Synapsin I gene expression in the adult rat brain with comparative analysis of mRNA and protein in the hippocampus.

Synapsin I is the best characterized member of a family of neuron-specific phosphoproteins thought to be involved in the regulation of neurotransmitter release. In this report, we present the first extensive in situ hybridization study detailing the regional and cellular distribution of synapsin I mRNA in the adult rat brain. Both the regional distribution and relative levels of synapsin I mRNA established by in situ hybridization were confirmed by RNA blot analysis. Our data demonstrate the widespread yet regionally variable expression of synapsin I mRNA throughout the adult rat brain. The greatest abundance of synapsin I mRNA was found in the pyramidal neurons of the CA3 and CA4 fields of the hippocampus, and in the mitral and internal granular cell layers of the olfactory bulb. Other areas abundant in synapsin I mRNA were the layer II neurons of the piriform cortex and layer II and V neurons of the entorhinal cortex, the granule cell neurons of the dentate gyrus, the pyramidal neurons of hippocampal fields CA1 and CA2, and the cells of the parasubiculum. In general, the pattern of expression of synapsin I mRNA paralleled those encoding other synaptic terminal-specific proteins, such as synaptophysin, VAMP-2, and SNAP-25, with noteworthy exceptions. To determine specifically how synapsin I mRNA levels are related to levels of synapsin I protein, we examined in detail the local distribution patterns of both synapsin I mRNA and protein in the rat hippocampus. These data revealed differential levels of expression of synapsin I mRNA and protein within defined synaptic circuits of the rat hippocampus.

Positive- and negative-acting promoter sequences regulate cell type-specific expression of the rat synapsin I gene.

The phosphoprotein synapsin I is expressed exclusively in neuronal cells. We are interested in elucidating the promoter sequences involved in cell type-specific expression of the synapsin I gene. The PC12 cell line expresses the 3.4 kb and 4.5 kb synapsin I mRNAs and is used to analyze cell type-specific gene expression. A series of deletion fragments of the rat synapsin I gene promoter were fused to the promoterless reporter gene encoding bacterial chloramphenicol acetyltransferase (CAT) for transfection analysis in PC12 cells and in HeLa cells, which do not express the gene. A -349 bp to +110 bp rat synapsin I promoter fragment contains a positive regulator, shown to be 33-times more active in PC12 cells than HeLa cells. Transfection of reporter plasmids containing up to 4.4 kb of rat synapsin I gene promoter sequences exhibit significantly reduced CAT activity in PC12 cells. The reduction in CAT expression was attributed to a negative regulator located between -349 bp and -1341 bp in the rat synapsin I promoter. Our results suggest that both positive and negative-acting sequence elements regulate cell type-specific expression of the rat synapsin I gene.

Distribution of glucuronic acid-and-sulfate-containing glycoproteins in the central nervous system of the adult mouse.

The distribution of glucuronic acid-and-sulfate-containing carbohydrate (GSC) epitope recognized by two monoclonal antibodies, HNK-1 and 4F4, was studied by immunocytochemistry in adult mouse brain. Both antibodies recognized proteins ranging in molecular weight from 60 to above 250 kDa in Western blot but no glycolipid was recognized in the adult brain. With both light and electron microscopic study, two patterns of staining are observed: diffuse neuropil staining, and individual neuronal somata staining. The diffuse neuropil staining is concentrated in discrete anatomically defined areas. At the EM level, this immunoreactivity is associated with numerous dendrites or astrocytic processes. At cell somata, most of neurons are stained only at Golgi apparatus (type 2); however, a distinct population of cells showed membranous staining (type 1) as well. Type 1 membranous immunoreactivity is observed only in membrane adjacent to astrocytic processes. In the cerebral cortex, type 1 neurons are found in layers III and V-VIa of somatosensory cortex, but only in layers V-VIa in most other cortical fields. Other areas containing type 1 neurons include the globus pallidus, the thalamic reticular nucleus, the hippocampus, the deep cerebellar nuclei, and a majority of the primary sensory and motor nuclei in the brainstem. The subpopulation of type 1 neurons show an overlap in distribution and morphology with some GABA-containing cells.

Cellular migration in developing cerebral wall explants in vitro.

Explants of the developing cerebral wall of the embryonic mouse survive in rotation-mediated culture for at least 3 days. [3H]Thymidine-labeled cells are initially located in the ventricular zone but after two days in vitro are located in a middle cell-rich layer. Cortical explants can thus be used as a model system in which the molecular mechanisms of neuronal migration in the developing cerebral wall can be examined.

Synaptic reorganization in the motor trigeminal nucleus of the rat following neonatal 6-hydroxydopamine treatment.

The synaptic organization of the motor trigeminal nucleus in adult rats treated neonatally with 6-hydroxydopamine (6-OHDA) was investigated quantitatively and compared with control nuclei. No statistically significant change was detected in the distribution of axon terminals in the neuropil, and the total number of axosomatic contacts per unit length of membrane was identical in the control and 6-OHDA-treated groups. However, 6-OHDA treatment causes a significant redistribution of the four morphologically distinct bouton populations forming axosomatic contacts with trigeminal motoneurons. Terminals containing lucent axoplasm and spherical synaptic vesicles have been identified as norepinephrine neuron terminals (Card et al.: J. Comp. Neurol. 250:469-484, '86). These and terminals with lucent axoplasm and pleomorphic vesicles are increased in number whereas terminals with dense axoplasm and either spherical or pleomorphic synaptic vesicles are decreased in number in the 6-OHDA-treated brains compared to controls. These results confirm that the norepinephrine hyperinnervation observed in histofluorescence preparations following neonatal 6-OHDA treatment reflects an increase in absolute numbers of norepinephrine terminals. The finding that the total number of axosomatic contacts per unit length of membrane remains constant while the proportions of individual afferent classes vary may indicate that the trigeminal motoneuron plays a major role in determining the overall density but not necessarily the individual specificity of its axosomatic innervation. The motor trigeminal nucleus is a useful model system in which to investigate both the response of norepinephrine fibers to neonatal 6-OHDA treatment and the respective roles of a target neuron and its afferents in the regulation of appropriate quantitative innervation patterns in the central nervous system.

