The regional and cellular distribution of GABAA receptor subunits in the human amygdala.

GABAergic neurotransmission in the amygdala plays a crucial role in mediating emotional learning, fear, and memory. In this study, expression of five major GABAA receptor subunits (α1, α2, α3, ß2,3, and γ2) was investigated in the normal human amygdala using immunohistochemistry. At the regional level, the amygdala contains a highly heterogeneous distribution of all the subunits investigated. The most intense staining for α1, α2, ß2,3, and γ2 subunits was present in the lateral nucleus (LA), and α3 in the intercalated nuclei (ICM). Six distinct cell populations that express GABAA receptor subunits were identified throughout the amygdala: type 1 aspiny cells in the basolateral nuclear group (BLNG) and superficial cortical-like nuclear region (SCLR) express α1, ß2,3, and γ2; type 2 larger aspiny cells in the paralaminar nucleus (PL) express α1, ß2,3, and γ2; type 3 aspiny cells in the BLNG express α1, ß2,3, and γ2 as well as calcium-binding proteins including parvalbumin (PV), calbindin (CB), and calretinin (CR); type 4 pyramidal cells in the BLNG and SCLR express α2, α3, ß2,3, and γ2 subunits at high levels on proximal specialised spines; type 5 cells in the central nucleus (CE) express α2, α3, and ß2,3; type 6 cells are found closely packed in the intercalated cell masses (ICM) and express α3 and ß2,3. The α1 subunit rarely co-labelled with α2 and α3 in the same cell population, while the α2 and α3 were often expressed within the same type 4 or 5 cell though not at always at the same puncta. The predominant GABAA receptor subunit combinations expressed in the human amygdala are the α1ß2,3γ2 and α2ß2,3γ2. Cells classified as interneuron types (types 1-3) contained GAD and principally expressed α1ß2,3γ2. The major projection neurons of the BLNG (type 4) are non-GABAergic and mainly express α2ß2,3γ2. The α3 subunit was found intracellularly in type 5 cells and decorating the surface of type 6 cells but rarely co-labelled with the subunits investigated. The results reveal a complex and heterogeneous distribution of GABAA receptor subtypes throughout the amygdala as well as on a variety of cell types through which inhibitory processing is carried out to maintain emotional responses, and control anxiety and fear responses in the brain.

mGluR1α expression in the hippocampus, subiculum, entorhinal cortex and superior temporal gyrus in Alzheimer's disease.

Glutamate is the main excitatory neurotransmitter in the central nervous system, responsible for a plethora of cellular processes including memory formation and higher cerebral function and has been implicated in various neurological disease states. Alzheimer's disease (AD) is the leading neurodegenerative disorder worldwide and is characterized by significant cell loss and glutamatergic dysfunction. While there has been a focus on ionotropic glutamatergic receptors few studies have attempted to elucidate the pathological changes of metabotropic glutamate receptors (mGluRs) in AD. mGluRs are G-protein coupled receptors which have a wide-ranging functionality, including the regulation of neuronal injury and survival. In particular, the group I mGluRs (mGluR1 and mGluR5) are associated with ionotropic receptor activation and upregulation with resultant glutamate release in normal neuronal functioning. The mGluR subtype 1 splice variant a (mGluR1α) is the longest variant of the mGluR1 receptor, is localized to dendritic processes and is mainly plasma membrane-bound. Activation of mGluR1a has been shown to result in increased constitutive activity of ionotropic receptors, although its role in neurodegenerative and other neurological diseases is controversial, with some animal studies demonstrating potential neuroprotective properties in excito- and neurotoxic environments. In this study, the expression of mGluR1a within normal and AD human hippocampal tissue was quantified using immunohistochemistry. We found a significantly reduced expression of mGluR1α within the stratum pyramidale and radiatum of the CA1subregion, subiculum, and entorhinal cortex. This downregulation could result in potential dysregulation of the glutamatergic system with consequences on AD progression by promoting excitotoxicity, but alternatively may also be a neuroprotective mechanism to prevent mGluR1α associated excitotoxic effects. In summary, more research is required to understand the role and possible consequences of mGluR1α downregulation in the human AD hippocampus, subiculum and entorhinal cortex and its potential as a therapeutic target.

