Differential pulse voltammetric determination of 5-hydroxyindoles in four raphe nuclei of chronic freely moving rats simultaneously recorded by polygraphic technique: Physiological changes with vigilance states

The effect of prostaglandin (PG) D2 on neuronal functions was investigated in neuroblastoma X glioma NG108-15 hybrid cells. PGD2 caused a sustained increase in miniature end-plate potentials (MEPPs) recorded from cultured striated muscle cells which had formed junctions with NG108-15 cells. PGD2 initially hyperpolarized and then depolarized NG108-15 cells. The time course of depolarization fitted well to the facilitative phase of MEPPs. The same action on synaptic transmission and membrane potentials was detected with PGF2 alpha but not with PGE1. PGD2 (10(-4)M) produced a 3-fold increase of adenylate cyclase activity in NG108-15 cell homogenates through its receptors that are distinct from those of PGE1 and PGI2. These results show that PGD2 facilitates MEPP frequency from NG108-15 cells due to depolarization, and suggest that PGD2 may act as a physiological neuromodulator for synaptic transmission in vivo.     

Synaptic signaling between neurons and glia

Rapid signaling between vertebrate neurons occurs primarily at synapses, intercellular junctions where quantal release of neurotransmitter triggers rapid changes in membrane conductance through activation of ionotropic receptors. Glial cells express many of these same ionotropic receptors, yet little is known about how receptors in glial cells become activated in situ. Because synapses were thought to be the sole provenance of neurons, it has been assumed that these receptors must be activated following diffusion of transmitter out of the synaptic cleft, or through nonsynaptic mechanisms such as transporter reversal. Two recent reports show that a ubiquitous class of progenitors that express the proteoglycan NG2 (NG2 cells) engage in rapid signaling with glutamatergic and gamma-aminobutyric acid (GABA)ergic neurons through direct neuron-glia synapses. Quantal release of transmitter from neurons at these sites triggers rapid activation of aminomethylisoxazole propionic acid (AMPA) or GABA(A) receptors in NG2 cells. These currents exhibit properties consistent with direct rather than spillover-mediated transmission, and electron micrographic analyses indicate that nerve terminals containing clusters of synaptic vesicles form discrete junctions with NG2 cell processes. Although activation of AMPA or GABA(A) receptors depolarize NG2 cells, these receptors are more likely to serve as routes for ion flux rather than as current sources for depolarization, because the amplitudes of the synaptic transients are small and the resting membrane potential of NG2 cells is highly negative. The ability of both glutamate and GABA to influence the morphology, physiology, and development of NG2 cells in vitro suggests that this rapid form of signaling may play important roles in adapting the behavior of these cells to the needs of surrounding neurons in vivo.     

NG2-positive cells in CNS function and the pathological role of antibodies against NG2 in demyelinating diseases

NG2 is expressed by a variety of immature glia in the CNS including oligodendrocyte progenitor cells, paranodal astrocytes and perisynaptic glia. The protein has a large extracellular domain with two LNS/Lam G domains at the N-terminus and a short intracellular tail with a PDZ-recognition domain at the C-terminus. Experiments suggest that the protein plays a role in migration. The PDZ protein GRIP was identified as an intracellular binding partner of NG2 in immature glial cells. A complex is formed between GRIP, NG2 and the AMPA class of glutamate receptors: this may position these glial receptors towards sites of neuronal glutamate release at synapses and during myelination. Identification of neuronal receptors and links to the cytoskeleton of NG2 is of critical importance. Some Multiple Sclerosis patients have autoantibodies to NG2 in the cerebral spinal fluid: such antibodies could interfere with remyelination by lysing oligodendrocyte progenitor cells or blocking their migration but may also cause pathology by disrupting glial-neuronal signalling at synapses and paranodes.     

Differential distributions and trafficking properties of dopamine D1 and D5 receptors in nerve cells

Objective

To explore the possible differential trafficking properties of the dopamine D1-like receptor subtypes, D1 receptor and D5 receptor.

