Pattern formation in the mammalian forebrain: patch neurons from the rat striatum selectively reassociate in vitro

Striatal Vulnerability in Huntington's Disease: Neuroprotection Versus Neurotoxicity

Huntington’s disease (HD) is an autosomal dominant neurodegenerative disease caused by the expansion of a CAG trinucleotide repeat encoding an abnormally long polyglutamine tract (PolyQ) in the huntingtin (Htt) protein. In HD, striking neuropathological changes occur in the striatum, including loss of medium spiny neurons and parvalbumin-expressing interneurons accompanied by neurodegeneration of the striosome and matrix compartments, leading to progressive impairment of reasoning, walking and speaking abilities. The precise cause of striatal pathology in HD is still unknown; however, accumulating clinical and experimental evidence suggests multiple plausible pathophysiological mechanisms underlying striatal neurodegeneration in HD. Here, we review and discuss the characteristic neurodegenerative patterns observed in the striatum of HD patients and consider the role of various huntingtin-related and striatum-enriched proteins in neurotoxicity and neuroprotection.

Distinct migratory behaviors of striosome and matrix cells underlying the mosaic formation in the developing striatum

The striatum, the largest nucleus of the basal ganglia controlling motor and cognitive functions, can be characterized by a labyrinthine mosaic organization of striosome/matrix compartments. It is unclear how striosome/matrix mosaic formation is spatially and temporally controlled at the cellular level during striatal development. Here, by combining in vivo electroporation and brain slice cultures, we set up a prospective experimental system in which we differentially labeled striosome and matrix cells from the time of birth and followed their distributions and migratory behaviors. Our results showed that, at an initial stage of striosome/matrix mosaic formation, striosome cells were mostly stationary, whereas matrix cells actively migrated in multiple directions regardless of the presence of striosome cells. The mostly stationary striosome cells were still able to associate to form patchy clusters via attractive interactions. Our results suggest that the restricted migratory capability of striosome cells may allow them to cluster together only when they happen to be located in close proximity to each other and are not separated by actively migrating matrix cells. The way in which the mutidirectionally migrating matrix cells intermingle with the mostly stationary striosome cells may therefore determine the topographic features of striosomes. At later stages, the actively migrating matrix cells began to repulse the patchy clusters of striosomes, presumably enhancing the striosome cluster formation and the segregation and eventual formation of dichotomous homogeneous striosome/matrix compartments. Overall, our study reveals temporally distinct migratory behaviors of striosome/matrix cells, which may underlie the sequential steps of mosaic formation in the developing striatum. J. Comp. Neurol. 525:794-817, 2017. © 2016 Wiley Periodicals, Inc.

Dynamic ordering of early generated striatal cells destined to form the striosomal compartment of the striatum

The mature striatum is divided into a labyrinthine system of striosomes embedded in a surrounding matrix compartment. We pulse-labeled striosomal cells (S cells) and matrix cells (M cells) in cats with (3) H-thymidine and followed their distributions during fetal and postnatal development. We identified three maturational phases in S-cell distributions. The early phase (sampled at embryonic day [E]27-E35 following E24-E28 (3) H-thymidine) was characterized by a transient medial accumulation of synchronously generated S cells within the caudate nucleus adjoining the ganglionic eminence, potentially a waiting compartment. Band-like arrangements of synchronously generated S cells then formed beyond this medial band. During the second phase (sampled at E38-E45), the loosely banded S-cell distributions were transformed into clustered arrangements typical of developing striosomes. In the third phase (sampled from E52 into the postnatal period), these developed into the typical mature striosomal architecture. At adulthood, gentle mediolateral birthdate-gradients in S cells were still evident, but M cells, produced over mid to late prenatal ages, became broadly distributed, without apparent gradients or banding arrangements. These findings suggest that the maturational histories of the striosomal and matrix neurons are influenced by their generation times and local environments, and that future S cells have transient, nonstriosomal distributions prior to their aggregation into striosomal clusters, including a putative waiting compartment. Further, the eventual patterning of the striosomal compartment reflects outside-in, band-like gradient patterns of settling of synchronously generated S cells, patterns that could be related both to neural processing in the mature striatum and to patterns of vulnerability of striatal neurons.

