Glutamate synaptic inputs to ventral tegmental area neurons in the rat derive primarily from subcortical sources.

Dopamine and GABA neurons in the ventral tegmental area project to the nucleus accumbens and prefrontal cortex and modulate locomotor and reward behaviors as well as cognitive and affective processes. Both midbrain cell types receive synapses from glutamate afferents that provide an essential control of behaviorally-linked activity patterns, although the sources of glutamate inputs have not yet been completely characterized. We used antibodies against the vesicular glutamate transporter subtypes 1 and 2 (VGlut1 and VGlut2) to investigate the morphology and synaptic organization of axons containing these proteins as putative markers of glutamate afferents from cortical versus subcortical sites, respectively, in rats. We also characterized the ventral tegmental area cell populations receiving VGlut1+ or VGlut2+ synapses according to their transmitter phenotype (dopamine or GABA) and major projection target (nucleus accumbens or prefrontal cortex). By light and electron microscopic examination, VGlut2+ as opposed to VGlut1+ axon terminals were more numerous, had a larger average size, synapsed more proximally, and were more likely to form convergent synapses onto the same target. Both axon types formed predominantly asymmetric synapses, although VGlut2+ terminals more often formed synapses with symmetric morphology. No absolute selectivity was observed for VGlut1+ or VGlut2+ axons to target any particular cell population. However, the synapses onto mesoaccumbens neurons more often involved VGlut2+ terminals, whereas mesoprefrontal neurons received relatively equal synaptic inputs from VGlut1+ and VGlut2+ profiles. The distinct morphological features of VGlut1 and VGlut2 positive axons suggest that glutamate inputs from presumed cortical and subcortical sources, respectively, differ in the nature and intensity of their physiological actions on midbrain neurons. More specifically, our findings imply that subcortical glutamate inputs to the ventral tegmental area expressing VGlut2 predominate over cortical sources of excitation expressing VGlut1 and are more likely to drive the behaviorally-linked bursts in dopamine cells that signal future expectancy or attentional shifting.

Projections from the rat prefrontal cortex to the ventral tegmental area: target specificity in the synaptic associations with mesoaccumbens and mesocortical neurons.

Excitatory projections from the prefrontal cortex (PFC) to the ventral tegmental area (VTA) play an important role in regulating the activity of VTA neurons and the extracellular levels of dopamine (DA) within forebrain regions. Previous investigations have demonstrated that PFC terminals synapse on the dendrites of DA and non-DA neurons in the VTA. However, the projection targets of these cells are not known. To address whether PFC afferents innervate different populations of VTA neurons that project to the nucleus accumbens (NAc) or to the PFC, a triple labeling method was used that combined peroxidase markers for anterograde and retrograde tract-tracing with pre-embedding immunogold-silver labeling for either tyrosine hydroxylase (TH) or GABA. Within the VTA, PFC terminals formed asymmetric synapses onto dendritic shafts that were immunoreactive for either TH or GABA. PFC terminals also synapsed on VTA dendrites that were retrogradely labeled from the NAc or the PFC. Dendrites retrogradely labeled from the NAc and postsynaptic to PFC afferents were sometimes immunoreactive for GABA but were never TH-labeled. Conversely, dendrites retrogradely labeled from the PFC and postsynaptic to PFC afferents were sometimes immunoreactive for TH but were never GABA-labeled. These results provide the first demonstration of PFC afferents synapsing on identified cell populations in the VTA and indicate a considerable degree of specificity in the targets of the PFC projection. The unexpected finding of selective PFC synaptic input to GABA-containing mesoaccumbens neurons and DA-containing mesocortical neurons suggests novel mechanisms through which the PFC can influence the activity of ascending DA and GABA projections.

Dopamine terminals in the rat prefrontal cortex synapse on pyramidal cells that project to the nucleus accumbens.

Afferents to the prefrontal cortex (PFC) from dopamine neurons in the ventral tegmental area have been implicated in working memory processes and in the pathogenesis of schizophrenia. Previous anatomical investigations have demonstrated that dopamine terminals synapse on dendritic spines and shafts of pyramidal cells in the PFC. Moreover, neurochemical and physiological studies suggest that dopamine modulates the activity of PFC neurons that project to the nucleus accumbens. However, whether this modulation involves direct synaptic input to cortico-accumbens projection neurons has not been determined. To address this question, retrograde transport of an attenuated strain of pseudorabies virus (PRV) from the nucleus accumbens was combined with immunoperoxidase labeling of tyrosine hydroxylase (TH) to identify dopamine terminals in the PFC. At survival times <48 hr, extensive dendritic distribution of immunogold labeling for PRV was observed in cortico-accumbens neurons. However, evidence consistent with trans-synaptic passage of PRV within this timeframe was observed only rarely. When examined at the electron microscopic level, immunogold labeling for PRV was localized to neuronal somata, proximal and distal dendrites, and dendritic spines. Some of these dendritic processes received symmetric synaptic input from TH-immunoreactive terminals. These data represent the first demonstration of dopamine synaptic contacts onto an identified population of pyramidal cells in the PFC. The findings have important implications for understanding how dopamine modulates cortical outflow to limbic regions in normal brain and pathological states such as schizophrenia.

