Acetylcholine receptor-like molecules are found in both synaptic and extrasynaptic clusters on the surface of neurons in the frog cardiac ganglion

Sixty monoclonal antibodies (mAbs) made against nicotinic acetylcholine receptors (AChRs) from electric organ were tested for their ability to cross-react at synaptic sites in the frog cardiac ganglion, where transmission is mediated by ACh via nicotinic receptors. Forty-one of the mAbs tested were known to bind to AChRs in frog skeletal muscle (Sargent et al., 1984). As determined by double-label immunofluorescence microscopy, 8 of the 60 mAbs bound to small, punctate sites that lay within areas of synaptic contact, marked by an anti-synaptic vesicle antibody. One of the 8 cross-reacting antibodies that produced particularly intense staining (mAb 22) was chosen for further study and was found to bind to the postsynaptic membrane beneath active zones, as determined by peroxidase immunocytochemistry and electron microscopy. This suggests that mAb 22 crossreacts with AChRs on the ganglion cell surface. While most mAb 22 immunoreactivity was located in the postsynaptic membrane, about 20% of the peroxidase-stained patches were extrasynaptic (327 patches analyzed from 8 ganglia). Virtually no peroxidase-stained patches were observed when an isotype-matched control mAb was used in place of mAb 22. In frog skeletal muscle peroxidase-stained patches obtained with mAb 22 were found exclusively at synaptic sites (179 patches examined from 6 muscles). These results suggest that extrasynaptic patches of AChRs are present in innervated autonomic neurons but not in innervated skeletal muscle.     

Intraspinal opiates for treatment of intractable pain in the terminally ill cancer patient

The discovery of opiate receptors and then their endogenous ligands in 1974 (Snyder et al., 1974) has elucidated a vast pharmacology of opiates providing a basis for their diverse clinical applications. With the awareness of quality of life as a primary goal in terminal cancer patients, widespread attention has been drawn to the direct delivery of long-term intraspinal analgesics to cancer patients for who all medical pain control regimens have failed (Coombs & Saunders, 1974). Intraspinal administration of opiates and nonopiate analgesics is not only appealing on theoretical grounds but provides a minimally invasive method to insure otherwise unobtainable pain relief while eliminating obtundation and systemic side-effects associated with conventional therapy (Cobb et al., 1984; Harbaugh et al., 1982; Leavens et al., 1982; Malone et al., 1985; Onofrie et al., 1981; Poletti et al., 1981). Although intraspinal opiates have been used in the treatment of postoperative and benign-pain syndromes (Asari et al., 1981; Cousins & Mather, 1984), in our discussion we review the basic science, current techniques and possible future improvements in spinal analgesia in the control of chronic cancer pain.     

A molecular basis for interactions between the immune and neuroendocrine systems

Homeostatic and psychologic alterations associated with infections and tumors are very interesting yet poorly understood pathophysiologic responses. Numerous anecdotal and indirect examples suggest that these responses occur through a link between the central nervous and immune systems (for review see Blalock, Bost, & Smith, 1985; Spector & Korneva, 1981; Maestroni & Pierpaoli, 1981; Felton et al., 1985; Jankovic, 1985). Interactions between the two systems are just now being described. One possible mechanism is direct modulation of the immune system by the sympathetic nervous system. This could occur in innervated immune organs such as spleen, thymus, and bone marrow (Felton et al., 1985). The evidence for this is that sympathectomy and lesioning of specific regions of the brain can be shown to both enhance and/or suppress immune responses (Miles et al., 1985; Roszman et al., 1985). Also, the firing rate of hypothalamic neurons is altered during an immune response (Besedovsky et al., 1977). Alternatively, hormonal involvement in immune reactions has been known for some time, in particular the immunosuppressive effects of glucocorticoids (for review see Cupps & Fauci, 1982). Recently, we and others found that neuroendocrine peptide hormones will modulate T and B lymphocytes plus other immunocyte responses (Besedovsky et al., 1977; Cupps & Fauci, 1982; Johnson et al., 1982; Wybran et al., 1979; Hazum, Chang & Cuatrecasas, 1979; O'Dorisio et al., 1981; Gilman et al., 1982; McCain et al., 1982; Mathews et al., 1983; Plotnikoff et al., 1985; Johnson et al., 1984). Furthermore, lymphocytes themselves can synthesize biologically active neuroendocrine hormones (Blalock & Smith, 1980; O'Dorisio et al., 1980; Smith & Blalock, 1981; Smith et al., 1983; Lolait et al., 1984; Ruff & Pert, 1984), as well as possess specific hormone receptors (Blalock et al., 1985; Johnson et al., 1982; Wybran et al., 1979; Hazum et al., 1979; O'Dorisio et al., 1981; Lopker et al., 1980; Payan, Brewster & Goetzl, 1984; Pert et al., 1985). Immune responses (Besedovsky, del Rey & Sorkin, 1981), thymic hormones (Healy et al., 1983), and lymphokines (Lotze et al., 1985; Woloski et al., 1985) have all been shown to exert hormonal effects. Thus, another method for communication between the immune and neuroendocrine systems seems to be through soluble factors such as neuroendocrine hormones. This review will concentrate on the latter topic, in particular on work this laboratory has done over the past few years to show the lymphocyte production and immunoregulatory actions of neuroendocrine hormones.     