Temporal regulation of ephrin/Eph signalling is required for the spatial patterning of the mammalian striatum

Brain structures, whether mature or developing, display a wide diversity of pattern and shape, such as layers, nuclei or segments. The striatum in the mammalian forebrain displays a unique mosaic organization (subdivided into two morphologically and functionally defined neuronal compartments: the matrix and the striosomes) that underlies important functional features of the basal ganglia. Matrix and striosome neurons are generated sequentially during embryonic development, and segregate from each other to form a mosaic of distinct compartments. However, the molecular mechanisms that underlie this time-dependent process of neuronal segregation remain largely unknown. Using a novel organotypic assay, we identified ephrin/Eph family members as guidance cues that regulate matrix/striosome compartmentalization. We found that EphA4 and its ephrin ligands displayed specific temporal patterns of expression and function that play a significant role in the spatial segregation of matrix and striosome neurons. Analysis of the striatal patterning in ephrin A5/EphA4 mutant mice further revealed the requirement of EphA4 signalling for the proper sorting of matrix and striosome neuronal populations in vivo. These data constitute the first identification of genes involved in striatal compartmentalization, and reveal a novel mechanism by which the temporal control of guidance cues enables neuronal segregation, and thereby the generation of complex cellular patterns in the brain.

Roles of micro-opioid receptors in GABAergic synaptic transmission in the striosome and matrix compartments of the striatum

The striatum is divided into two compartments, the striosomes and extrastriosomal matrix, which differ in several cytochemical markers, input-output connections, and time of neurogenesis. Since it is thought that limbic, reward-related information and executive aspects of behavioral information may be differentially processed in the striosomes and matrix, respectively, intercompartmental communication should be of critical importance to proper functioning of the basal ganglia-thalamocortical circuits. Cholinergic interneurons are in a suitable position for this communication since they are preferentially located in the striosome-matrix boundaries and are known to elicit a conditioned pause response during sensorimotor learning. Recently, micro-opioid receptor (MOR) activation was found to presynaptically suppress the amplitude of GABAergic inhibitory postsynaptic currents in striosomal cells but not in matrix cells. Disinhibition of cells in the striosomes is further enhanced by inactivation of the protein kinase C cascade. We discuss in this review the possibility that MOR activation in the striosomes affects the activity of cholinergic interneurons and thus leads to changes in synaptic efficacy in the striatum.

Ctip2 controls the differentiation of medium spiny neurons and the establishment of the cellular architecture of the striatum

Striatal medium spiny neurons (MSN) are critically involved in motor control, and their degeneration is a principal component of Huntington's disease. We find that the transcription factor Ctip2 (also known as Bcl11b) is central to MSN differentiation and striatal development. Within the striatum, it is expressed by all MSN, although it is excluded from essentially all striatal interneurons. In the absence of Ctip2, MSN do not fully differentiate, as demonstrated by dramatically reduced expression of a large number of MSN markers, including DARPP-32, FOXP1, Chrm4, Reelin, MOR1 (mu-opioid receptor 1), glutamate receptor 1, and Plexin-D1. Furthermore, MSN fail to aggregate into patches, resulting in severely disrupted patch-matrix organization within the striatum. Finally, heterotopic cellular aggregates invade the Ctip2-/- striatum, suggesting a failure by MSN to repel these cells in the absence of Ctip2. This is associated with abnormal dopaminergic innervation of the mutant striatum and dramatic changes in gene expression, including dysregulation of molecules involved in cellular repulsion. Together, these data indicate that Ctip2 is a critical regulator of MSN differentiation, striatal patch development, and the establishment of the cellular architecture of the striatum.

Patch/matrix patterns of gray matter differentiation in the telencephalon of chicken and mouse

The mammalian striatum, a subpallial area, consists of two compartments (patches/striosomes and matrix) that differ in their neuronal birth dates, connectivity, neurochemistry, and molecular make-up. For example, members of the cadherin family of adhesion molecules (cadherin-8 and OL-protocadherin) are differentially expressed by the striosomes and the striatal matrix. A patch/matrix type of organization also has recently been found in the ventral hyperstriatum and the neostriatum of the chicken pallium, where cell clusters of similar birthdates ("isochronic" clusters) are surrounded by a matrix of cells that are born at a different time. Immunostaining with antibodies against cadherins reveals a similar arrangement of cell clusters. In the avian neostriatum, cadherin-7-positive cell clusters ("islands") are surrounded by a matrix of cells that express R-cadherin. The islands coincide, at least in part, with the isochronic cell clusters, as shown by pulse-labeling with bromodeoxyuridine. Likewise, isochronic clusters of the hyperstriatum ventrale relate to patchy heterogeneities in the cadherin-7 immunoreactivity pattern. Cadherins are known to mediate the aggregation and sorting of cells during development in many organs. Their differential expression by isochronic cell populations in the mammal subpallium and avian pallium suggests a common morphogenetic mechanism that regulates the formation of the patch/matrix patterns in these regions.