Dopamine terminals synapse on callosal projection neurons in the rat prefrontal cortex.

Dopamine (DA) afferents to the prefrontal cortex (PFC) play an important role in the cognitive functions subserved by this cortical area. Within the PFC, DA terminals synapse onto the distal dendrites of both local circuit neurons and pyramidal projection cells. We have previously demonstrated in the rat PFC that some of the dendrites and spines postsynaptic to DA terminals arise from pyramidal neurons that project to the nucleus accumbens. However, it is not known whether the pyramidal cells that give rise to callosal intercortical connections of the PFC also receive DA synaptic input. To address this question, retrograde tract tracing using an attenuated strain of pseudorabies virus (PRV-Bartha) was combined with immunocytochemistry for tyrosine hydroxylase (TH) to identify DA terminals in the PFC. Thirty-six to 40 hours following injection of PRV into the contralateral PFC, numerous callosal projection neurons were extensively labeled throughout their dendritic trees, with no evidence of PRV trans-synaptic passage. In tissue prepared for electron microscopy, labeling for PRV was distributed throughout pyramidal cell somata and extended into distal dendrites and dendritic spines. Some PRV-labeled dendrites and spines received symmetric synaptic input from terminals containing peroxidase labeling for TH. These results demonstrate that DA terminals synapse onto the distal dendrites of callosally projecting PFC neurons and suggest substrates through which DA may modulate interhemispheric cortical communication.

Hippocampal afferents to the rat prefrontal cortex: synaptic targets and relation to dopamine terminals.

Afferents to the prefrontal cortex (PFC) from the hippocampal formation and from midbrain dopamine (DA) neurons have been implicated in the cognitive and adaptive functions of this cortical region. In the present study, we investigated the ultrastructure and synaptic targets of hippocampal terminals, as well as their relation to DA terminals within the PFC of adult rats. Hippocampal afferents were labeled either by anterograde transport of wheat germ agglutinin-horseradish peroxidase (WGA-HRP) from the ventral hippocampal formation or by anterograde degeneration following fimbria lesion. Hippocampal terminals in the PFC, identified by either method, formed primarily asymmetric axospinous synapses, with a small percentage forming asymmetric axodendritic synapses. Dopamine terminals in the PFC were identified by peroxidase immunocytochemistry for either tyrosine hydroxylase or DA and formed primarily symmetric synapses onto dendritic spines and small caliber dendritic shafts. Spines that received symmetric synaptic contact from DA terminals invariably also received an asymmetric synapse from an unlabeled terminal, forming a triadic complex. Hippocampal and DA terminals in the PFC were not often observed in the same area of the neuropil, and no examples of convergence of hippocampal and DA terminals onto common postsynaptic targets were observed. Further analysis revealed that spines receiving synaptic contact from hippocampal terminals did not receive additional synaptic contact from any other source. However, when localized to the same area of the neuropil, hippocampal and DA terminals were often in direct apposition to one another, without forming axo-axonic synapses. These results suggest that 1) hippocampal terminals primarily form excitatory synapses onto spiny pyramidal neurons, 2) hippocampal afferents are unlikely to be synaptically modulated by DA or non-DA terminals at the level of the dendritic spine, and 3) appositions between hippocampal and DA terminals may facilitate presynaptic interactions between these afferents to the PFC.

Prefrontal cortical efferents in the rat synapse on unlabeled neuronal targets of catecholamine terminals in the nucleus accumbens septi and on dopamine neurons in the ventral tegmental area.