The localization of inhibitory neurotransmitter receptors on dopaminergic neurons of the human substantia nigra.

The substantia nigra pars compacta (SNc) is comprised mainly of dopaminergic pigmented neurons arranged in groups, with a small population of nonpigmented neurons scattered among these groups. These different types of neurons possess GABAA, GABAB, and glycine receptors. The SNc-pigmented dopaminergic neurons have postsynaptic GABAA receptors (GABAAR) with a subunit configuration containing alpha3 and gamma2 subunits, with a small population of pigmented neurons containing alpha1 beta2,3 gamma2 subunits. GABAB receptors comprised of R1 and R2 subunits and glycine receptors are also localized on pigmented neurons. In contrast, nonpigmented (mainly parvalbumin positive neurons) located in the SNc are morphologically and neurochemically similar to substantia nigra pars reticulata (SNr) neurons by showing immunoreactivity for parvalbumin and GABAARs containing immunoreactivity for alpha1, alpha3, beta2,3, and gamma2 subunits as well as GABAB R1 and R2 subunits and glycine receptors. Thus, these two neuronal types of the SNc, either pigmented dopaminergic neurons or nonpigmented parvalbumin positive neurons, have similar GABAB and glycine receptor combinations, but differ mainly in the subunit composition of the GABAARs located on their membranes. The different types of GABAARs suggest that GABAergic inputs to these neuronal types operate through GABAARs with different pharmacological and physiological profiles, whereas GABABR and glycine receptors of these cell types are likely to have similar properties.

Variable colocalisation of GABAA receptor subunits and glycine receptors on neurons in the human hypoglossal nucleus.

The hypoglossal nucleus, the nucleus of the twelfth cranial nerve, is located dorsally in the midline of the medulla oblongata. The hypoglossal nucleus contains lower motor neurons which innervate the tongue muscles that control tongue movements involved in speech production, swallowing, mastication and associated respiratory movements. GABAA and glycine receptors are heteropentameric ionotropic receptors that facilitate fast-response, inhibitory neurotransmission in the mammalian brain and spinal cord. We investigated the immunohistochemical distribution of the GABAA receptor α1, α2, ß2,3 subunits and glycine receptors as well as their relationship to the vesicular GABA transporter (VGAT) in the human hypoglossal nucleus at the light and confocal laser scanning microscope levels. The results showed that all of the GABAA receptor subunits as well as glycine receptor display punctate labelling indicative of synapses on the soma and dendritic membranes of large neurons within the hypoglossal nucleus. On average, approximately 50% of glycine receptors were co localised with GABAA receptor α1 subunits. Also on average GABAA α2 and ß2,3 subunits were colocalised with approximately 30% of glycine receptor subunits. VGAT positive terminals were associated with both GABAA and glycine receptor types. Both glycinergic and GABAergic positive puncta were found adjacent to VGAT terminal-like staining. These results suggest that inhibition of human hypoglossal motor neurons occurs not only through complex interaction of separated GABAAR and glycine receptor regions, but also through synapses containing both inhibitory receptor types co-existing at the same synaptic sites.

Doublecortin expression in the normal and epileptic adult human brain.

Mesial temporal lobe epilepsy (MTLE) is a neurological disorder associated with spontaneous recurrent complex partial seizures and hippocampal sclerosis. Although increased hippocampal neurogenesis has been reported in animal models of MTLE, increased neurogenesis has not been reported in the hippocampus of adult human MTLE cases. Here we showed that cells expressing doublecortin (Dcx), a microtubule-associated protein expressed in migrating neuroblasts, were present in the hippocampus and temporal cortex of the normal and MTLE adult human brain. In particular, increased numbers of Dcx-positive cells were observed in the epileptic compared with the normal temporal cortex. Importantly, 56% of Dcx-expressing cells in the epileptic temporal cortex coexpressed both the proliferative cell marker, proliferating cell nuclear antigen and early neuronal marker, TuJ1, suggesting that they may be newly generated neurons. A subpopulation of Dcx-positive cells in the epileptic temporal cortex also coexpressed the mature neuronal marker, NeuN, suggesting that epilepsy may promote the generation of new neurons in the temporal cortex. This study has identified, for the first time, a novel population of Dcx-positive cells in the adult human temporal cortex that can be upregulated by epilepsy and thus, raises the possibility that these cells may have functional significance in the pathophysiology of epilepsy.