Methods

To visualize distributions of dopamine D1-like receptor subtypes at subcellular level, the yellow and cyan variants of green fluorescent protein (GFP) were used to tag D1 and D5 receptors. After transfection with the tagged dopamine receptors, the neuroblastoma cells NG108-15 were treated with D1 agonist SKF38393 or acetylcholine (ACh). Then we observed the subcellular distributions of the tagged receptors under the confocal microscopy and tried to determine trafficking properties by comparing their distribution patterns before and after the drug treatment.

Results

In resting conditions, D1 receptors located in the plasma membrane of NG108-15 cells, while D5 receptors located in both plasma membrane and cytosol. With the pre-treatment of SKF38393, the subcellular distribution of D1 receptors was changed. The yellow particle-like fluorescence of tagged D1 receptors appeared in the cytosol, indicating that D1 receptors were internalized into cytosol from the cell surface. Same situation also occurred in ACh pre-treatment. In contrast, the subcellular distribution of D5 receptors was not changed after SKF38393 or ACh treatment, indicating that D5R was not translocated to cell surface. Interestingly, when D1 and D5 receptors were co-expressed in the same cell, both kept their distinct subcellular distribution patterns and the trafficking properties.

Conclusion

Our present study reveals that in NG108-15 nerve cells, dopamine D1 and D5 receptors exhibit differential subcellular distribution patterns, and only D1 receptor has a marked trafficking response to the drug stimulation. We further discuss the potential role of the differential trafficking properties of D1-like receptors in complex modulation of DA signaling.     

Facilitation of synaptic transmission by prostaglandin D2 at synapses between NG108-15 hybrid and muscle cells

The effect of prostaglandin (PG) D₂ on neuronal functions was investigated in neuroblastoma × glioma NG108-15 hybrid cells. PGD₂ caused a sustained increase in miniature end-plate potentials (MEPPs) recorded from cultured striated muscle cells which had formed junctions with NG108-15 cells. PGD₂ initially hyperpolarized and then depolarized NG108-15 cells. The time course of depolarization fitted well to the facilitative phase of MEPPs. The same action on synaptic transmission and membrane potentials was detected with PGF_2α but not with PGE₁. PGD₂ (10⁻⁴M) produced a 3-fold increase of adenylate cyclase activity in NG108-15 cell homogenates through its receptors that are distinct from those of PGE₁ and PGI₂. These results show that PGD₂ facilitates MEPP frequency from NG108-15 cells due to depolarization, and suggest that PGD₂ may act as a physiological neuromodulator for synaptic transmission in vivo.     

NG2 cells differentiate into astrocytes in cerebellar slices

NG2-glia are an abundant population of glial cells that have been considered by many to be oligodendrocyte progenitor cells (OPCs). However, growing evidence suggests that NG2-glia may also be capable of differentiating into astrocytes and neurons under certain conditions. Here, we have examined NG2-glia in cerebellar slices, using transgenic mice in which the astroglial marker glial specific protein (GFAP) drives expression of the reporter gene enhanced green fluorescent protein (EGFP). Immunolabelling for NG2 shows that NG2-glia and GFAP-EGFP astroglia are separate populations in most areas of the brain, although a substantial population of NG2-glia in the pons also express the GFAP-EGFP reporter. In the cerebellum, NG2-glia did not express EGFP, either at postnatal day (P)12 or P29–30. We developed an organotypic culture of P12 cerebellar slices that maintain cytoarchitectural integrity of Purkinje neurons and Bergmann glia. In these cultures, BrdU labelling indicates that the majority of NG2-glia enter the cell cycle within 2 days in vitro (DIV), suggesting that NG2-glia undergo a ‘reactive’ response in cerebellar cultures. After 2 DIV NG2-glia began to express the astroglial reporter EGFP and in some cases the respective GFAP protein. However, NG2-glia did not acquire phenotypic markers of neural stem cells or neurons. The results suggest that NG2-glia are not lineage restricted OPCs and are a potential source of astrocytes in the cerebellum.     