Physiological and pharmacological studies indicate that descending projections from the prefrontal cortex modulate dopaminergic transmission in the nucleus accumbens septi and ventral tegmental area. We investigated the ultrastructural bases for these interactions in rat by examining the synaptic associations between prefrontal cortical terminals labeled with anterograde markers (lesion-induced degeneration or transport of Phaseolus vulgaris leucoagglutinin; PHA-L) and neuronal processes containing immunoreactivity for the catecholamine synthesizing enzyme, tyrosine hydroxylase. Prefrontal cortical terminals in the nucleus accumbens and ventral tegmental area contained clear, round vesicles and formed primarily asymmetric synapses on spines or small dendrites. In the ventral tegmental area, these terminals also formed asymmetric synapses on large dendrites and a few symmetric axodendritic synapses. In the nucleus accumbens septi, degenerating prefrontal cortical terminals synapsed on spiny dendrites which received convergent input from terminals containing peroxidase immunoreactivity for tyrosine hydroxylase, or from unlabeled terminals. In single sections, some tyrosine hydroxylase-labeled terminals formed thin and punctate symmetric synapses with dendritic shafts, or the heads and necks of spines. Close appositions, but not axo-axonic synapses, were frequently observed between degenerating prefrontal cortical afferents and tyrosine hydroxylase-labeled or unlabeled terminals. In the ventral tegmental area, prefrontal cortical terminals labeled with immunoperoxidase for PHA-L were in synaptic contact with dendrites containing immunogold reaction product for tyrosine hydroxylase, or with unlabeled dendrites. These results suggest that: (1) catecholaminergic (mainly dopaminergic) and prefrontal cortical terminals in the nucleus accumbens septi dually synapse on common spiny neurons; and (2) dopaminergic neurons in the ventral tegmental area receive monosynaptic input from prefrontal cortical afferents. This study provides the first ultrastructural basis for multiple sites of cellular interaction between prefrontal cortical efferents and mesolimbic dopaminergic neurons.

Ultrastructural localization of the serotonin transporter in superficial and deep layers of the rat prelimbic prefrontal cortex and its spatial relationship to dopamine terminals.

Dopamine levels within the prefrontal cortex (PFC) can be manipulated by selective inhibitors of the serotonin transporter (SERT). However, the cellular mechanisms underlying these effects are not clear. The present study sought to examine the distribution of immunogold-silver labeling for SERT (SERT-ir) in the rat prelimbic PFC and to describe its ultrastructural spatial relationship to dopamine axons labeled by immunoperoxidase staining for tyrosine hydroxylase (TH-ir). SERT was localized to axonal profiles that ranged in size from fine caliber fibers containing dense SERT-ir, primarily along the membrane, and rarely forming synapses to large, spherical varicosities exhibiting less dense staining, mainly within the cytoplasm, and more commonly forming synapses. Synaptic contacts of SERT profiles were typically asymmetric, axospinous, and more frequent in superficial (38%) than deep (19%) layers. For TH-ir profiles, only 24% were within the same 13.8 microm(2) microenvironment as SERT-ir profiles. Furthermore, TH-ir and SERT-ir profiles were rarely directly apposed to each other or convergent onto common dendritic structures. Instead, these two profiles were typically separated by an average distance of 1.30 microm in the coronal plane, a value that did not vary with the size of SERT-ir axons, the amount of SERT labeling, or the cortical layer examined. These results are consistent with two populations of SERT profiles within the rat prelimbic PFC that may arise from different raphe nuclei or that represent varicose and intervaricose portions of the same axons. Moreover, the functional interactions between cortical serotonin and dopamine systems that may contribute to the therapeutic efficacy of antidepressant drugs are likely to occur over distances greater than 1 microm.

Dynorphin-immunoreactive terminals in the rat nucleus accumbens: cellular sites for modulation of target neurons and interactions with catecholamine afferents.

Dynorphin facilitates conditioned place aversion and reduces locomotor activity through mechanisms potentially involving direct activation of target neurons or release of catecholamines from afferents in the nucleus accumbens. We examined the ultrastructural substrates underlying these actions by combining immunoperoxidase labeling for dynorphin 1-8 and immunogold silver labeling for the catecholamine synthesizing enzyme, tyrosine hydroxylase (TH). The two markers were simultaneously visualized in single coronal sections through the rat nucleus accumbens. By light microscopy, dynorphin immunoreactivity was seen as patches of immunoreactive varicosities throughout all rostrocaudal levels of the nucleus accumbens. The dynorphin-immunoreactive terminals identified by electron microscopy ranged from 0.2 to 1.5 microns in cross-sectional diameter, contained numerous small (30-40 nm) clear vesicles, as well as one or more large (80-100 nm) dense core vesicles. From the dynorphin-immunoreactive terminals quantitatively examined in single sections, 74% (173/370) showed symmetric synaptic junctions mainly with large unlabeled dendrites. Of the dynorphin-immunoreactive terminals forming identifiable synapses, approximately 30% contacted more than one dendritic target. In addition, single dendrites frequently received convergent input from more than one dynorphin-labeled terminal. Irrespective of their dendritic associations, dynorphin-immunoreactive terminals also frequently showed close appositions with other axons and terminals; these included unlabeled (41%), TH-labeled (10%) or dynorphin-labeled axons (14%). In contrast to dynorphin-immunoreactive terminals, TH-labeled terminals formed primarily symmetric synapses with small dendrites and spines or lacked recognizable specializations in the plane of section analyzed. In some cases, single dendrites were postsynaptic to both dynorphin and TH-immunoreactive terminals. We conclude that dynorphin-immunoreactive terminals potently modulate, and most likely inhibit, target neurons in both subregions of the rat nucleus accumbens. This modulatory action could attenuate or potentiate incoming catecholamine signals on more distal dendrites of the accumbens neurons. The findings also suggest potential sites for presynaptic modulatory interactions involving dynorphin and catecholamine or other transmitters in apposed terminals.