Changing distribution patterns of synaptophysin-immunoreactive structures in the human dorsal striatum of the fetal brain

Within the striatum two compartments, matrix and patches, can be distinguished by differences in the expression of neuroactive substances, afferent and efferent connections and time of neurogenesis. The present study was done to demonstrate the pattern of synaptophysin (SYN) expression which is indicative of synaptogenesis in the human fetal striatum (15th-32nd weeks of gestation) with special reference to developmental changes. From the 15th to the 22nd gestational weeks an intense diffuse SYN immunolabelling of striatal patches is observed. In the matrix SYN-immunoreactive fiber bundles are seen until the 20th week. Thereafter, the matrix is nearly devoid of SYN-immunoreactive structures. From the 28th week of gestation the matrix contains diffuse SYN immunoreactivity which gradually becomes as intense as that of the patches. The latter, thus, can no longer be delineated in the 30th week. The results show that fibrous SYN immunolabelling most probably indicating intra-axonal transport of synaptic vesicles can only be observed during the first half of gestation. Moreover, it becomes obvious that the patch compartment can selectively be visualized by anti-SYN until the 28th week. This pattern may correspond to the early dopaminergic innervation from the substantia nigra which is known to reach the developing patches. From the 28th week a transition from patchy to diffuse immunolabelling is seen. The increase in matrix labelling may be due to the occurrence of new neuronal contacts. The changeover from patchy to homogeneous SYN immunolabelling takes place distinctly earlier than changes in the distribution of other neuroactive substances described before.

Heterogeneity of cadherin-8 expression in the neonatal rat striatum: comparison with striatal compartments

Mechanisms of organization of the striatal compartments are poorly understood, although involvement of cell adhesion molecules in the compartmentalization has been suggested. Cadherin-8 distribution in the neonatal rat striatum was immunohistochemically studied using a rabbit anti-cadherin-8 antiserum. Intensity of cadherin-8 immunolabeling in the striatum was heterogeneous from postnatal day 0 to postnatal day 7. At postnatal day 9, cadherin-8 immunoreactivity was so weak that heterogeneity was no longer clearly seen. Cadherin-8 immunoreactivity was not detectable at postnatal day 14. Cadherin-8-rich and cadherin-8-poor areas were identical to calbindin-rich areas and tyrosine hydroxylase-rich patches, respectively, in allocation, indicating that cadherin-8 was predominantly expressed in the striatal matrix. These results suggest that cadherin-8 is involved in formation of the striatal compartmentalized structures during brain development.

Mosaic distribution of chondroitin and keratan sulphate in the developing rat striatum: possible involvement of proteoglycans in the organization of the nigrostriatal system

The striatum of the mammalian basal ganglia is composed of two neurochemically distinct compartments termed patches and matrix that contribute overall to a mosaic organization. Glycosaminoglycans (GAGs), the sugar moieties of proteoglycans, provide specific spatio-temporal guidance cues during the development of several functional neural systems. However, their distribution within the nigrostriatal system has not been investigated yet. Here, the immunohistochemical distributions of unsulphated (C0S), 4-sulphated (C4S) and 6-sulphated chondroitin (C6S) and keratan sulphate (KS) were examined in the developing neostriatum of rat and compared with the distribution of dopaminergic terminals. All the chondroitin sulphate (CS) isomers are homogeneously expressed in the embryonic striatum. After birth, C0S and C6S reveal the striatal mosaic in being preferentially expressed within the matrix compartment and in boundaries around patches whereas the C4S epitope is present in both compartments, with a slight patchy distribution. KS expression is detected first in the patches during the early postnatal period and subsequently only in the matrix compartment. All these GAG expressions disappear as the brain matures except for C4S which remains high throughout adult life. Furthermore, studies within the developing medial forebrain bundle reveal that CS isomers, but not KS, are expressed in and around the dopamine axonal tract but show similar developmental patterns of distribution which do not appear to be specifically associated with the nigrostriatal pathway. These results suggest a possible implication of proteoglycans during the development of the striatum and may be useful for understanding the complex cellular and molecular interactions in degeneration and plasticity of the nigrostriatal circuit in Parkinson's disease.

