascicle. A significant descending components of labeled fibers appears in the spinal V tract when the superior ganglion of either IX or X is injected. These fibers distribute mainly in the pars caudalis of the spinal V nucleus and, to a lesser degree, the cuneate nucleus.

Convergent prefrontal and nigral projections to the striatum of the rat

Projections to the striatum from the prefrontal cortex, the substantia nigra's pars compacta (SNC), and the ventral tegmental area (AVT) were examined autoradiographically. These projections converge on the striatum in an organized manner such that the prefrontal areas innervated by AVT project to the same part of the striatum as AVT, and prefrontal areas innervated by SNC project to the same part of the striatum as SNC.

Afferent connections of the entorhinal area in the rat as demonstrated by retrograde cell-labeling with horseradish peroxidase

The entorhinal cortex (EC) of the rat has been divided into medial (MEA) and lateral (LEA) subdivisions. In order to analyze its afferent connections, small deposits of horseradish peroxidase (HRP) were placed at various loci within EC. The patterns of retrograde cell-labeling charted in 18 such cases suggested that EC is projected upon by several allocortical and subcortical structures and that there are differences in the afferent connections of the two subdivisions. Thus, although HRP injection of either division of EC led to cell-labeling in the hippocampal formation, most in ammonic field CA1 and the subiculum, several cells of the presubiculum were preferentially labeled by injection of MEA. Injections of LEA, but not those in MEA, resulted in substantial cell-labeling in the anterior piriform cortex of both hemispheres. Regardless of the location of its injection site within EC, the enzyme labeled cells in the diagonal band nucleus of Broca, amygdala and claustrum. The pattern of cell-labeling in the diagonal band nucleus extended into the ventrolaterally contiguous nucleus basalis after injection of LEA and into the dorsally contiguous medial septal nucleus after injection of MEA Whereas HRP deposits in either division of EC resulted in cell-labeling in the cortical and medial nuclei of the amygdala, only those deposits which involved LEA led to cell-labeling in the posterior part of the lateral nucleus. In the thalamus, labeled cells were found in the rostral part of the paratenial, periventricular and reuniens nuclei. Finally, at midbrain levels, numerous labeled cells appeared in the dorsal raphe nucleus, a few in the median raphe and locus coeruleus, and, only after rostral EC injection, in the ventral tegmental area.

Convergent thalamic and mesencephalic projections to the anterior medial cortex in the rat

Small microelectrophoretic deposits of horseradish-peroxidase (HRP) were placed at various loci within the gray matter of the rat's anterior medial cortex. A comparison of the patterns of retrograde cell-labeling charted in 26 such cases confirmed earlier findings in fiber-degeneration studies according to which the respective thalamocortical projections of the mediodorsal (MD) and anteromedial nucleus (AM) overlap each other over a wide region of the anterior medial cortex. This region of thalamocortical convergence, extending from pregenual levels caudalward as far as the anterior border of the retrosplenial cortex, corresponds almost exactly to the cortical region from which locally deposited HRP was found to be transported so as to label cells in one or both of two mesencephalic cell groups: the ventral tegmental area (AVT) dorsal and lateral to the interpeduncular nucleus, and the medial one-quarter of the pars compacta of the substantia nigra (SNC).