Ultrastructural immunocytochemical localization of neurotensin and the dopamine D2 receptor in the rat nucleus accumbens.

The neuroleptic-like effects of neurotensin (NT) are thought to be due to interactions with dopamine (DA) acting primarily at D2 receptors within the nucleus accumbens septi (Acb). Using electron microscopic dual labeling immunocytochemistry, we sought to demonstrate cellular substrates for functional interactions involving NT and DA D2 receptors in the adult rat Acb. Peroxidase reaction product representing D2 receptor-like immunoreactivity (D2-LI) was seen along membranes of Golgi lamellae and multivesicular bodies of perikarya containing immunogold labeling representing NT-LI. Dually labeled somata usually contained highly indented nuclei, a characteristic of aspiny neurons. Dendrites also occasionally colocalized the two immunomarkers. Other somata, dendrites, and all axon terminals were singly labeled with either NT-LI or D2-LI. In distinct sets of terminals, NT-LI was commonly associated with large, dense-cored vesicles, whereas D2-LI was found along the plasmalemma and over nearby small clear vesicles. Each type of terminal comprised approximately 20% of synaptic input to NT-immunoreactive dendrites. Similar proportions of terminals containing NT-LI or D2-LI contacted unlabeled (approximately 55%) or NT-labeled (approximately 35%) dendrites and, occasionally, were observed converging onto common dendrites. Terminals containing NT-LI or D2-LI also were often closely apposed. These findings provide the first ultrastructural evidence that: (1) NT and D2 receptors are colocalized in aspiny neurons and dendrites, (2) NT may produce a direct postsynaptic effect on neurons receiving input from terminals which are presynaptically modulated by DA via D2 receptors, and (3) NT and DA acting at D2 receptors may interact through presynaptic modulation of common axon terminals.

Axon terminals immunolabeled for dopamine or tyrosine hydroxylase synapse on GABA-immunoreactive dendrites in rat and monkey cortex.

Dopamine afferents to the cortex regulate the excitability of pyramidal neurons via a direct synaptic input. However, it has not been established whether dopamine also modulates pyramidal cell activity indirectly through synapses on gamma-aminobutyric acid (GABA) interneurons, and whether such inputs differ across cortical regions and species. We sought to address these issues by an immunocytochemical electron microscopic approach that combined peroxidase staining for dopamine or tyrosine hydroxylase (TH) with a pre-embedding gold-silver marker for GABA. In the deep layers of the rat prefrontal cortex and in the superficial layers of the monkey prefrontal and primary motor cortices, terminal varicosities immunoreactive for dopamine or TH formed primarily thin, symmetric synapses on distal dendrites. Both GABA-immunoreactive dendrites as well as unlabeled spines and dendrites were contacted by dopamine- or TH-immunoreactive terminals. Synaptic specializations were detected at some, but not all of these contacts. The relative frequency of these appositional and synaptic contacts did not appear to differ between the rat and monkey prefrontal cortex, or between the monkey prefrontal and motor cortices. Across regions and species, labeled and unlabeled targets of dopamine- or TH-positive terminals received additional synaptic input from unlabeled, and occasionally GABA-immunoreactive terminals. Close appositions between dopamine- or TH-immunoreactive and GABA-positive terminals were observed only rarely. These findings indicate that dopamine afferents provide direct synaptic inputs to GABA local circuit neurons in a consistent fashion across cortical regions and species. Thus, dopamine's cellular actions involve direct as well as modulatory effects on both GABA interneurons and pyramidal projection neurons.

Parvalbumin-immunoreactive axon terminals in macaque monkey and human prefrontal cortex: laminar, regional, and target specificity of type I and type II synapses.