Opioid receptor gene expression in the rat brain during ontogeny, with special reference to the mesostriatal system: an in situ hybridization study

The three main types of opioid receptors micro, delta and kappa are found in the central nervous system and periphery. In situ hybridization study was undertaken to determine the expression of mu, delta, kappa-opioid receptors mRNAs in the brain during pre- and postnatal development, especially in the mesostriatal system. By G13, mu and kappa-opioid receptor mRNA were detectable in the telencephalon; mu-opioid receptor mRNA was found in the striatal neuroepithelium and cortical plate and kappa-opioid receptor mRNA in the corroidal fissure. By G15, kappa-opioid receptor mRNA was detectable in the nucleus accumbens and dorsal striatum, and in the substantia nigra and ventral tegmental area, suggesting an early expression of the corresponding receptor on dopaminergic terminal fibers. For the mu-opioid receptor mRNA in the striatum, patches appeared at G20. Delta-opioid receptor mRNA was first detected at G21, in many areas including the accumbens nucleus and the dorsal striatum. At P8, delta-opioid receptor mRNA was detected in large-sized cells of the striatum, possibly cholinergic, suggesting a possible modulation by opioids of the striatal cholinergic neurons. Our results demonstrate the early appearance of mu and kappa-opioid receptor mRNA (G13) and the relatively late development of delta-opioid receptor mRNA (G21) in the brain. We also show a distinct pattern of expression for mu, delta and kappa-opioid receptor mRNAs in the mesostriatal system during the development.

Striatal cholinergic interneurons: birthdates predict compartmental localization

The striatal patch and matrix compartment neurons are born at different times during rat development. The majority of the early born neurons preferentially end up in the patch compartment, while the majority of the later born neurons end up in the matrix compartment. Although the cholinergic interneurons are all born early in neurogenesis (between embryonic day E12 and E17), and we would therefore expect them to be located mainly in the patches, they are relatively homogeneously distributed in the adult, with a preference for the matrix area just outside the patches (the intermediate zone). To ask if birthdate can predict the compartmental localization of cholinergic neurons in the striatum, we marked new postmitotic neurons in the embryo with a maternal injection of bromodeoxyuridine (BrdU) on E13, E15 or E17 and labeled the patch compartment with an injection of the retrograde tracer True Blue into the substantia nigra on postnatal day (P) 1. The pups were sacrificed at P40 and the tissue was processed for BrdU, choline acetyltransferase, and True Blue triple labeling. Cholinergic neurons that became postmitotic at E13, had a higher chance of ending up in the patch compartment compared to either the intermediate zone or the rest of the matrix compartment. On the other hand cholinergic neurons that became postmitotic at E17 had a higher chance of ending up in the matrix compartment (including the intermediate zone). We conclude that birthdate can predict compartmental localization, with the cholinergic neurons in the intermediate zone following the same pattern as the cholinergic neurons in the rest of the matrix compartment. Cholinergic neurons show the same relative birthdate/compartment relationship as do other striatal neurons, although the absolute birthdates of cholinergic neurons are shifted earlier in neurogenesis.

The neostriatal mosaic: basis for the changing distribution of neurokinin-1 receptor immunoreactivity during development

The pattern of neurokinin-1 receptor-like immunoreactivity (NK-1Rir) was mapped in perinatal and adult mouse striatum by using a new polyclonal antiserum. NK-1Rir was detected in the differentiating regions of the ganglionic eminences on embryonic day 12.5 (E12.5). NK-1Rir structures were enriched in the striatal patch compartment between E16.5 and approximately postnatal day 3 (P3); distributed more uniformly, within portions of both the patch and matrix compartments on P7; and enriched in the matrix compartment in the adult. Analysis of the phenotype of NK-1Rir cells on P2, P7, and in the adult suggested that cholinergic cells accounted for the majority of NK-1Rir cells early postnatally, with increasing contributions from somatostatinergic cells later postnatally. In the adult, approximately half of NK-1Rir cells were cholinergic and half were somatostatinergic. The transient enrichment of NK-1R-bearing cells and processes in the patch compartment which contains cells that express substance P (SP), a putative ligand for the NK-1R, may be a consequence of compartment formation or may be functionally important for compartment development.

Differential maturation of cholinergic interneurons in the striatal patch versus matrix compartments

Striatal neurons are generated in two distinct phases. Neurons that become postmitotic early in embryonic development come to be located primarily in the patch compartment of the striatum, while the majority of the neurons situated in the striatal matrix compartment are generated later in embryogenesis. The cholinergic interneurons in the striatum, which have been reported to be more or less homogeneously distributed in the adult, are all generated early in development. Given that early generated neurons are expected to be situated primarily in the patch compartment, we investigated the apparently homogeneous distribution of cholinergic neurons by analysing their localizations in the patch and matrix compartments during striatal development. To selectively mark the striatal patch compartment we made injections of the retrograde fluorescent tracer True Blue in the substantia nigra on embryonic day 20 or postnatal day (P)1, and then stained for cholineacetyltransferase (ChAT) at different time-points in development. After P7, the distribution of the ChAT positive neurons changes from an earlier preference for the patch compartment to a preference for an area of the matrix just outside of the patches. Absolute counts show that this change in distribution is caused mainly by a late turn on of ChAT by the cholinergic neurons in the matrix compartment. These data suggest that there are different compartmental subpopulations of cholinergic neurons in the striatum.