Characterization of the altered oligosaccharide composition of the insulin receptor on neural-derived cells

Typical insulin receptors are present on neuroblastoma cell lines. High affinity binding for insulin was present in membrane preparations from NG108 (a hybrid mouse neuroblastoma-rat glioma) as well as in membranes from SK-N-MC and SK-N-SH, two human neuroblastoma cell lines. Specific [125I]insulin binding was 24.4% for NG108, 16.9% for SK-N-MC and 5.2% for SK-N-SH at membrane protein concentrations of 0.4 mg/ml. IC50 for [125I]insulin binding was 3.4 nM in NG108 membrane preparations and 0.9 nM for SK-N-SH and 1.8 nM in SK-N-MC membranes. Apparent mol. wt. for the alpha subunits (identified by specific immunoprecipitation using the anti-insulin receptor antiserum B10) on SDS PAGE was 134 kDa for NG108; 124 kDa for SK-N-MC and 120 kDa for SK-N-SH. Neuraminidase digestion increased the mobility of the alpha subunit from both NG108 and SK-N-MC receptors to 120 kDa, whereas that from SK-N-SH were unaffected. Endoglycosidase H and endoglycosidase F digestions increased the mobility of the alpha subunits of all 3 cell lines to varying degrees, suggesting the presence of N-linked glycosylation. Insulin induced autophosphorylation of the insulin receptor beta subunit in WGA-purified membranes from all 3 cell lines. In addition, phosphorylation of a protein with an apparent mol. wt. 105 kDa was stimulated by insulin in WGA purified membranes from NG108. Tyrosine-specific kinase activity was present in the membranes from each cell line and was stimulated by insulin in a dose-dependent manner from 10(-9) to 10(-6) M. Proinsulin was about 100 times less potent in stimulating phosphorylation of the artificial substrate poly (Glu, Tyr)4:1 when compared to insulin in accordance with its lower binding affinity to the insulin receptor. Hexose transport was stimulated by insulin in all 3 cell lines. These results indicate that neuroblastoma cells contain specific insulin receptors and that they may be useful as models for studying the role of insulin in nervous tissue.     

Cellular Distribution of G Protein Goa in Pituitary Lactotrophs: Effects of Dopamine

Membrane-bound GTP-binding (G) proteins mediate signal transduction in a variety of cell systems. The exact mechanisms of G proteins action are still under investigation but they appear to involve effectors located in the plasma membrane as well as in other parts of the cell. With this study, we investigated the cellular and ultrastructural localization of G protein subunits, and particularly of Goa, in normal rat anterior pituitaries and in estrone-induced rat adenomatous lactotrophs. We also evaluated the effects of Goα cellular redistribution in rat adenomatous lactotrophs following short-term exposure to dopamine (DA). Using the Protein A-gold (PAG) methodology, Goα was found to be present in the cysternae of the endoplasmic reticulum of normal pituitary cells and of adenomatous lactotrophs. In the latter, Goα could be co-localized with prolactin (PRL). By immunoblots, using specific antisera, significant amounts of Goα and Gs42α, together with smaller amounts of Giα, Gs47α and Gβ were found to be present in the uncontaminated supernatant fraction of adenomatous lactotrophs. Unexpectedly, exposure of the cells to DA induced a rapid and short-lived decrease in the cytosolic fraction of Goα and Gβ associated with a decrease of PRL release. Since cytosolic Goα can be ADP-ribosylated by pertussis toxin (PT) and is therefore in a heterotrimeric form, our data suggest that the soluble Go protein may play a role during lactotrophs' exposure to an inhibitor of PRL release, perhaps through its relocalization after being internalized with the D₂ receptor or by being used for interaction with intracellular and/or membrane-bound effectors.     

Morphine dependence in human neuroblastoma SH-SY5Y cells is associated with adaptive changes in both the quantity and functional interaction of PGE1 receptors and stimulatory G proteins