Differential localization of GABAA receptor subunits within the substantia nigra of the human brain: an immunohistochemical study.

Gamma-aminobutyric acid(A) (GABA(A)) receptors (GABA(A)R) are inhibitory heteropentameric chloride ion channels comprising a variety of subunits and are localized at postsynaptic sites within the central nervous system. In this study we present the first detailed immunohistochemical investigation on the regional, cellular, and subcellular localisation of alpha(1), alpha(2), alpha(3), beta(2,3), and gamma(2) subunits of the GABA(A)R in the human substantia nigra (SN). The SN comprises two major regions, the SN pars compacta (SNc) consisting of dopaminergic projection neurons, and the SN pars reticulata (SNr) consisting of GABAergic parvalbumin-positive projection neurons. The results of our single- and double-labeling studies demonstrate that in the SNr GABA(A) receptors contain alpha(1), alpha(3), beta(2,3), and gamma(2) subunits and are localized in a weblike network over the cell soma, dendrites, and spines of SNr parvalbumin-positive nonpigmented neurons. By contrast, GABA(A)Rs on the SNc dopaminergic pigmented neurons contain predominantly alpha(3) and gamma(2) subunits; however there is GABA(A)R heterogeneity in the SNc, with a small subpopulation (6.5%) of pigmented SNc neurons additionally containing alpha(1) and beta(2,3) GABA(A)R subunits. Also, in the SNr, parvalbumin-positive terminals are adjacent to GABA(A)R on the soma and proximal dendrites of SNr neurons, whereas linear arrangements of substance P-positive terminals are adjacent to GABA(A) receptors on all regions of the dendritic tree. These results show marked GABA(A)R subunit hetereogeneity in the SN, suggesting that GABA exerts quite different effects on pars compacta and pars reticulata neurons in the human SN via GABA(A) receptors of different subunit configurations.

Increased progenitor cell proliferation and astrogenesis in the partial progressive 6-hydroxydopamine model of Parkinson's disease.

The existence of endogenous progenitor cells in the adult mammalian brain presents an exciting and attractive alternative to existing therapeutic options for treating neurodegenerative diseases such as Parkinson's disease (PD). However, prior to designing endogenous cell therapies, the effect of PD neuropathology on endogenous progenitor cell proliferation and their neurogenic potential must be investigated. This study examined the effect of dopaminergic cell loss on the proliferation and differentiation of subventricular zone- (SVZ) and midbrain-derived progenitor cells in the adult rodent brain, using the partial progressive 6-hydroxydopamine (6-OHDA) lesion model of PD. Cell proliferation and differentiation were assessed with 5-bromo-2'-deoxyuridine (BrdU) labeling and immunohistochemistry for cell type-specific markers. Tyrosine hydroxylase immunohistochemistry demonstrated a complete loss of nigrostriatal projections in the striatum and a subsequent progressive loss of dopamine (DA) cells in the SN. Quantification indicated that 6-OHDA lesion-induced cell degeneration produced a significant increase in BrdU immunoreactivity in the SVZ, ipsilateral to the lesioned hemisphere from 3 to 21 days post-lesion, compared with sham-lesioned animals. Similarly, in the striatum we observed a significant increase in the total number of BrdU positive cells in 6-OHDA-lesioned animals at all time points examined. More importantly, a significant increase in midbrain-derived BrdU positive cells was demonstrated in 6-OHDA-lesioned animals 28 days post-lesion. While we did not detect neurogenesis, BrdU labeled cells co-expressing the astrocytic marker glial fibrillary acidic protein (GFAP) were widely distributed throughout the 6-OHDA-lesioned striatum at all time points. In contrast, BrdU-labeled cells in the SN of 6-OHDA-lesioned animals did not co-express neural markers. These results demonstrate that DA-ergic neurodegeneration in the partial progressive 6-OHDA-lesioned rat brain increases SVZ- and midbrain-derived progenitor cell proliferation. While, newborn striatal progenitors undergo robust astrogenesis, newborn midbrain-derived progenitors remain in an undifferentiated state suggesting local environments differentially regulate endogenous progenitor cell populations in PD.