The development of striatal patch/matrix organization after prenatal methylazoxymethanol: a combined immunocytochemical and bromo-deoxy-uridine birthdating study

The antimitotic drug methylazoxymethanol was used to destroy striatal patch neurons during their three-day-period of neurogenesis in the rat. Single or multiple injections of methylazoxymethanol were given during embryonic days 13-15, the period when patch neurons are known to undergo their final cell division. Methylazoxymethanol treatments produced a dramatic reduction in striatal volume. Immunocytochemical analysis revealed the continued presence of patches of neurons that were substance P-immunoreactive and devoid of calbindin and enkephalin immunoreactivity. Both the number of patches and relative volume occupied by patches was reduced in methylazoxymethanol-treated striata. Patch neurons could also be labelled by an intrastriatal injection of FluoroGold during the first postnatal week. The early ingrowth of nigrostriatal dopamine afferents was less noticeably patchy in the methylazoxymethanol-treated animals, in part owing to an overall increase in density. Large reductions in the number of neurons immunoreactive for choline acetyltransferase were observed, whereas NADPH diaphorase-stained neurons were not reduced unless methylazoxymethanol was given on embryonic day 15. Injections of bromo-deoxy-uridine, either during or after the 24 h that each methylazoxymethanol injection was considered to be effective, revealed that (i) some patch neurons continued to be generated in the 24-h period following methylazoxymethanol administration, and (ii) many patch neurons were generated after the effects of methylazoxymethanol had worn off. These findings demonstrate that it was impossible to completely eliminate the patches using methylazoxymethanol injections during the period of patch neurogenesis. However, methylazoxymethanol treatment during this time did produce a dramatic loss of cells and a relatively greater reduction in patch volume. Despite this disruption, the appropriate compartmentalization of neuroactive substances appeared to be maintained.

Dopaminergic control of gene transcription during striatal ontogeny: c-fos induction by D1 receptor activation in the developing striosomes

During striatal development, dopamine afferents initially reach the striosomal compartment, and this early dopamine innervation is thought to influence, through the D1 receptors first expressed in the developing patches, the phenotype of target striatal cells. Dopaminergic control of gene expression during ontogeny could be mediated by transcription factors such as c-fos, whose expression is regulated by synaptic signals. However, in the striatum of intact adult animals, D1 dopamine agonists fail to induce c-fos expression. The c-fos response to D1 receptor activation in adults requires a previous sensitization of dopaminergic receptors by chronic treatment with reserpine or by lesion of the nigro-striatal pathway. In this work, we investigated through in situ hybridization the ability of striatal cells to express c-fos messenger RNA (mRNA) in response to the D1 agonist SKF 38393 (4 to 8 mg/kg) in developing mice. During a transient postnatal period, c-fos expression in a patchy distribution was induced by D1 receptor activation: only a faint response was detected on postnatal day 1, but islands of strong hybridization signals for c-fos mRNA in response to the D1 agonist were observed at postnatal day 3, with a progressive decrease in intensity from day 6 to day 15. The distribution of this transient c-fos response corresponded to the early striosomal compartment since it matched with the regions of intense mu-opioid and dopamine-D1 receptor binding, as assessed by autoradiography performed on adjacent sections. By day 21, as in adult animals, no more c-fos response to D1 agonists was observed, except in the most caudal division of the striatum. Strong expression, which persisted into adulthood, was detected in this region from the third postnatal day. This induction of striatal c-fos expression by D1 agonists during early postnatal development is indicative of an enhanced sensitivity of D1 receptors or of D1-associated transduction pathways compared to the adult pattern, and suggests a possible role for dopamine-controlled c-fos gene expression in the development of target striatal neurons during this critical period.