In sensory regions of primate neocortex, the calcium-binding protein parvalbumin (PV) is present in axon terminals that form both Gray's type I (asymmetric) and type II (symmetric) synapses. Those terminals forming type I synapses appear to arise from relay nuclei in the thalamus, whereas those forming type II synapses derive from cortical local circuit neurons. However, whether PV is present in both of these two types of terminals in the association regions of the primate prefrontal cortex (PFC) is not known. In the present study, PV-immunoreactive (IR) axon terminals in the superficial layers (layers 2-3a) of monkey PFC area 9 were found to form exclusively type II synapses onto the dendritic spines (44%), shafts (39%), or somata/axon initial segments (17%) of pyramidal neurons. In contrast, in the middle layers (layers 3b-4), 52% of the PV-IR axon terminals formed type I synapses, and 79% of these terminals contacted dendritic spines. However, in the adjacent area 46, only 12% of the PV-IR terminals in the middle layers formed type I synapses. In addition, the PV-IR axon terminals forming type I synapses were 50% larger than those terminals forming type II synapses. Similar to the macaque monkey, in area 9 of the human PFC, PV-IR axon terminals forming type I synapses onto dendritic spines were found in the middle layers. These findings indicate that PV-IR axon terminals in macaque monkey and human PFC are likely to have both intrinsic and extrinsic sources. In addition, the laminar, regional, and target specificity of the labeled terminals forming type I synapses suggests that they arise from PV-IR neurons in the mediodorsal thalamic nucleus.

Dopamine transporter immunoreactivity in monkey cerebral cortex: regional, laminar, and ultrastructural localization.

Dopamine (DA) influences a number of cognitive and motor functions that are mediated by the primate cerebral cortex, and the DA membrane transporter (DAT) is known to be a critical regulator of DA neurotransmission in subcortical structures in rodents. To gain insight into the possible functional role of cortical DAT, we compared the regional, laminar, and ultrastructural distribution of DAT immunoreactivity to that of tyrosine hydroxylase (TH), the rate-limiting enzyme in DA synthesis, in the cerebral cortex of macaque monkeys. DAT-immunoreactive (DAT-IR) axons were present throughout the cortical mantle, with substantial differences in density and laminar distribution across cytoarchitectonic areas. In particular, high densities of DAT-IR axons were present in certain regions (e.g., posterior parietal cortex, dentate gyrus) not previously thought to receive a substantial DA input. The laminar distribution of DAT-IR axons ranged from a restricted localization of labeled axons to layer 1 in lightly innervated regions to the presence of axons in all six cortical layers, with a particularly dense plexus in deep layer 3, in highly innervated regions. These regional and laminar patterns paralleled those of TH-IR axons, but several differences in fiber morphology and ultrastructural localization of DAT were observed. For example, in contrast to TH, DAT immunoreactivity in the cortex was localized predominantly to small-diameter profiles, whereas, in the dorsolateral caudate nucleus, DAT and TH immunoreactivities were present in both large-diameter and small-diameter profiles, which may represent varicose and intervaricose axon segments, respectively. Overall, the distribution of DAT-IR axons confirms and extends the results of previous reports, using other markers of DA axons, that the DA innervation of the primate cerebral cortex is global but specialized on both a regional basis and a laminar basis. In particular, these observations reveal an anatomical substrate for a direct and potent influence of DA over neuronal activity in posterior parietal cortex and in certain regions of the temporal lobe. However, due to its predominant distribution to small-diameter profiles, immunoreactivity for DAT may not be an appropriate ultrastructural marker for larger DA varicosities in the primate cortex. Moreover, this distribution of DAT suggests that cortical DA fibers may permit greater neurotransmitter diffusion than subcortical DA axons.

Immunolocalization of the cocaine- and antidepressant-sensitive l-norepinephrine transporter.

Norepinephrine (NE) transporters (NETs) constitute the primary mechanism for inactivation of synaptically released NE, are targets for multiple antidepressants and psychostimulants, and have been reported to be deficient in affective and autonomic disorders. Although the regional distribution of NETs has been defined through synaptosomal transport and autoradiographic approaches, NET protein expression has yet to be characterized fully in the central nervous system (CNS). We identified a cytoplasmic NET epitope (amino acids 585-602) and corresponding antibody (43411) that permits cellular localization of endogenous NET expression in the CNS and periphery. In the adult rat brain, NET labeling was confined to noradrenergic neuronal somata, axons, and dendrites, including extensive arborizations within the hippocampus and cortex, but was absent from epinephrine- and dopamine-containing neurons. Intracerebroventricular anti-dopamine beta-hydroxylase/saporin, a treatment that destroys a majority of noradrenergic neurons and their projections, validated the specificity of the 43411 antibody. At the level of light microscopy, 43411 labeling colocalized with the axonal markers syntaxin, synaptophysin, and SNAP-25. Indirect immunofluorescence revealed a nonuniform pattern of NET expression along axons, particularly evident within sympathetic fibers of the vas deferens, reflecting a high degree of spatial organization of NE clearance. NET labeling in somata was intracellular and absent from plasma membranes. Among nonneuronal cells, glial cells lacked NET immunoreactivity, whereas CNS ependymal cells were an unexpected site of labeling. NET immunoreactivity was also evident in a subset of adrenal chromaffin cells where labeling appeared to be predominantly associated with intracellular vesicles. Initial ultrastructural evaluation via preembedding immunogold techniques also revealed substantial cytoplasmic NET immunoreactivity in axon terminals within the prelimbic prefrontal cortex, consistent with postulates of regulated trafficking controlling neurotransmitter clearance. NET visualization should be of significant benefit in evaluating neuronal injury resulting from chronic drug exposure and in disease states.