The immunohistochemical distribution of the GABAA receptor α1, α2, α3, ß2/3 and γ2 subunits in the human thalamus.

The GABAA receptor is the most abundant inhibitory receptor in the human brain and is assembled from a variety of different subunit subtypes which determines their pharmacology and physiology. To determine which GABAA receptor subunit proteins are found in the human thalamus we investigated the distribution of five major GABAA receptor subunits α1, α2, α3, ß2,3 and γ2 using immunohistochemical techniques. The α1-, ß2,3- and γ2- subunits which combine to form a benzodiazepine sensitive GABAA receptor showed the most intense levels of staining and were the most common subunits found throughout the human thalamus especially in the ventral and posterior nuclear groups. The next most intense staining was for the α3-subunit followed by the α2-subunit. The intralaminar nuclear group, the mediodorsal nucleus and the thalamic reticular nucleus contained α1-, ß2,3- and γ2- subunits staining as well as the highest levels of the α2- and α3- subunits. The sensory dorsal lateral geniculate nucleus contained very high levels of α1- and ß2,3- and γ2-subunits. The highest densities of GABAA receptors found throughout the thalamus which contained the subunits α1, ß2,3, and γ2 included nuclei which are especially involved in the control or the modulation of the cortico-basal ganglia-thalamo-cortical motor circuits and are thus important in disorders such as Huntington's disease where the GABAergic projections of the basal ganglia are compromised. In addition the majority of receptors in the thalamic reticular nucleus contain α3 and γ2 subunits whilst the intralaminar nuclei contain high levels of α2 and α3 subunits.

Activated c-Jun is present in neurofibrillary tangles in Alzheimer's disease brains.

Alzheimer's disease (AD) pathology is characterized by the presence of insoluble beta-amyoid deposits and neurofibrillary tangles containing hyperphosphorylated tau. Increased expression of the immediate early gene product c-Jun has also been reported in post-mortem AD brains, and the presence of upstream regulators of c-Jun has been described in tangle formations. Here, we report the presence of c-Jun specifically phosphorylated on ser-63, but not ser-73, in tangle-bearing neurons and in 'late-stage' extracellular tangles in AD brains. Western blot analysis confirmed the presence of c-Jun phosphorylated on ser-63 but not on ser-73 in AD brain tissue. The expression of differentially phosphorylated c-Jun in the AD brain may reflect the contradictory roles of these phosphorylation sites in neurons. Furthermore, the inappropriate sequestration of phosphorylated c-Jun in tangles in AD brains may contribute to AD pathology and neurodegeneration.

Neuroprotective strategies for basal ganglia degeneration: Parkinson's and Huntington's diseases.

There are three main mechanisms of neuronal cell death which may act separately or cooperatively to cause neurodegeneration. This lethal triplet of metabolic compromise, excitotoxicity, and oxidative stress causes neuronal cell death that is both necrotic and apoptotic in nature. Aspects of each of these three mechanisms are believed to play a role in the neurodegeneration that occurs in both Parkinson's and Huntington's diseases. Strategies to rescue or protect injured neurons usually involve promoting neuronal growth and function or interfering with neurotoxic processes. Considerable research has been done on testing a large array of neuroprotective agents using animal models which mimic these disorders. Some of these approaches have progressed to the clinical arena. Here, we review neuroprotective strategies which have been found to successfully ameliorate the neurodegeneration associated with Parkinson's and Huntington's diseases. First, we will give an overview of the mechanisms of cell death and the background of Parkinson's and Huntington's diseases. Then we will elaborate on a range of neuroprotective strategies, including neurotrophic factors, anti-excitotoxins, antioxidants, bioenergetic supplements, anti-apoptotics, immunosuppressants, and cell transplantation techniques. Most of these approaches hold promise as potential therapies in the treatment of these disorders.

