Rick B. Meeker

Quantitative mapping of glutamate presynaptic terminals in the supraoptic nucleus and surrounding hypothalamus

Although the hypothalamus is generally regarded to have low levels of glutamate receptors, anatomical and physiological studies have provided consistent evidence implicating glutamate as a potential transmitter for the control of neuroendocrine cell activity. To clarify the extent of the contribution of synapses utilizing glutamate for control of vasopressin/oxytocin neuroendocrine cells, we mapped the density and location of glutamate immunoreactive terminals in the supraoptic nucleus and surrounding hypothalamus. Colloidal gold particle densities in presynaptic terminals were measured from electron micrographs of: (1) the magnocellular neuroendocrine cell perikarya (main body of the supraoptic nucleus), (2) the dendritic field of the magnocellular neuroendocrine cells (ventral dendritic neuropil) and (3) the hypothalamic perinuclear zone dorsal to the supraoptic nucleus. In addition, serial sections were stained, alternatively, for glutamate or GABA to determine glutamate staining in GABA cells. Terminals with high glutamate immunoreactivity were clearly distinguished from the glutamate precursor staining found in GABA terminals and were abundant at all rostral-caudal levels within each region. The number of glutamate terminals identified in each region was similar but represented a very high proportion of all terminals in the ventral dendritic neuropil (38%) vs. the main body of the supraoptic nucleus and the perinuclear zone (20-22%). The regional variation in the relative proportion of glutamate terminals was determined largely by differences in the number of non-glutamate terminals within each region. Glutamate and GABA terminals together accounted for over two-thirds of the innervation of vasopressin/oxytocin neuroendocrine cells. No systematic relationship was observed between excitatory and inhibitory inputs on the same cell. These results suggest that glutamate is the predominant excitatory transmitter used for control of vasopressin/oxytocin cells. The relative contribution of glutamate neurotransmission to a particular region will depend, in part, on the number and type of competing non-glutamate terminals.

Light and electron microscopic localization of glutamate immunoreactivity in the supraoptic nucleus of the rat hypothalamus

The distribution of glutamate immunoreactivity was mapped within the supraoptic nucleus of the rat hypothalamus utilizing a specific anti-glutamate antibody. Magnocellular neuroendocrine cells of the supraoptic nucleus showed intense immunoreactivity for glutamate which varied with the conditions of fixation. Within the perikarya, reaction product was found associated with the endoplasmic reticulum but not the mitochondria, Golgi, dense bodies or neurosecretory granules. A relatively high density of glutamate-immunoreactive terminals was found in the supraoptic nucleus. These terminals were less affected by fixation condition and were generally found contacting large, glutamate-immunoreactive processes within the ventral dendritic neuropil of the supraoptic nucleus. The pattern and characteristics of glutamate immunoreactivity in the supraoptic nucleus suggested the presence of two distinct glutamate pools. The magnocellular neuroendocrine cells may contain a large, labile metabolic pool of glutamate. These cells, in turn, appear to receive glutamate synaptic input from a more stable pool consistent with suggestions that glutamate may be used as a transmitter within this system.

Choline deficiency induces apoptosis in primary cultures of fetal neurons

Treatment of rats with choline during brain development results in long‐lasting enhancement of spatial memory whereas choline deficiency has the opposite effect. Changes in rates of apoptosis may be responsible. We previously demonstrated that choline deficiency induced apoptosis in PC12 cells and suggested that interruption of cell cycling due to a decrease in membrane phosphatidylcholine concentration was the critical mechanism. We now examine whether choline deprivation induces apoptosis in nondividing primary neuronal cultures of fetal rat cortex and hip‐pocampus. Choline deficiency induced widespread apoptosis in primary neuronal cells, indicating that cells do not have to be dividing to be sensitive to choline deficiency. When switched to a choline‐deficient medium, both types of cells became depleted of choline, phosphocholine and phosphatidylcholine, and in primary neurons neurite outgrowth was dramaticallyatten‐uated. Primary cells could be rescued from apoptosis by treatment with phosphocholine or lysophosphatidyl‐choline. As described previously for PC12 cells, an increase in ceramide (Cer) was associated with choline deficiency‐induced apoptosis in primary neurons. The primary neuronal culture appears to be an excellent model to explore the mechanism whereby maternal dietary choline intake modulates apoptosis in the fetal brain.—Yen, C.‐L. E., Mar, M.‐H., Meeker, R. B., Fernandes, A., Zeisel, S. H. Choline deficiency induces apoptosis in primary cultures of fetal neurons. FASEB J. 15, 1704–1710 (2001)