Intracellular signaling pathways that regulate dendritic spine morphogenesis

Rac is a member of the Rho family of small GTPases and acts as a molecular switch. When GTP-bound, Rac binds specific effectors to induce downstream signaling events, including actin cytoskeletal rearrangements (Hall, Science 1998;279:509-514). Herein we review the recent evidence suggesting that Rac is involved in the morphogenesis of dendritic spines (Luo et al., Nature 1996;379:837-840; Nakayama et al., J Neurosci 2000; 20:5329-5338). In addition, we discuss how Rac activity is regulated by guanine nucleotide exchange factors, which may be further regulated by extracellular factors. Thus, the Rac signal transduction pathway may provide links between extracellular ligands or synaptic activity and the regulation of the actin cytoskeleton in spine morphogenesis.     

Postsynaptic scaffolds of excitatory and inhibitory synapses in hippocampal neurons: maintenance of core components independent of actin filaments and microtubules.

The mechanisms responsible for anchoring molecular components of postsynaptic specializations in the mammalian brain are not well understood but are presumed to involve associations with cytoskeletal elements. Here we build on previous studies of neurotransmitter receptors (Allison et al., 1998) to analyze the modes of attachment of scaffolding and signal transducing proteins of both glutamate and GABA postsynaptic sites to either the microtubule or microfilament cytoskeleton. Hippocampal pyramidal neurons in culture were treated with latrunculin A to depolymerize actin, with vincristine to depolymerize microtubules, or with Triton X-100 to extract soluble proteins. The synaptic clustering of PSD-95, a putative NMDA receptor anchoring protein and a core component of the postsynaptic density (PSD), was unaffected by actin depolymerization, microtubule depolymerization, or detergent extraction. The same was largely true for GKAP, a PSD-95-interacting protein. In contrast, the synaptic clustering of Ca(2+)/calmodulin-dependent protein kinase II (CaMKII)alpha, another core component of the PSD, was completely dependent on an intact actin cytoskeleton and was partially disrupted by detergent. Drebrin and alpha-actinin-2, actin-binding proteins concentrated in spines, were also dependent on F-actin for synaptic localization but were unaffected by detergent extraction. Surprisingly, the subcellular distributions of the inhibitory synaptic proteins GABA(A)R and gephyrin, which has a tubulin-binding motif, were unaffected by depolymerization of microtubules or actin or by detergent extraction. These studies reveal an unsuspected heterogeneity in the modes of attachment of postsynaptic proteins to the cytoskeleton and support the idea that PSD-95 and gephyrin may be core scaffolding components independent of the actin or tubulin cytoskeleton.     