The distribution of progenitor cells in the subependymal layer of the lateral ventricle in the normal and Huntington's disease human brain.

The recent demonstration of endogenous stem/progenitor cells in the adult mammalian brain raises the exciting possibility that these undifferentiated cells may be able to generate new neurons for cell replacement in neurodegenerative diseases such as Huntington's disease (HD). Previous studies have shown that neural stem cells in the rodent brain subependymal layer (SEL), adjacent to the caudate nucleus, proliferate and differentiate into neurons and glial cells and that neurogenesis occurs in the hippocampus and the SEL of the caudate nucleus in the adult human brain, but no previous study has shown the extent to which progenitor cells are found in the SEL in the normal and diseased human brain with respect to location. From detailed serial section studies we have shown that overall, there is a 2.7-fold increase in the number of proliferating cell nuclear antigen positive cells in HD (grade 2/3); most notably, the ventral and central regions of the SEL adjacent to the caudate nucleus contained the highest number of proliferating cells and in all areas and regions examined there were more cells in the HD SEL compared with the normal brain. Furthermore, progenitor cells colocalized with betaIII tubulin in a subset of cells in the SEL indicating neurogenesis in the HD brain. There was a 2.6-fold increase in the number of new neurons that were produced in the Huntington's disease SEL compared with the normal SEL; however, the Huntington's disease SEL had many more proliferating progenitor cells; thus, the proportion of new neuron production relative to the number of progenitor cells was approximately the same. This study provides new evidence of the pattern of neurogenesis in the normal and HD brain.

TATA-binding protein in neurodegenerative disease.

TATA binding protein (TBP) is a general transcription factor that plays an important role in initiation of transcription. In recent years evidence has emerged implicating TPB in the molecular mechanism of a number of neurodegenerative diseases. Wild type TBP in humans contains a long polyglutamine stretch ranging in size from 29 to 42. It has been found associated with aggregated proteins in several of the polyglutamine disorders. Expansion in the CAA/CAG composite repeat beyond 42 has been shown to cause a cerebellar ataxia, SCA17. The involvement of such an important housekeeping protein in the disease mechanism suggests a major impact on the functioning of cells. The question remains, does TBP contribute to these diseases through a loss of normal function, likely to be catastrophic to a cell, or the gain of an aberrant function? This review deals with the function of TBP in transcription and cell function. The distribution of the polyglutamine coding allele lengths in TBP of the normal population and in SCA17 is reviewed and an outline is given on the reported cases of SCA17. The role of TBP in other polyglutamine disorders will be addressed as well as its possible role in other neurodegenerative diseases.

Activating transcription factor 2 expression in the adult human brain: association with both neurodegeneration and neurogenesis.

Activating transcription factor 2 (ATF2) is a member of the activator protein-1 family of transcription factors, which includes c-Jun and c-Fos. ATF2 is highly expressed in the mammalian brain although little is known about its function in nerve cells. Knockout mouse studies show that this transcription factor plays a role in neuronal migration during development but over-expression of ATF2 in neuronal-like cell culture promotes nerve cell death. Using immunohistochemical techniques we demonstrate ATF2 expression in the normal human brain is neuronal, is found throughout the cerebral cortex and is particularly high in the granule cells of the hippocampus, in the brain stem, in the pigmented cells of the substantia nigra and locus coeruleus, and in the granule and molecular cell layers of the cerebellum. In contrast to normal cases, ATF2 expression is down-regulated in the hippocampus, substantia nigra pars compacta and caudate nucleus of the neurological diseases Alzheimer's, Parkinson's and Huntington's, respectively. Paradoxically, an increase in ATF2 expression was found in the subependymal layer of Huntington's disease cases, compared with normal brains; a region reported to contain increased numbers of proliferating progenitor cells in Huntington's disease. We propose ATF2 plays a role in neuronal viability in the normal brain, which is compromised in susceptible regions of neurological diseases leading to its down-regulation. In contrast, the increased expression of ATF2 in the subependymal layer of Huntington's disease suggests a role for ATF2 in some aspect of neurogenesis in the diseased brain.