Pattern formation in the mammalian forebrain: striatal patch and matrix neurons intermix prior to compartment formation

The striatum of the mammalian forebrain is divided into two compartments: the patches and the matrix. Neurons of the patch compartment in the rat striatum become postmitotic earlier in neurogenesis than neurons of the matrix compartment. The selective adhesion of patch neurons to one another has been suggested previously to be an important developmental mechanism of striatal compartmentation. We asked if the selective adhesion of patch neurons is expressed before or after the migration of the majority of the matrix neurons into the striatum. Patch neurons were labelled in vivo by a fluorescent retrograde tracer injected into the substantia nigra on embryonic day 19, which almost exclusively labelled patch neurons. Matrix neurons were labelled with a maternal injection of bromodeoxyuridine at embryonic day 18. When animals were killed at embryonic day 20, the majority of the retrogradely labelled patch neurons were intermixed with the bromodeoxyuridine-labelled matrix neurons, although there appeared to be clustering of some of the patch neurons. However, by postnatal day 2 there was a complete segregation of the clusters of the retrogradely labelled patch neurons from the bromodeoxyuridine-labelled matrix neurons in the striatum. This process was modelled in vitro. The patch and matrix compartments were labelled in vivo at embryonic day 13 and 18 respectively, with different birthdate markers ([3H]thymidine or bromodeoxyuridine). At embryonic day 20 the striatal tissue was removed, dissociated and reaggregated in suspension cultures. After 1 day in vitro, labelled patch and matrix neurons were randomly intermixed within the reaggregates. Examination of the cultures at 2.5 and 4 days in vitro revealed clumping of the labelled patch neurons towards the centres of the reaggregates. Over this same period, the labelled matrix neurons did not clump and were dispersed towards the periphery of the reaggregates. The results suggest that patch neuron adhesiveness may appear relatively soon after these neurons become postmitotic, but that this adhesiveness is unable to overcome the initial force produced by the massive migration of matrix neurons into the striatum. We hypothesize that a migratory phase of embryonic striatal development exists, when fated patch and matrix neurons intermix. After this migratory phase, patch neuron adhesiveness can produce the mature segregation of the striatal compartments.

Spatially localized neuronal cell lineages in the developing mammalian forebrain

The role of cell lineage in the organization of the cerebral cortex and striatum of the developing rat forebrain was analysed using retroviral-mediated gene transfer to mark the progeny of individual progenitors. Injections around the onset of neurogenesis (embryonic day 14) produced neuronal- and glial-specific clones in the striatum and cortex. The majority of the neuronal clones were restricted to either the deep or superficial layers of the cortex and to either the striatal patch or matrix compartments of the striatum. Moreover, modeling the distributions of the neuronal clones in various ways revealed that grouping the clones into deep vs superficial cortical compartments and patch vs matrix striatal compartments best accounted for the clone distributions. These results suggest that at the onset of neurogenesis there is a heterogeneity of neuronal progenitors within the proliferative ventricular zone.

Organotypic slice cultures of the rat striatum--I. A histochemical and immunocytochemical study of acetylcholinesterase, choline acetyltransferase, glutamate decarboxylase and GABA

Slices of striatal tissue from newborn to eight-day-old rats were cultured for six to 47 days. Cholinergic neurons and fibres were then visualized by histochemical staining for acetylcholinesterase or immunocytochemical staining for choline acetyltransferase. GABA-containing neurons and fibres were visualized by immunocytochemical staining for glutamate decarboxylase or GABA. Corresponding to the normal postnatal development in vivo, acetylcholinesterase staining of the striatal tissue progressed from a "patchy" distribution in the six to 14 days old cultures to an almost even distribution of high acetylcholinesterase activity after 18-27 days. Extrinsic afferents were accordingly not necessary for the maintenance of a patch-matrix-like, acetylcholinesterase distribution during the first one to two weeks in culture, just as a subsequent, normal developmental change of the acetylcholinesterase staining pattern into a more homogeneous distribution also occurred without such afferents. Cholinergic, choline acetyltransferase-immunoreactive neurons were evenly distributed within the cultured striatal tissue, like in vivo, but the density of the neurons appeared to be higher in the cultures. The neurons had a morphology corresponding to the "classical", large-sized, aspiny, cholinergic interneurons in the adult rat striatum. Glutamate decarboxylase-immunoreactive and GABA-immunoreactive neurons were either lightly or darkly stained and of medium size, but some large, lightly stained glutamate decarboxylase-immunoreactive and GABA-immunoreactive neurons were also found. The difference in staining density among the medium-sized cells was observed with both antisera and hence provide evidence for the existence of two populations of medium-sized GABAergic neurons, which in vivo are intensely stained interneurons and more weakly stained, spiny projection neurons. Fibres stained better for glutamate decarboxylase than for GABA and outgrowth of glutamate decarboxylase-immunoreactive nerve fibres from the striatal slice cultures onto the coverslip was often observed. The presence at all culture periods of "protospines" on cell bodies and proximal dendrites of some glutamate decarboxylase-immunoreactive, and in particular some GABA-immunoreactive neurons, suggested that at least some developmental characteristics might be maintained for extended periods in culture. In several cultures, groups of small GABA-immunoreactive cells were observed. Similar groups were also found by staining for glutamate decarboxylase, but a smaller proportion of the cells were then positively stained. In view of their immature appearance with few or no processes, the known presence of GABA in neuroblast-like cells, and the recent demonstration of neuronal and glial progenitor cells in the adult mouse striatum, the small cells might belong to a population of undifferentiated cells surviving in the slice cultures.(ABSTRACT TRUNCATED AT 400 WORDS)