A critical role for palladin in astrocyte morphology and response to injury

Astrocytes respond to injury of the CNS with a dramatic change in morphology, contributing to the formation of a glial scar. We recently identified a novel actin-associated protein named palladin, which possesses the features of a potent cytoskeletal scaffold. Palladin expression was assayed in two populations of cultured astrocytes, polygonal versus stellate, and was detected at high levels in polygonal astrocytes and low levels in stellate astrocytes. When stellate astrocyte monolayers were wounded, palladin was rapidly upregulated along the edge of the wound, coordinate with an increase in actin assembly. Palladin upregulation occurred along a similar rapid time course following injury to the cerebral cortex of adult rats. To explore palladin function more directly, palladin cDNA was transfected into stellate astrocytes, which acquired a spread morphology and prominent actin bundles. These results suggest that palladin upregulation following injury may be a key step in the acquisition of the reactive astrocyte morphology.

Vasopressin mRNA Expression in Individual Magnocellular Neuroendocrine Cells of the Supraoptic and Paraventricular Nucleus in Response to Water Deprivation

Vasopressin neuroendocrine function involves the regulation of both secretion and synthesis from magnocellular neuroendocrine cells but the coordination of these two processes is poorly understood. To explore the temporal relationship between physiological stimulation and vasopressin mRNA levels we measured vasopressin mRNA content within individual magnocellular neurons of the supraoptic and paraventricular nucleus during the course of water deprivation. Analysis of autoradiographic silver grain densities from in situ hybridization of an [125I]dCTP-labeled oligonucleotide specific for vasopressin mRNA revealed a wide variety of resting vasopressin mRNA levels and differential responses to water deprivation in the magnocellular neuroendocrine cells. During water deprivation, the vasopressin mRNA content of the paraventricular nucleus increases rapidly and with shorter latency and greater incremental response than the supraoptic nucleus. Double-labeling experiments with combined in situ hybridization and immunocytochemistry identified a population of vasopressin immunoreactive cells which maintain very low basal levels of vasopressin mRNA. The location of these cells correlates with the location of increased silver grain densities during water deprivation. One subset of vasopressin magnocellular neurons failed to show high levels of vasopressin mRNA, indicating that all cells are not equally responsive to water deprivation. These patterns of vasopressin mRNA expression suggest the presence of functional subpopulations of vasopressin neuroendocrine cells which may reflect stimulus-specific patterns of afferent input to the supraoptic and paraventricular nucleus.

Ultrastructural distribution of glutamate immunoreactivity within neurosecretory endings and pituicytes of the rat neurohypophysis

An ultrastructural analysis of post-embedding glutamate immunocytochemistry within the neural lobe of the pituitary was used to explore the possible role of glutamate within the magnocellular neuroendocrine cells. Relative densities of a colloidal gold marker associated with various cellular and subcellular compartments of the neural lobe were quantified by computer analysis of electron micrographs. Robust glutamate immunoreactivity was observed in both pituicytes (cytoplasm, mitochondria and nucleus) and neurosecretory endings. Within the neurosecretory endings, glutamate staining was specifically localized to the microvesicles with no overlap into the neurosecretory granule population. Stimulation of the vasopressin/oxytocin neurosecretory system by water deprivation increased glutamate content in pituicytes and mitochondria within neurosecretory endings but had little influence on microvesicle glutamate content. The results are consistent with the existence of multiple functional pools of immunoreactive glutamate in both pituicytes and neurosecretory endings. Microvesicles within the neurosecretory endings exhibit many properties of secretory vesicles, appear to be functionally independent of the neurosecretory granules, and have sufficient glutamate immunoreactivity to suggest that this amino acid may be compartmentalized for release in the neural lobe.

Cell trafficking through the choroid plexus

The choroid plexus is a multifunctional organ that sits at the interface between the blood and cerebrospinal fluid (CSF). It serves as a gateway for immune cell trafficking into the CSF and is in an excellent position to provide continuous immune surveillance by CD4+ T cells, macrophages and dendritic cells and to regulate immune cell trafficking in response to disease and trauma. However, little is known about the mechanisms that control trafficking through this structure. Three cell types within the choroid plexus, in particular, may play prominent roles in controlling the development of immune responses within the nervous system: the epithelial cells, which form the blood-CSF barrier, and resident macrophages and dendritic cells in the stromal matrix. Adhesion molecule and chemokine expression by the epithelial cells allows substantial control over the selection of cells that transmigrate. Macrophages and dendritic cells can present antigen within the choroid plexus and/or transmigrate into the cerebral ventricles to serve a variety of possible immune functions. Studies to better understand the diverse functions of these cells are likely to reveal new insights that foster the development of novel pharmacological and macrophage-based interventions for the control of CNS immune responses.