Chronic exposure of all-trans-retinoic acid-differentiated SH-SY5Y cells to morphine (10 μM; 2 days) results in sensitization of adenylate cyclase as characterized by a significant increase in both PGE1 receptor-mediated as well as receptor-independent (NaF, 10 mM; forskolin, 100 μM) stimulation of effector activity. To investigate the underlying biochemical alterations, chronic opioid regulation of each of the components comprising the stimulatory PGE, receptor system was examined. On receptor level, chronic morphine treatment was found to reduce PGE₁ receptor number (B_max) by approximately 40%, whereas their affinity slightly increased. Binding experiments performed in the presence of GTPγS (100 μM) further indicate that the decrease in PGE1 receptor density is associated with a loss of functionally G protein-coupled receptors. On post-receptor level, chronic morphine treatment substantially increased the abundance and functional activity of stimulatory G proteins, as assessed by cholera toxin-catalyzed ADP-ribosylation of G_sα and S49 cyc⁻ reconstitution assays. No changes were found on the level of adenylate cyclase. Evaluation of the functional interaction between PGE₁ receptors and G_s in situ by application of a C-terminal anti-G_sα antibody revealed a more intense coupling efficiency between these two entities, since a significant higher amount of antibody (2.3-fold) was required in morphine dependent cell membranes to half-maximally attenuate PGE₁ receptor-stimulated adenylate cyclase activity. In addition, limitation of the amount of functionally available G_sα within the PGE₁ receptor/adenylate cyclase signal transduction cascade abolished the generation of a supersensitive adenylate cyclase response during the state of naloxone (100 μM)-precipitated withdrawal. These data demonstrate that in human neuroblastoma SH-SY5Y cells chronic morphine-induced sensitization of adenylate cyclase is associated with distinct quantitative and qualitative adaptations within the stimulatory adenylate cyclase-coupled PGE₁ receptor system. Thus, alterations in the functional activity of stimulatory receptor systems are suggested to contribute to the cellular mechanisms underlying opioid dependence.     

Evidence for oligomerization between GABAB receptors and GIRK channels containing the GIRK1 and GIRK3 subunits

The stimulation of inhibitory neurotransmitter receptors, such as γ‐aminobutyric acid type B (GABA_B) receptors, activates G protein‐gated inwardly‐rectifying K⁺ (GIRK) channels, which influence membrane excitability. There is now evidence suggesting that G protein‐coupled receptors and G protein‐gated inwardly‐rectifying K⁺ [GIRK/family 3 of inwardly‐rectifying K⁺ (Kir3)] channels do not diffuse freely within the plasma membrane, but instead there are direct protein–protein interactions between them. Here, we used bioluminescence resonance energy transfer, co‐immunoprecipitation, confocal and electron microscopy techniques to investigate the oligomerization of GABA_B receptors with GIRK channels containing the GIRK3 subunit, whose contribution to functional channels is still unresolved. Co‐expression of GABA_B receptors and GIRK channels in human embryonic kidney‐293 cells in combination with co‐immunoprecipitation experiments established that the metabotropic receptor forms stable complexes with GIRK channels. Using bioluminescence resonance energy transfer, we have shown that, in living cells under physiological conditions, GABA_B receptors interact directly with GIRK1/GIRK3 heterotetramers. In addition, we have provided evidence that the receptor–effector complexes are also found in vivo and identified that the cerebellar granule cells are one neuron population where the interaction probably takes place. Altogether, our data show that signalling complexes containing GABA_B receptors and GIRK channels are formed shortly after biosynthesis, probably in the endoplasmic reticulum and/or endoplasmic reticulum/Golgi apparatus complex, suggesting that this might be a general feature of receptor–effector ion channel signal transduction and supporting a channel‐forming role for the GIRK3 subunit.     

GRP78 compartmentalized redistribution in Pb-treated glia: role of GRP78 in lead-induced oxidative stress

Glucose-regulated protein of 78 kDa (GRP78) is an endoplasmic reticulum (ER) molecular chaperone functioning in protein folding, assembly and trafficking. GRP78 also plays a role in protection against cytotoxicity and apoptosis induced by environmental insults. Our previous study showed that lead (Pb) directly targets GRP78 by binding to the protein and increasing GRP78 levels. In this study, the effect of Pb on compartmentalized distribution of GRP78 in living cells was examined. A rat GRP78-EGFP fusion protein and EGFP were transiently expressed in astrocytoma cells exposed to 5 microM Pb acetate or 50 microM CuSO4 and fluorescence signals were captured. Control cells expressing EGFP showed a homogeneous distribution of EGFP that was not changed by Pb or Cu treatment. Cells expressing GRP78-EGFP showed a compartmentalized, non-homogeneous distribution of GRP78-EGFP in the cytosol. The redistribution of GRP78-EGFP fluorescent bodies was observed in cells exposed to Pb for 10 h, but not 5 h. Redistribution was also observed in cells exposed to 50 microM Cu for 5 or 10 h. To assess GRP78 function, GRP78 was depleted with dsRNAi oligos in rat C6 glioma cells. GRP78 depletion significantly increased the sensitivity of cells to Pb exposure as indicated by the generation of reactive oxygen species (ROS). These data suggest that Pb directly targets GRP78 and induces its compartmentalized redistribution in living cells and that GRP78 plays a protective role in Pb neurotoxicity.     