Ontogeny of the proenkephalin system in the rat corpus striatum: its relationship to dopaminergic innervation and transient compartmental expression

The earliest detection of the proenkephalin gene was on embryonic day 16 in neuronal cell bodies in the ventrolateral portion of the caudal neostriatum. This expression was identified by both immunocytochemistry for synenkephalin, the nonopioid N-terminus of proenkephalin (1-70), and preproenkephalin in situ hybridization with a complementary DNA probe. Two developmental gradients of preproenkephalin expression and synenkephalin immunoreactivity were observed: (i) a ventrolateral to dorsomedial and caudal to rostral gradient in the rostral caudate-putamen; and (ii) a ventromedial to dorsolateral and rostral to caudal gradient in the caudal caudate-putamen. Ventrolateral to dorsomedial and caudal to rostral developmental gradients of synenkephalin fiber immunoreactivity were also identified in the globus pallidus. Methionine enkephalin immunoreactivity was not consistently detectable until postnatal day 10 and 15 in the rostral and caudal globus pallidus, respectively. A transient patchy distribution of increased preproenkephalin expression from embryonic day 20 through postnatal day 5 occurred. These patches and a subcallosal streak were found to overlap partially with areas of increased tyrosine hydroxylase immunoreactivity by adjacent section analyses. The earliest detection of tyrosine hydroxylase immunoreactivity was found to coincide with that of proenkephalin on embryonic day 16, but in differing regions of the corpus striatum. Tyrosine hydroxylase immunoreactivity in the rostral caudate-putamen preceded, while in the caudal caudate-putamen it followed first expression of the proenkephalin gene. Early proenkephalin expression, by both synenkephalin immunocytochemistry and preproenkephalin in situ hybridization, was also detected in the central nucleus of the amygdala on embryonic day 16 immediately ventral to the area of expression in the caudate-putamen. Preproenkephalin expression in the olfactory tubercle and nucleus accumbens first appeared on embryonic day 20 and expression proceeded in a lateral to dorsomedial gradient continuous with the ventral part of the rostral caudal-putamen. Relatively late detection of methionine enkephalin immunoreactivity in comparison to synenkephalin possibly indicates a developmental delay in the complete enzymatic processing of the proenkephalin precursor. Differing gradients in the ontogeny of preproenkephalin expression in the rostral vs the caudal caudate-putamen suggest possible anatomical and developmental differences of these two regions. Also, transient compartmentalization of preproenkephalin expression and differences in dopaminergic innervation as detected by tyrosine hydroxylase immunoreactivity were further support for the existence of two subsets of proenkephalinergic neurons in the caudate-putamen. Contemporaneous development of preproenkephalin expression and synenkephalin immunoreactivity in the central nucleus of the amygdala with the ventral part of the caudal caudate-putamen also suggested developmental homology.(ABSTRACT TRUNCATED AT 400 WORDS)

Embryonic lesions of the substantia nigra prevent the patchy expression of opiate receptors, but not the segregation of patch and matrix compartment neurons, in the developing rat striatum

Unilateral lesions of the substantia nigra on embryonic day 19 prevent the development of the normal patchy distribution of opiate receptors in the ipsilateral rat striatum. Independent, early and permanent labelling of patch compartment neurons in the same brains on embryonic day 14 with [3H]thymidine revealed that the substantia nigra lesions did not prevent the aggregation of early born neurons into patches, but rather blocked the normal expression of one phenotype (dense opiate receptor binding) of these patches. Thus, early nigrostriatal connections may not be critical for the fundamental patch/matrix compartmentation of the striatum, but may be important in the maturation of phenotypic markers of these compartments.