Synaptic targets of pyramidal neurons providing intrinsic horizontal connections in monkey prefrontal cortex.

xu I sLxxJ In monkey prefrontal cortex, the intrinsic axon collaterals of supragranular pyramidal neurons extend horizontally for considerable distances through the gray matter and give rise to stripe-like clusters of axon terminals (Levitt et al. [1993] J. Comp. Neurol. 338:360-376). Because understanding the functional role of these connections requires knowledge of their synaptic targets, we made injections of biotinylated dextran amine (BDA) into layer 3 of macaque prefrontal area 9 and examined the labeled intrinsic axon collaterals by electron microscopy. Labeled axon terminals formed exclusively asymmetric synapses, and 95.6% of the postsynaptic structures were dendritic spines, presumably belonging to other pyramidal neurons. The remaining postsynaptic structures were dendritic shafts, many of which had the morphological characteristics of local circuit neurons. The prefrontal injections also labeled associational projections that traveled through the white matter to terminate in other areas of prefrontal cortex. All of the synapses formed by these associational axons were asymmetric, and 91.9% were onto dendritic spines. The similarities in synaptic targets of the prefrontal intrinsic and associational axon terminals suggested that these projections might arise from the same neurons, an interpretation confirmed in dual label, retrograde tracing studies. To determine the specificity of the synaptic targets of these prefrontal connections, two additional comparisons were made. In the posterior parietal cortex (area 7a), 94.2% of the synapses furnished by BDA-labeled intrinsic collaterals of supragranular pyramidal neurons were also with dendritic spines. In contrast, only 75.6% of unlabeled asymmetric synapses in the prefrontal cortex were onto dendritic spines. These comparisons suggest that the axons of supragranular pyramidal neurons in primate association cortices are preferentially directed to specific targets. Finally, after injections of BDA, a small number of retrogradely labeled pyramidal neurons were observed within the anterogradely labeled clusters of intrinsic axon terminals. At the ultrastructural level, synapses between anterogradely labeled axon terminals and retrogradely labeled dendritic spines were identified. These findings suggest that reciprocal, monosynaptic connections may exist between pyramidal neurons located in different stripe-like clusters, providing a potential anatomical substrate for reverberating excitatory circuits within the primate association cortices.

Topographical organization of the efferent projections of the medial prefrontal cortex in the rat: an anterograde tract-tracing study with Phaseolus vulgaris leucoagglutinin.

The purpose of the present investigation was to examine the topographical organization of efferent projections from the cytoarchitectonic divisions of the mPFC (the medial precentral, dorsal anterior cingulate and prelimbic cortices). We also sought to determine whether the efferents from different regions within the prelimbic division were organized topographically. Anterograde transport of Phaseolus vulgaris leucoagglutinin was used to examine the efferent projections from restricted injection sites within the mPFC. Major targets of the prelimbic area were found to include prefrontal, cingulate, and perirhinal cortical structures, the dorsomedial and ventral striatum, basal forebrain nuclei, basolateral amygdala, lateral hypothalamus, mediodorsal, midline and intralaminar thalamic nuclei, periaqueductal gray region, ventral midbrain tegmentum, laterodorsal tegmental nucleus, and raphe nuclei. Previously unreported projections of the prelimbic region were also observed, including efferents to the anterior olfactory nucleus, the piriform cortex, and the pedunculopontine tegmental-cuneiform region. A topographical organization governed the efferent projections from the prelimbic area, such that the position of terminal fields within target structures was determined by the rostrocaudal, dorsoventral, and mediolateral placement of the injection sites. Efferent projections from the medial precentral and dorsal anterior cingulate divisions (dorsomedial PFC) were organized in a similar topographical fashion and produced a pattern of anterograde labeling different from that seen with prelimbic injection sites. Target structures innervated primarily by the dorsomedial PFC included certain neocortical fields (the motor, somatosensory, and visual cortices), the dorsolateral striatum, superior colliculus, deep mesencephalic nucleus, and the pontine and medullary reticular formation. Previously unreported projections to the paraoculomotor central gray area and the mesencephalic trigeminal nucleus were observed following dorsomedial PFC injections. These results indicate that the efferent projections of the mPFC are topographically organized within and across the cytoarchitectonic divisions of the medial wall cortex. The significance of topographically organized and restricted projections of the rat mPFC is discussed in light of behavioral and physiological studies indicating functional heterogeneity of this region.