Autoradiographic study of beta 1-adrenergic receptor development in the mouse forebrain.

The development of beta 1-adrenergic receptors has been studied in the mouse forebrain from embryonic day 14 (E14) to adulthood, using autoradiographic visualization of [125I]iodocyanopindolol (ICYP) binding sites. From E14, ICYP binding sites are detected in moderate amounts in the striatum and basal forebrain and in very low concentration in the cortical plate. At E17, binding sites have increased in number in the deep layers of the embryonic cortex and extend over the whole thickness of the cortical ribbon at birth. On postnatal day 4 (P4), ICYP binding sites are more abundant in the superficial than in the inner cortex. By P10 the adult pattern of ICYP binding site distribution is achieved, namely: a high concentration in ventral pallidum, striatum and cortical layers I, II and III, a moderate concentration in layers V and VI and a lower density in septal areas and in cortical layer IV. It is well established that norepinephrine fibers arrive in the embryonic cortex early in development. The present results show that the development of norepinephrine fiber and beta 1 receptor systems are coincident in the mouse.

Interpeduncular nucleus organization in the rat: cytoarchitecture and histochemical analysis.

The organization of the interpeduncular nucleus (IPN) in the adult rat was analyzed using cytoarchitectonic, histochemical and immunohistochemical methods. Four paired and four unpaired subnuclei can be distinguished in the IPN on the basis of neuronal size, morphology, staining characteristics and packing density. The rostral portion of the IPN contains a rostral dorsal, a rostral ventral and paired rostral lateral and dorsal lateral nuclei. The dorsal lateral nuclei continue into the caudal IPN, which also contains a caudal dorsal, a caudal ventral and paired caudal lateral nuclei. The distribution of extrinsic afferents and of chemically identified intrinsic neuronal and fiber populations within subdivisions of the IPN was examined using immunohistochemistry, acetylcholinesterase histochemistry, catecholamine histofluorescence and the autoradiographic tracing method. Six immunohistochemically distinct neuronal groups are identified in the IPN. Perikarya and axons showing substance P-, leu-enkephalin-, somatostatin-, avian pancreatic polypeptide-, serotonin- and glutamic acid decarboxylase-like immunoreactivity are localized to specific IPN subnuclei. Acetylcholinesterase-positive staining, extrinsic norepinephrine-containing fibers and afferents from the dorsal tegmental nuclei are also distributed specifically to IPN subnuclei. These findings demonstrate a cytoarchitectonic and cytochemical complexity in the rat IPN that implies an important functional role for this poorly understood nuclear complex.

Enhanced dopamine cell survival in reaggregates containing telencephalic target cells.

Dissociated, 14-day-old embryonic cells of the rostral mesencephalic tegmentum (RMT), including the dopamine neurons of this region, were allowed to reaggregate and develop in rotatory culture for 7 days in the presence of dissociated embryonic cells from the target areas of the dopaminergic neurons, corpus striatum (CS) or frontal cortex (FCx). Alternatively, RMT cells were allowed to reaggregate by themselves or in the presence of dissociated cells from a telencephalic area, occipital cortex (OCx), or mesencephalic area, tectum (T), which are not target areas for the dopamine neurons. Histofluorescence analysis revealed the number of dopamine neurons contained within reaggregates of any given type. Approximately 4 times as many dopamine neurons were found in RMT-CS coaggregates and 1.5 times as many in RMT-FCx coaggregates than in aggregates constituted from cells of the RMT either alone, or in coaggregates from RMT-OCx or RMT-T. Since axonal process formation and maintenance can only be observed in RMT-CS and RMT-FCx coaggregates, the enhanced dopamine neuron survival is probably due to an interaction of dopaminergic axonal processes with target cells within the reaggregates.

Target neuron-specific process formation by embryonic mesencephalic dopamine neurons in vitro.

Mesencephalic dopamine neurons from the embryonic mouse brain were dissociated, aggregated in vitro in the presence of dissociated cells from appropriate or inappropriate target neuron areas, and visualized by the Falck-Hillarp histofluorescence technique after exposure to 1 microM exogenous dopamine. When aggregated with the surrounding rostral mesencephalic tegmentum cells only or with the addition of rostral tectum cells, the dopamine neurons formed a dense dendritic arborization, but no axons were observed. In the presence of dopamine-neuron target cells from the corpus striatum, a dense axonal plexus characteristic of that formed in this area in vivo was observed. In contrast, in aggregates formed with target cells from the frontal cortex, branching fluorescent axons bearing irregularly spaced and shaped varicosities were found coursing through the neuropil, as is characteristic of the dopaminergic innervation to the frontal cortex in vivo. Only proximal dendrites were observed in the presence of these axonal target cells. Dopamine neurons cultured with inappropriate target cells from the occipital cortex did not form either extensive axonal or dendritic processes. Thus, the presence, type, and distribution of dopamine neuronal processes are dependent on the presence of appropriate target cells. The formation of unique patterns of neuronal processes by dissociated neurons in vitro suggests that the information necessary for this differentiation is intrinsic to the dopamine neurons and their target cells. This system provides a useful model with which to study basic mechanisms underlying neuronal recognition.