Alzheimer's disease: specific increases in a G protein subunit (Gs alpha) mRNA in hippocampal and cortical neurons.

The GTP binding protein, Gs, activates adenyl cyclase in direct response to stimulation of several neurotransmitter receptors. In situ hybridization histochemistry (ISHH) with a 35S-labelled oligonucleotide has been used to detect the mRNA encoding the alpha subunit of Gs (Gs alpha) in human hippocampus, temporal and visual cortices and cerebellum, and its level has been compared between Alzheimer's disease (AD) and control brains. A marked regional increase was found in the hippocampus of AD cases. Analysis of levels of Gs alpha mRNA in individual constituent pyramidal cells confirmed this increase (3 to 4-fold in densitometric units) in hippocampal fields CA1, CA3 and CA4, as well as in temporal cortex. Levels of Gs alpha mRNA were also determined relative to total poly(A)+ mRNA in the same cell populations in each case. Gene-specific elevation of Gs alpha mRNA was thereby confirmed in hippocampal fields, and also in temporal cortex. No changes were seen in visual cortex. The increase in Gs alpha mRNA may represent a response by AD neurons in affected areas to receptor alterations, or to an abnormality in receptor-G protein coupling. Alternatively, altered G protein gene expression might be a pathogenic event underlying changes in linked receptor populations.     

Prostanoid signaling: dual role for prostaglandin E2 in neurotoxicity

The prostanoids, a naturally occurring subclass of eicosanoids, are lipid mediators generated through oxidative pathways from arachidonic acid. These cyclooxygenase metabolites, consisting of the prostaglandins (PG), prostacyclin and tromboxane, are released in response to a variety of physiological and pathological stimuli in almost all organs, including the brain. They are produced by various cell types and act upon targeted cells via specific G protein-coupled receptors. The existence of multiple receptors, cross-reactivity and coupling to different signal transduction pathways for each prostanoid, collectively establish their diverse effects. Notably, these effects can occur in functionally opposing directions within the same cell or organ. Prostaglandin E(2) (PGE(2)) is the most versatile prostanoid because of its receptors, E Prostanoid (EP) receptor subtypes 1 through 4, its biological heterogeneity and its differential expression on neuronal and glial cells throughout the central nervous system. Since PGE(2) plays an important role in processes associated with various neurological diseases, this review focuses on its dual neuroprotective and neurotoxic role in EP receptor subtype signaling pathways in different models of brain injury.     

Involvement of GPR12 in the induction of neurite outgrowth in PC12 cells

GPR12, an orphan G protein-coupled receptor, constitutively activates the Gs signaling pathway and further increases intracellular cyclic AMP. GPR12 overexpression has been reported to promote neurite extension in neurons or transform neuro2a neuroblastoma cells into neuron-like cells. However, the possible effects and mechanisms of GPR12 in the differentiation of PC12 cells are still unknown. The present study shows that GPR12 overexpression induced PC12 cells differentiation into neuron-like cells with enlarged cell sizes and neuritogenesis possibly via activation of Erk1/2 signaling and significantly increased the expression of several neurite outgrowth-related genes, including Bcl-xL, Bcl-2 and synaptophysin. These findings indicate that GPR12 may play a role in neurite outgrowth during PC12 cell differentiation.     