Immunoblot and immunohistochemical comparison of murine monoclonal antibodies specific for the rat D1a and D1b dopamine receptor subtypes.

The two D1-like dopamine receptor subtypes, D1a and D1b, are structurally similar and pharmacologically indistinguishable using currently available ligands. To differentiate between the D1-like dopamine receptor subtypes, murine monoclonal antibodies to the rat Dla and the rat D1b dopamine receptor have been prepared. Rat D1-like and D2-like dopamine receptors expressed in Sf9 cells were used to verify the immunospecificity of the monoclonal anti-(D1a dopamine receptor) and anti-(D1b dopamine receptor) antibodies using immunoblot and immunohistochemical techniques. These two antibodies were used to compare the temporal dynamics of D1-like dopamine receptors expressed in Sf9 cells following infection with recombinant baculovirus and to monitor the partial purification of detergent solubilized receptors following ion exchange chromatography. Immunoreactivity of the anti-(D1a receptor) antibody was observed in the striatum and cortical regions of the rat brain using immunoblot techniques. No reactivity on immunoblots was observed for the anti-(D1b receptor) antibody using rat brain tissue, probably due to the low levels of receptor expression. For immunohistochemical studies using rat brain slices, the anti-(D1a receptor) antibody heterogeneously labeled cells and punctate processes within the striatal neuropil while labeling in the adjacent cerebral cortex was weak. Anti-(D1b receptor) antibody immunoreactivity was weak in the .striatum and generally limited to sparse perikarya in the dorsal region. However, immunoreactivity was observed in numerous cells within the vertical and horizontal limbs of the diagonal band and in the ventral pallidum. Immunoreactivity of the anti-(D1b receptor) antibody was also observed in layer V pyramidal neurons of the frontal sensorimotor cortex.

Limited collateralization of neurons in the rat prefrontal cortex that project to the nucleus accumbens.

The specificity and selectiveness of a neuronal message depends in part on the number of recipient neurons that simultaneously receive this message. Hence, projections involved in higher order cognitive processes might be expected to exhibit a lower degree of collateralization than projections that mediate more basic brain functions. This study sought to determine the degree to which neurons projecting from the prefrontal cortex to the nucleus accumbens collateralize to major cortical and subcortical regions: the contralateral prefrontal cortex, the basolateral amygdala or the ventral tegmental area. Fluoro-Gold and cholera toxin-b were used to label prefrontal cortex neurons that project to these targets, and the proportion of neurons singly and dually labeled by immunofluorescence for these tracers was determined. The prefrontal cortex neurons projecting to these regions exhibited a partially complementary laminar distribution. Furthermore, of the neurons projecting to the nucleus accumbens, 13% sent a collateralized projection to the contralateral prefrontal cortex, 7% collateralized to the basolateral amygdala, and 3% sent a branched projection to the ventral tegmental area. No differences were observed in the degree of collateralization of neurons in superficial versus deep layers.Thus, the degree of collateralization of corticoaccumbens neurons was overall limited, but significantly greater to a cortical target than to subcortical regions. These branching patterns provide anatomical substrates for temporal and spatial coordination of activity in limbic circuits.

Cellular and subcellular localization of syntaxin-like immunoreactivity in the rat striatum and cortex.