Afferent-boundary interactions in the developing neostriatal mosaic

The caudate-putamen (neostriatum) of the mammalian basal ganglia is composed of two neurochemically distinct compartments termed patch (island, striosome) and matrix that overall contribute to a mosaic organization. In the present study, the distribution of the developmentally regulated extracellular matrix molecule tenascin, as well as several other neural cell adhesion molecules, was examined in the neostriatal mosaic of the early postnatal mouse and compared with tyrosine hydroxylase distribution following partial destruction of the dopaminergic nigrostriatal projection. During normal neostriatal development, tenascin is most dense within the matrix compartment and highly concentrated in boundaries around patches. This pattern is apparent on embryonic day 18, and for the most part disappears by postnatal day 12. Tenascin immunoreactivity is altered in the neostriatum following lesions of the nigrostriatal pathway in the first postnatal week revealed by an overall reduced expression of this molecule and a marked reduction in tenascin staining of boundaries at the interface of tyrosine hydroxylase-rich patch and tyrosine hydroxylase-poor matrix compartments. When compared to tyrosine hydroxylase immunoreactivity, other cell adhesion molecules tested failed to show altered intensities and patterns of immunoreactivity within the neostriatum after similar lesions. Reduced levels of tenascin in the lesioned neostriatum, in register with altered levels of tyrosine hydroxylase immunostaining of dopaminergic inputs, suggests that axons may affect the expression of particular recognition molecules in their target structures. The fact that boundaries are malleable can be related to afferent-induced plastic events in the differentiation of cellular elements in the developing nigrostriatal system.

Relationships between neuronal birthdates and cytoarchitecture in the rat inferior olivary complex

The correlation between birthdates of neurons and their ultimate location within the inferior olivary nucleus (ION) was investigated in the rat by the 5-bromodeoxyuridine (BrdU) method. We performed injections every 4 hours throughout the ION generation period, and were thus able to demonstrate that 1) neurons are distributed in the adult ION following characteristic gradients that define subdivisions identical to those established by hodological studies; and 2) ION neurons born at the same time tend to be arrayed in small clusters in the adult structure. Implications of these findings for the mechanisms of olivary neuron migration, selective aggregation, and elaboration of projectional topography are discussed. This study provides direct evidence that one of the factors governing the elaboration of the cytoarchitecture of a neuronal nucleus is the temporal sequence of generation of its neurons.

Mechanisms of striatal pattern formation: conservation of mammalian compartmentalization

The striatum is composed of two neuroanatomically and neurochemically defined compartments, termed the patches and matrix. We compared this compartmentalization of the striatum in sections from the rat, rhesus monkey and human, in terms of (1) total striatal area, (2) the ratio of patch to matrix areas, (3) the number of patches and (4) the cross-sectional area of individual patches. Dense mu-opiate receptor binding and immunohistochemical staining for enkephalin were used as histochemical markers for the patch compartment and heavy immunostaining for calcium binding protein was used as a matrix marker. Analysis of coronal sections revealed that a relatively constant ratio of 15% patch to 85% matrix area is maintained in each species. The numbers of patches also remain relatively constant across species, despite a 19-fold increase in total striatal area from rat to human. The constant ratio of patch to matrix areas is maintained by an increase in the size of the individual patches. We hypothesize that the maintenance of a 15% patch to 85% matrix ratio in the striata of different mammalian species occurs through proportionate changes in the length of striatal neurogenesis and the numbers of striatal precursors in the ventricular zone, whereas the maintenance of average patch number is proposed to be a function of reciprocal connections with the substantia nigra and adhesive factors that are specific to patch cells.

Neuronal lineages in chimeric mouse forebrain are segregated between compartments and in the rostrocaudal and radial planes

On the basis of neuronal phenotypes and the mode of development of the mammalian forebrain, the cerebral cortex can be subdivided into deep versus superficial layers, and the striatum into patch versus matrix compartments. Interspecific chimeric Mus musculus----Mus caroli mice were used to determine the contribution of lineage to cellular position within these forebrain compartments. Statistical analysis revealed evidence of both spatial and compartmental lineage segregation. A significant difference in genotype ratio depending on chimeric specimen was observed between areas (regardless of compartment) that were separated by greater than 300 microns in the rostrocaudal plane. Differences were observed between early-born (striatal patch and deep cortex) versus late-born (striatal matrix and superficial cortex) neurons, but not between neurons of cortex as a whole versus neurons of striatum as a whole. The difference between early- and late-born neurons was primarily due to the difference between deep and superficial cortical neurons. On a finer scale of analysis, differences in genotype ratios were seen between radially aligned deep versus superficial cortical compartments, in both the neuronal and glial populations. This evidence is consistent with an early positional and compartmental segregation of forebrain progenitor cells.