Enkephalinergic mechanisms in the "compensated" phase of Parkinson's disease

Loss of 70-80% of striatal dopamine (DA) content has been regarded crucial to the onset of Parkinson's Disease (PD) (Bernheimer et al., 1973). Several compensatory mechanisms have been shown to develop in the nigrostriatal DA system which could possibly contribute to the maintenance of DA-ergic transmission at the early stages of the disease. Hornykiewicz (1966) proposed that the preclinical phase of Parkinsonism might be due to compensatory changes that permit residual DA-ergic neurons to subserve functions previously carried out by the entire nigrostriatal projection. One such compensatory mechanism may include increase in transmitter release from the remaining DA-ergic terminals (Agid et al., 1973), increase in the density of the biosynthetic enzymes of DA synthesis (Zigmond et al., 1984), and increase in the number of the D2 DA postsynaptic receptors (Bokobza et al., 1984). However, with further progression of striatal DA loss, these compensatory mechanisms become insufficient in maintaining adequate DA-ergic transmission and the clinical symptoms of the disease become apparent.     

Role of CaCMKII in the cross talk between lonotropic nucleotide and nicotinic receptors in individual cholinergic terminals

Ionotropic P2X receptors for ATP are formed, to date, by seven different subunits named P2X (Torres et al., 1999; Cunha and Ribeiro, 2000; North and Surprenant, 2000; Pintor et al., 2000; Hervás et al., 2003; Miras-Portugal et al., 2003; Illes and Ribeiro, 2004), which are cloned from various mammalian species (Illes and Ribeiro, 2004). These subunits can occur as homo- or hetero-oligomeric assemblies of more than one subunit (North and Surprenant, 2000), except P2X (Miras-Portugal et al., 2003) receptor, which has been described not to coassemble with other subunits (Torres et al., 1999). They are abundantly expressed in the peripheral and central nervous systems and exhibit high permeability to Ca2+ ions (Cunha and Ribeiro, 2000). The existence of presynaptic ionotropic receptors for nucleotides, either for ATP or dinucleotides, has been reported in isolated synaptic terminals from mammalian brain, and both exhibit good permeability to Ca2+ ions (Pintor et al., 2000; Hervás et al., 2003; Miras-Portugal et al., 2003). Studies on isolated single terminals have confirmed the existence of independent and specific responses to ATP and dinucleotides on the same or different terminals (Miras-Portugal et al., 1999; Díaz-Hernández et al., 2002; Hervás et al., 2005; Sánchez-Nogueiro et al., 2005). The activation of presynaptic ionotropic nucleotide receptors can induce the release of other neurotransmitters such as acetylcholine, glutamate, or GABA. In these specific terminals, ionotropic nucleotide receptors can be modulated by interaction with metabotropic receptors, such as GABAB and adenosine receptors (Khakh and Henderson, 1998; Gómez-Villafuertes et al., 2001), and ionotropic, such as nicotinic cholinergic receptors (Díaz-Hernández et al., 2004; Sánchez-Nogueiro et al., 2005). Here, we discuss a relevant finding on the interaction between ionotropic nucleotide and nicotinic receptors in cholinergic synaptic terminals and the role of CaCMKII in this interaction.     

Glutamate receptor targeting in the postsynaptic spine involves mechanisms that are independent of myosin Va

Targeting of glutamate receptors (GluRs) to synapses involves rapid movement of intracellular receptors. This occurs in forms of synaptic upregulation of receptors, such as long-term potentiation. Thus, many GluRs are retained in a cytoplasmic pool in dendrites, and are transported to synapses for upregulation, presumably via motor proteins such as myosins travelling along cytoskeletal elements that extend up into the spine. In this ultrastructural immunogold study of the cerebellar cortex, we compared synapses between normal rats/mice and dilute lethal mutant mice. These mutant mice lack myosin Va, which has been implicated in protein trafficking at synapses. The postsynaptic spine in the cerebellum lacks the inositol trisphosphate receptor (IP3R) -laden reticular tubules that are found in normal mice and rats (Takagishi et al., Neurosci. Lett., 1996, 215, 169). Thus, we tested the hypothesis that myosin Va is necessary for transport of GluRs and associated proteins to spine synapses. We found that these spines retain a normal distribution of (i) GluRs (delta 1/2, GluR2/3 and mGluR1alpha), (ii) at least one associated MAGUK (membrane-associated guanylate kinase) protein, (iii) Homer (which interacts with mGluR1alpha and IP3Rs), (iv) the actin cytoskeleton, (v) the reticulum-associated protein BiP, and (vi) the motor-associated protein, dynein light chain. Thus, while myosin Va may maintain the IP3R-laden reticulum in the spine for proper calcium regulation, other mechanisms must be involved in the delivery of GluRs and associated proteins to synapses. Other possible mechanisms include diffusion along the extrasynaptic membrane and delivery via other motors running along the spine's actin cytoskeleton.     