The diversity of GABA(A) receptor subunit distribution in the normal and Huntington's disease human brain.

GABA(A) receptors are assembled into pentameric receptor complexes from a total of 19 different subunits derived from a variety of different subunit classes (α1-6, ß1-3, γ1-3, δ, ɛ, θ, and π) which surround a central chloride ion channel. GABA(A) receptor complexes are distributed heterogeneously throughout the brain and spinal cord and are activated by the extensive GABAergic inhibitory system. In this chapter, we describe the heterogeneous distribution of six of the most widely distributed subunits (α1, α2, α3, ß2,3, and γ2) throughout the human basal ganglia. This review describes the studies we have carried out on the normal and Huntington's disease human basal ganglia using autoradiographic labeling and immunohistochemistry in the human basal ganglia. GABA(A) receptors are known to react to changing conditions in the brain in neurological disorders, especially in Huntington's disease and display a high degree of plasticity which is thought to compensate for loss of function caused by disease. In Huntington's disease, the variable loss of GABAergic medium spiny striatopallidal projection neurons is associated with a loss of GABA(A) receptor subunits in the striosome and/or the matrix compartments of the striatum. By contrast in the globus pallidus, a loss of the GABAergic striatal projection neurons results in a dramatic upregulation of subunits on the large postsynaptic pallidal neurons; this is thought to be a compensatory plastic mechanism resulting from the loss of striatal GABAergic input. Most interestingly, our studies have revealed that the subventricular zone overlying the caudate nucleus contains a variety of proliferating progenitor stem cells that possess a heterogeneity of GABA(A) receptor subunits which may play a role in human brain repair mechanisms.

Immediate-early genes, kindling and long-term potentiation.

The mechanism(s) by which long-term changes are induced and maintained in the nervous system are poorly understood. Kindling is an example of a permanent change in brain function that results from repeated elicitation of seizures. Recently, a class of genes called "immediate-early genes" that were previously thought to be only involved in cell division, differentiation and perhaps neoplasia have been shown to be rapidly and transiently induced in adult neurons following afterdischarges, ECS and chemically-evoked seizures. The products of these genes (e.g., FOS, JUN) are DNA-binding proteins and it is thought that they alter, perhaps in a coordinate fashion, the transcription of "late-effector genes." These late genes may code for enzymes, neuropeptides, receptors, ion channels, structural proteins, growth factors, etc. that may cause permanent biochemical and/or morphological changes in the brain that give rise to the kindled state. Thus, these early genes may act as molecular switches turning on a plasticity (kindling) program in neurons in a fashion similar to their induction of developmental programs in dividing cells.

Insulin-like growth factor-1 reduces postischemic white matter injury in fetal sheep.

Insulin-like growth factor-1 (IGF-1) is known to be important for oligodendrocyte survival and myelination. In the current study, the authors examined the hypothesis that exogenous IGF-1 could reduce postischemic white matter injury. Bilateral brain injury was induced in near-term fetal sheep by 30 minutes of reversible carotid artery occlusion. Ninety minutes after ischemia, either vehicle (n = 8) or a single dose of 3 microg IGF-1 (n = 9) was infused intracerebroventricularly over 1 hour. White matter changes were assessed after 4 days recovery in the parasagittal intragyral white matter and underlying corona radiata. Proteolipid protein (PLP) mRNA staining was used to identify bioactive oligodendrocytes. Glial fibrillary acidic protein (GFAP) and isolectin B-4 immunoreactivity were used to label astrocytes and microglia, respectively. Myelin basic protein (MBP) density and the area of the intragyral white matter tracts were determined by image analysis. Insulin-like growth factor-1 treatment was associated with significantly reduced loss of oligodendrocytes in the intragyral white matter (P < 0.05), with improved MBP density (P < 0.05), reduced tissue swelling, and increased numbers of GFAP and isolectin B-4 positive cells compared with vehicle treatment. After ischemia there was a close association of PLP mRNA labeled cells with reactive astrocytes and macrophages/microglia. In conclusion, IGF-1 can prevent delayed, postischemic oligodendrocyte cell loss and associated demyelination.