Differential expression of five N-methyl-D-aspartate receptor subunit mRNAs in vasopressin and oxytocin neuroendocrine cells

Vasopressin and oxytocin neuroendocrine cells within the supraoptic nucleus display distinctive electrophysiological properties and differential responses to selected NMDA receptor (NR) antagonists. To determine if these differences might be due to NMDA receptor composition, we compared the expression of NR1, NR2A, NR2B, NR2C and NR2D subunit mRNAs in immunocytochemically identified vasopressin and oxytocin neuroendocrine cells. In contrast to NR1 subunit mRNA which was equally expressed in both vasopressin and oxytocin cells, NR2B and NR2C displayed very different expression patterns. In oxytocin cells, the NR2B subunit comprised the majority (65%) of the total NR2 expression with NR2C and NR2D contributing 6% and 27%, respectively. Vasopressin cells exhibited 5-fold higher NR2C (32%), approximately half as much NR2B mRNA (39%) and equivalent NR2D (31%). In vitro expression studies have shown that the NR1-NR2C subunit combination exhibits weaker magnesium block and higher affinity for glycine than NR1-NR2B. Thus, the high expression of NR2C in vasopressin cells relative to oxytocin cells may make these cells more susceptible to glutamatergic activation. These observations in vasopressin and oxytocin cells provide the basis for a working model to investigate how differential NMDA receptor composition may shape the neurophysiological properties of neurons.

Astrocytes and microglia differentially regulate trafficking of lymphocyte subsets across brain endothelial cells

Feline brain endothelial cells (BECs), astrocytes, and microglia were combined in different configurations in a cell culture insert system to assess the effect of different cell types on the trafficking of peripheral blood mononuclear cell (PBMC) subsets in response to feline immunodeficiency virus (FIV). The addition of astrocytes to BECs significantly increased the adherence of PBMCs. This increase in adherence was suppressed by microglia, whereas microglia alone had no effect on PBMC adherence. FIV exposure of the glial cells did not alter PBMC adherence as compared to same configurations with untreated cells. All PBMC subsets showed some level of trafficking across the endothelial cell layer. The level of trafficking of monocytes and B cells was significantly increased if astrocytes were present. The presence of microglia with the astrocytes reduced transmigration across all PBMC subsets. FIV exposure of astrocytes significantly increased the percentage of CD8 T cell transmigration from 24% to 64% of the total CD4 and CD8 numbers. The presence of microglia significantly reversed the preferential trafficking of CD8 cells in the presence of astrocytes. The results suggested that interaction between the triad of endothelial cells, astrocytes, and microglia played an important, but varying, role in the trafficking of different PBMC subsets. In general, astrocytes had a positive effect on trafficking of PBMCs, while microglia had a suppressive effect. Effects of FIV on trafficking were largely restricted to increases seen in CD8 T cells and monocytes.

Differential Distribution of Muscarinic Cholinergic and Putative Nicotinic Cholinergic Receptors within the Hypothalamo-Neurohypophysial System of the Rat

Binding of the muscarinic cholinergic receptor probe [3H]quinuclidinylbenzilate ([3H]QNB) and the putative nicotinic receptor probe [125I]alpha-bungarotoxin ([125I]alpha BTX) to vasopressin (VP) and oxytocin (OT) neuroendocrine cells was investigated with a combination of quantitative receptor binding, autoradiography and immunocytochemistry. A single high-affinity site was labelled by [3H]QNB in the hypothalamus and pituitary (KD = 0.76-1.44 X 10(-10) M) with a mean hypothalamic density of 213 fmol/mg protein compared with only 56 fmol/mg protein in the pituitary. Analysis of autoradiographic silver grains from [3H]QNB binding revealed a relative absence of binding associated with magnocellular VP and OT cell groups in the hypothalamus. The median eminence and neural lobe of the pituitary contained low levels of [3H] QNB binding, which, however, were the highest within the hypothalamo-neurohypophysial system. The ligand [125I]alpha BTX binds with both a high and low affinity to sites within the hypothalamus and pituitary (high-affinity KD = 0.77-1.03 X 10(-10) M). In the hypothalamus the density of high-affinity binding sites (25 fmol/mg protein) is approximately 2.5 times greater than in the pituitary. In contrast to [3H]QNB, high-affinity binding of [125I]alpha BTX was found to be highly concentrated within the supraoptic nucleus, nucleus circularis, and the magnocellular areas of the paraventricular nucleus. Autoradiographic silver grains were distributed over both VP and OT immunoreactive neurons and processes. Binding within the neural lobe was very low. These data suggest that the cholinergic regulation of VP and OT release may occur via nicotinic cholinergic receptors at the level of the magnocellular cell bodies and predominantly via muscarinic cholinergic receptors within the neural lobe.