Hypothalamic compensatory mechanisms in Parkinson's disease

Parkinson's disease (PD) is associated with loss of dopaminergic neurons of the nigrostriatal bundle and to a lesser extent of the mesolimbic and hypothalamic dopaminergic systems. Frank symptoms of the disease usually emerge when at least 70-80% of striatal dopamine (DA) content have been reduced, raising the possibility that the preclinical phase of the disease might be due to compensatory changes that permit residual dopaminergic neurons to subserve functions previously carried out by the entire projection. These neurochemical compensatory mechanisms are known to occur at a striatal level of the rate limiting enzymes of catecholamine synthesis as well as alterations in the sensitivity of the dopaminergic postsynaptic receptors (Zigmond et al., 1984; Bokobza et al., 1984). Compensatory mechanisms, although generally less well recognized, also occur in the hypothalamus and involve endocrine regulation, abnormal neuropeptide release and the emergence of several autonomic and sensory symptoms manifesting prior to or during the course of the disease. Such neurochemical and clinical adaptation mechanisms of the hypothalamus may help to explain the neurobiological events underlying the preclinical phase of Parkinsonism. Moreover, progressive failure of these hypothalamic adaptive mechanisms may be critical in the transition of the disease into the "malignant phase" (Danielczyk et al., 1980).     

Interaction between P2X and nicotinic acetylcholine receptors in glutamate nerve terminals of the rat hippocampus

Nicotinic acetylcholine receptors (nAChRs [constituted by pentameric association of alpha2-10 and beta2-4 subunits]) and P2X receptors (P2XRs [activated by ATP and constituted by multimeric association of P2X1-7 subunits]) are both ionotropic receptors permeable to cations, which have in common the disparity between the wealth of data showing their presence in the brain and little evidence of their participation in mediating synaptic transmission. This has led to the proposal that both nAChRs and P2XRs might primarily modulate rather than directly mediate synaptic transmission, which is in accordance with the predominant presynaptic localization of both receptor subtypes (Role and Berg, 1996; Cunha and Ribeiro, 2000). Interestingly, both functional neurochemical (Allgaier et al., 1995; Salgado et al., 2000; Diáz-Hernández et al., 2002) and electrophysiological studies (Barajas-Lopez et al., 1998; Searl et al., 1998; Zhou and Calligan, 1998; Khakh et al., 2000) indicated a close interaction between nAChRs and P2XRs, which is paralleled by a co-release of ATPand ACh from central terminals (e.g., Richardson and Brown, 1987). Because glutamate release in the hippocampus is controlled by both nAChRs (e.g., McGehee et al., 1995) and P2XRs (Khakh et al., 2003; Rodrigues et al., 2005), we investigated if there was a functional interaction between these two presynaptic ionotropic receptors in the control of glutamate release in the rat hippocampus.     

A postnatal change in the immunological properties of the acetylcholine receptor at rat muscle endplates

We have used a myasthenic serum that in adult rat muscle is specific for acetylcholine receptors (AChRs) in the extra-junctional membrane to characterize the AChRs at developing endplates. Immunocytochemical experiments show that AChRs at endplates in the rat diaphragm bind the myasthenic antibodies during the first week after birth but lose their reactivity during the second and third postnatal weeks. AChRs at endplates in adult rat diaphragm do not bind the antibodies even after denervation; in contrast, AChRs at endplates in an adult chicken muscle (anterior latissimus dorsi) are recognized by the antibodies. The loss of immunological reactivity thus may be correlated with a change in the channel properties of the AChR and with the appearance of synaptic folds, two postnatal developmental changes that occur at the endplates of rats, but not of chickens.     

Neuromuscular junctions contain NP185: the multifunctional protein is located at the presynaptic site.