The cerebellofugal projections in the brachium conjunctivum of the rat. II. The ipsilateral and contralateral descending pathways.

The cerebellofugal projections in the ipsilateral and contralateral descending pathways of the brachium conjunctivum (B.C.) in the rat have been investigated in 22 animals using the Fink-Heimer technique to demonstrate the axonal degeneration resulting from complete B.C. lesions (6), partial B.C. lesions (14) and control lesions dorsal to the B.C. (2). The incidental degeneration resulting from the concomitant involvement of the structures surrounding the B.C. is accounted for in terms of known fiber pathways and from the results in the control experiments. This study confirms Ramón y Cajal's ('03) original observation that cerebellofugal fibers in the B.C. project caudally throughout the length of the hindbrain via both ipsilateral and contralateral descending pathways. The fibers forming the ipsilateral descending pathway proceed ventrally from the B.C. at the level of the trigeminal motor nucleus, turn caudally and terminate within nucleus reticularis parvocellularis (Rpa). In particular, fibers within this pathway terminate densely in two cytoarchitecturally distinct Rpa subnuclei--nucleus "k" (Meessen and Olszewski, '49) and a caudal linear subnucleus--which project to the cerebellum (Faull, '77). The contralateral descending pathway (B.C.de) roceeds caudally from the decussation of the B.C. within the ventromedial region of the magnocellular nuclei of the reticular formation of the pons and medulla. Cerebellofugal fibers of the B.C.de terminate in a distinctive pattern within precerebellar brainstem nuclei: densely throughout the middle third of nucleus reticularis tegmenti pontis; in a longitudinal zone of each of the three pontine gray subnuclei; in the principal and dorsal accessory nuclei of the inferior olive; and sparsely within nucleus reticularis paramedianus. Fibers in the B.C.de also terminate within the magnocellular nuclei of the reticular formation, principally the nuclei reticularis pontis oralis and caudalis.

The cerebellofugal projections in the brachium conjunctivum of the rat I. The contralateral ascending pathway.

The cerebellofugal projections in the contralateral ascending pathway of the brachium conjunctivum (B.C.) in the rat have been investigated in 23 animals using the Fink-Heimer technique to demonstrate the axonal degeneration resulting from complete B.C. lesions (7), partial B.C. lesions (14) and control lesions dorsal to the B.C. (2). All of the degeneration resulting from the concomitant involvement of the structures surrounding the B.C. is accounted for in terms of known fiber pathways and from the results in the control experiments. The contralateral ascending pathway ascends rostrally from the decussation of the B.C. through the ventromedial midbrain tegmentum to the diencephalon. In the midbrain, cerebellofugal fibers terminate heavily throughout the red nucleus including the nucleus minimus, while others pass dorsolaterally and dorsomedially from the ascending tract to terminate in adjacent midbrain nuclei. The dorsolaterally directed fibers terminate in the midbrain reticular formation,the stratum griseum profundum of the superior colliculus, the anterior pretectalnucleus and the nucleus of the posterior commissure; the dorsomedially directed fibers terminate in the principal oculomotor nucleus, the nucleus of Darkschewitsch, interstitial nucleus of Cajal and the central gray matter. A considerable number of the cerebellofugal fibers proceed more rostrally within the prerubral field and enter the thalamus by two routes. Most follow a direct subthalamic course within field H of Fore1 and after contributing fibers to the zona incerta, enter the caudal pole of the ventromedial nucleus (Vm) of the thalamus to terminate throughout Vm and the ventrolateral complex (Vl). Others enter via the internal medullary lamina and terminate throughout the parafascicular and central lateral nuclei. A small number of cerebellothalamic fibers form a commissural projection to V1 on the opposite side.The finding that the cerebellothalamic projections to the ventral nucleus are distributed throughout Vm and V1 establishes the Vm-V1 complex as the homologue in the rat of the ventral anterior and ventral lateral nuclei in the primate thalamus.