A single class of neurotensin receptors with high affinity in neuroblastoma X glioma NG108-15 hybrid cells that mediate facilitation of synaptic transmission

Receptor binding of [3H]neurotensin was examined on membrane preparations derived from neuroblastoma X glioma NG108-15 hybrid cells. The specific binding was saturable and reversible, and a dissociation constant (Kd) was calculated to be about 0.24 nM from the rate constants. Scatchard analysis of neurotensin binding at equilibrium revealed a single class of binding sites with a Kd of 0.86 nM and a maximal binding capacity (Bmax) of 250 fmol/mg of protein (7700 receptor sites/cell). [D-Arg9]-Neurotensin had a high affinity (IC50 = 0.5 nM) for the neurotensin receptors, but [D-Phe11]-neurotensin had a lower affinity (IC50 = 280 nM), while angiotensin II and bradykinin had almost no affinity for [3H]neurotensin-binding sites. Under similar conditions [3H]neurotensin binding to mouse and rat brain synaptosomal fractions showed two binding sites with high (0.86 and 0.44 nM) and low (13 and 19 nM) affinities. We have examined several possible physiological consequences of neurotensin receptor binding. Neurotensin (10 microM) exhibited no influence on adenylate cyclase activity, 45Ca uptake, or 32Pi incorporation into phosphatidylinositol fractions of NG108-15 cells. Electrophysiological study of isolated NG108-15 cells revealed neurotensin-induced transient hyperpolarization followed by sustained depolarization with enhanced membrane excitability. Application of neurotensin to NG108-15 cells that had formed synapses with cultured striated muscle cells caused a considerable increase in frequency of miniature endplate potentials from the muscle cells. These data show that NG108-15 cells possess a single class of neurotensin receptors similar to a high affinity site of synaptosomal membranes from the murine brains.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of umami receptor and coupling G protein in mouse taste cells

Taste receptor cells (TRCs) express multiple umami receptors. We performed physiological investigations to determine whether umami-responding cells in taste buds possess G protein-coupled receptors and to determine what type of G proteins exist if any. To clarify the components that participate in intracellular umami signal transduction in mouse, we recorded the activation of TRCs. TRCs treated with the G protein inhibitor GDP-beta-S lost umami-induced inward currents. Treatment with the Galphai inhibitor, pertussis toxin, did not increase the intracellular Ca2+ level in many TRCs. Immunohistochemical analysis revealed that a subset of TRCs responding to umami stimuli expressed alpha-gustducin. Thus, we demonstrated that umami stimuli were received by G protein-coupled receptors that function together with some of the Galphai family members.     

Detection of delta opioid receptor and N-methyl-D-aspartate receptor-like immunoreactivity in retinoic acid-differentiated neuroblastoma x glioma (NG108-15) cells

NG108-15 neuroblastoma cells differentiated with 0.1 M of all-trans retinoic acid (RA) were processed for immunohistochemical analysis using polyclonal antisera against the delta opioid receptor (DOR) and the N-Methyl-D-Aspartate receptor (NMDAR1) to determine the cellular sites for possible functional associations between DOR and NMDAR1 receptors. In this study, 6 days of RA treatment resulted in prominent morphological differentiation characterized by the appearance of numerous axon- and dendrite-like processes and formation of networks between the cell clusters. An immunocytochemical approach allowed the demonstration of antibody concentration-dependent differences, not evident in ligand binding studies, in the distribution of DOR and NMDA receptor protein between cell soma and processes. RA-differentiated cultures showed positive DOR-like immunostaining (DOR-LI) throughout the cell bodies as well as on the newly acquired processes. In contrast, NMDAR1-like immunoreactivity (NMDAR1-LI) in the RA-treated cells was detected in the cell soma and processes only with the higher concentration of the antiserum. With the lower concentration of the antibody the NMDAR1-LI was not detected in the processes and was limited to a punctuate subcellular distribution in the soma. The DOR-LI pattern of distribution in NG108-15 cells differentiated with RA appeared to be consistent with the DOR-LI detected in the CNS. The NMDAR1-LI distribution in these cells is similar to brain tissue with respect to its presence on the newly acquired processes. However, it differed from brain in that a much higher abundance of NMDAR1 receptors was observed in the cell soma. This differential distribution of DOR and NMDAR1 receptors in the RA-treated NG108-15 cells could provide a basis for future studies of drug-induced changes in these two receptors. J. Neurosci. Res. 47:83–89, 1997. © 1997 Wiley-Liss, Inc.