Syntaxin is a synapse-specific protein previously localized to the plasma membrane of axon terminals. Biochemical and molecular biological studies indicate a prominent role for syntaxin 1A and 1B in synaptic vesicle docking and/or fusion, suggesting that these proteins are localized to active zone regions of most terminal varicosities in the central nervous system. We sought to test this hypothesis by examining the cellular and subcellular immunocytochemical localization of syntaxin 1 proteins in the striatum and frontal cortex of rats. Using either a polyclonal anti-syntaxin antibody, or a monoclonal antibody directed against the identical protein, HPC-1, immunoperoxidase reaction product was localized to preterminal axons and terminal varicosities that made almost exclusively Type I (asymmetric) synapses on dendritic spines or distal shafts. Immunoreactive terminals forming Type II (symmetric) synapses were observed rarely and only in tissue that was pretreated by rapid freeze-thaw to enhance antibody penetration. From a semi-quantitative analysis, it was estimated that at least 48-62% of all vesicle-filled varicosities and 67-69% of all terminals forming Type I synapses were immunoreactive for syntaxin or HPC-1, respectively. Using a pre-embedding immunogold-silver technique to provide a non-diffusible marker for subcellular localization, gold-silver particles for syntaxin or HPC-1 were localized to the cytoplasmic surface of non-synaptic portions of the plasma membrane of preterminal axons and terminal varicosities. Enrichment of presynaptic active zone regions was not observed with immunogold-silver staining. These findings suggest that syntaxin is primarily contained in a subpopulation of terminals that are associated with excitatory amino acid transmitters, but appears not to be ubiquitously expressed in all terminal classes. The results further indicate that syntaxin is localized to non-synaptic regions of axon and terminal membranes, but may not be enriched in presynaptic active zones. The apparent inconsistency between the subcellular localization of syntaxin and its proposed role in vesicle exocytosis is discussed in terms of possible technical limitations and alternative functions for syntaxin.

Ultrastructural localization of serotonin2A receptors in the middle layers of the rat prelimbic prefrontal cortex.

Cortical serotonin(2A) receptors are hypothesized to be involved in the pathology and treatment of schizophrenia. Light microscopic studies in the rat prefrontal cortex have localized serotonin(2A) receptors to the dendritic shafts of pyramidal and local circuit neurons. Electrophysiological studies have predicted that these receptors are also located on glutamate terminals, whereas neurochemical studies have hypothesized that they are located on dopamine terminals in this area. The present study sought to determine the ultrastructural localization of immunoperoxidase labeling for serotonin(2A) receptors in the middle layers of the prelimbic portion of the rat prefrontal cortex. Serotonin(2A) receptor immunoreactivity was observed in 325 identifiable structures. Of these, 73% were postsynaptic profiles that were composed of either dendritic shafts (58%) or dendritic spine heads and necks (42%). Twenty-four percent of the labeled profiles were presynaptic axons and varicosities; most of these had morphological features that were characteristic of monoamine axons: thin diameter, lack of myelination, occasional content of dense-cored vesicles, and infrequent formation of synapses in single sections. The remainder of the labeled profiles (4%) were glial processes. These findings suggest that serotonin(2A) receptor-mediated effects within the rat prelimbic prefrontal cortex are primarily postsynaptic in nature, affecting both the spines of pyramidal cells and the dendrites of pyramidal and local circuit neurons in this area. The results further suggest that serotonin acts presynaptically via this receptor subtype, most likely at receptors on monoamine fibers, and only rarely directly on glutamate axons.

Dopaminergic transmission in the rat retina: evidence for volume transmission.

The study was designed to determine whether dopaminergic neurotransmission in the retina can operate via volume transmission. In double immunolabelling experiments, a mismatch as well as a match was demonstrated in the rat retina between tyrosine hydroxylase (TH) and dopamine (DA) immunoreactive (ir) terminals and cell bodies and dopamine D2 receptor-like ir cell bodies and processes. The match regions were located in the inner nuclear and plexiform layers (D2 ir cell bodies plus processes). The mismatch regions were located in the ganglion cell layer, the outer plexiform layer, and the outer segment of the photoreceptor layer, where very few TH ir terminals can be found in relation to the D2 like ir processes. In similar experiments analyzing D1 receptor like ir processes versus TH ir nerve terminals, mainly a mismatch in their distribution could be demonstrated, with the D1 like ir processes present in the outer plexiform layer and the outer segment where a mismatch in D2 like receptors also exists. The demonstration of a mismatch between the localization of the TH terminal plexus and the dopamine D2 and D1 receptor subtypes in the outer plexiform layer, the outer segment and the ganglion cell layer (only D2 immunoreactivity (IR)) suggests that dopamine, mainly from the inner plexiform layer, may reach the D2 and D1 mismatch receptors via diffusion in the extracellular space. After injecting dopamine into the corpus vitreum, dopamine diffuses through the retina, and strong catecholamine (CA) fluorescence appears in the entire inner plexiform layer and the entire outer plexiform layer, representing the match and mismatch DA receptor areas, respectively. The DA is probably bound to D1 and D2 receptors in both plexiform layers, since the DA receptor antagonist chlorpromazine fully blocks the appearance of the DA fluorescence, while only a partial blockade is found after haloperidol treatment which mainly blocks D2 receptors. These results indicate that the amacrine and/or interplexiform DA cells, with sparse branches in the outer plexiform layer, can operate via volume transmission in the rat retina to influence the outer plexiform layer and the outer segment, as well as other layers of the rat retina such as the ganglion cell layer.