A comparative study of the neurons of origin of the spinocerebellar afferents in the rat, cat and squirrel monkey based on the retrograde transport of horseradish peroxidase.

The cell bodies of the neurons of the spinocerebellar pathways were examined using large injections of horseradish peroxidose into the cerebellum. Sections of each spinal segment were examined with both the DAB and the de Olmos O-dianisidine techniques. Results common to all three species were found. In Clarke's nucleus, the central cervical nucleus, and the spinal border cells there were many heavily labeled cells. Clarke's nucleus was found to project primarily ipsilaterally; the spinal border cells primarily contralaterally; and the central cervical nucleus bilaterally. In addition to these aggregates of spinocerebellar neurons there were numerous labeled neurons scattered throughout the spinal grey. Labeled neurons were found in all portions of the spinal grey except the substantia gelatinosa and lateral cervical nucleus and occurred in all spinal segments. They varied in morphology from large multipolar neurons, found predominantly in the ventral horn to small globular and fusiform neurons that were most abundant in the dorsal horn. These cells were found to project both ipsilaterally and contralaterally. Results common to only two of the species examined were also found. In the dquirrel monkey and the cat, but not the rat, the marginal layer of the dorsal horn in all segments of the spinal contained numerous labeled neurons. These marginal neurons were especially numerous in the squirrel monkey, where as many as 13 to 16 labeled neurons per section of the dorsal horn were found. In the rat and the squirrel monkey but not the cat, some intensely labeled large multipolar neurons were found in the sacral and caudal segments. These are the cells of Stilling's nucleus, a column of cells similar in position and orientation to that of Clarke's column but different in its projections and details of cytoarchitecture. Thus we have not only confirmed that Clarke's nucleus, the central cervical nucleus, and the spinal border cells project to the cerebellum but we have also found several new sources of spinocerebellar afferents.

GABA(A) receptors in the primate basal ganglia: an autoradiographic and a light and electron microscopic immunohistochemical study of the alpha1 and beta2,3 subunits in the baboon brain.

The distribution of gamma-aminobutyric acid(A) (GABA(A)) receptors was investigated in the basal ganglia in the baboon brain by using receptor autoradiography and the immunohistochemical localisation of the alpha1 and beta2,3 subunits of the GABA(A) receptor by light and electron microscopy. In the caudate-putamen, the alpha1 subunit was distributed in high densities in the matrix compartment, and the beta2,3 subunits were more homogeneously distributed; the globus pallidus showed lower levels of the alpha1 and beta2,3 subunits. Four types of alpha1 subunit immunoreactive neurons were identified in the baboon striatum: the most numerous (75%) were type 1 medium-sized aspiny neurons; type 2 (2%) were large aspiny neurons with an indented nuclear membrane located in the ventral striatum; type 3 neurons were the least numerous (1%) and were comprised of large neurons in the ventromedial regions of the striatum; and type 4 (22%) neurons were medium to large aspiny neurons located in striosomes. At the ultrastructural level, alpha1 and beta2,3 subunit immunoreactivity was localised in the neuropil of the striatum in both symmetrical and asymmetrical synaptic contacts. In the globus pallidus, alpha1 and beta2,3 subunits were localised on large neurons and were found in three types of synaptic terminals: type 1 terminals were small and established symmetrical synapses; type 2 terminals were large; and type 3 terminals formed small synaptic terminals with subjunctional dense bodies. These results show that the subunit composition of GABA(A) receptors varies between the striosome and the matrix compartments in the striatum and that there is receptor subunit homogeneity in the globus pallidus.