The NP185 polypeptide (AP3) is a multifunctional component isolated from brain endocytic vesicles, which binds to tubulin and clathrin light chains, decoated vesicles, synaptic vesicles, and the synaptosomal plasma membrane (Su et al., 1991). The NP185 molecules are expressed during avian cerebellar synaptogenesis and appear to function in CNS regions rich in synaptic terminals (Perry et al., 1991). In this report we describe double-labelling experiments with avian embryonic striated muscle fibers demonstrating the exclusive presence of the brain-specific protein at the neuromuscular junction. We used indirect rhodamine immunofluorescence labeling with a monoclonal antibody (mAb-8G8) to mark the location of NP185 in muscle combined with fluorescein-alpha-bungarotoxin to mark the postsynaptic location of the acetylcholine receptors (AChRs). We show that the distribution of both NP185 and AChRs has an overall correlation, but the location of NP185 is circumscribed to presynaptic structures adjacent but not overlapping with postsynaptic structures displaying the AchRs. To confirm the identity of NP185, the molecule was extracted from both tissues, partially purified, immunoprecipitated, and identified in Western blots with the mAb 8G8. The mAb reacted with an identical 185 kD protein band purified from both tissues. Based on its properties and specific neuronal location, the NP185 molecule may function in motor nerve terminals by screening membrane proteins, identifying areas of the synaptic plasma membrane, and to anchor these elements with structural proteins for their recycling and transport within the neuronal cellular compartments.     

Distribution of Ca2+ channels on frog motor nerve terminals revealed by fluorescent omega-conotoxin.

Tetramethylrhodamine-conjugated omega-conotoxin was used as a fluorescent stain (Jones et al., 1989) to determine the spatial distribution of voltage-gated Ca2+ channels along frog motor nerve terminals. Like native omega-conotoxin, the fluorescent toxin blocked neuromuscular transmission irreversibly. The fluorescent staining was confined to the neuromuscular junction and consisted of a series of narrow bands (in face views) or dots (in side views) approximately 1 micron apart. This characteristic staining pattern was prevented by pretreatment with omega-conotoxin and by prior denervation for 5-7 d. Combined fluorescence and phase-contrast optics indicated that the stain was on the synaptic rather than the nonsynaptic side of the nerve terminal. The bands and dots of stain proved to be in spatial register with the postsynaptic junctional folds, as revealed by combined staining of ACh receptors. It is concluded that the voltage-gated Ca2+ channels on frog motor nerve terminals are concentrated at active zones. The findings are consistent with the suggestion (Heuser et al., 1974; Pumplin et al., 1981) that the large intramembraneous particles seen at freeze-fractured active zones are voltage-gated Ca2+ channels.     

Postmitotic, postmigrational expression of tyrosine hydroxylase in olfactory bulb dopaminergic neurons

The developmental expression of tyrosine hydroxylase (TOH) was studied in a large, specific population of dopaminergic (DA) neurons in the main olfactory bulb (MOB) of the rat. These DA neurons comprise an anatomically distinctive population that has been well characterized in the adult hamster (Davis and Macrides, 1983) and rat (Halasz et al., 1981; Baker et al., 1983, 1984). We addressed a basic question in developmental neurobiology: What factors regulate the expression of neuronal transmitter phenotype during development? Olfactory bulb DA neurons are born in the ventricular and subependymal zones and migrate through all intervening layers to the most superficial layer in the bulb (Altman, 1969; Bayer, 1983). The time of TOH expression in these neurons was determined using immunohistochemistry and light microscopic image-analysis techniques. The results indicate that TOH phenotype is not expressed when the cells are born in the subependymal zone nor during their migration to the periglomerular region but only after they reached their final destination, the glomerular layer. This suggests that epigenetic factors associated with the glomeruli initiate the expression of the key transmitter synthesizing enzyme in these neurons. Primary olfactory neurons in the nasal epithelium project exclusively to glomeruli of the MOB; removal of this input in adult rats (Kawano and Margolis, 1982; Baker et al., 1983, 1984), mice (Nadi et al., 1981; Baker et al., 1983), dogs (Nadi et al., 1981), and hamsters (Kream et al., 1984) appears to down-regulate the expression of the TOH in periglomerular cells. The present results suggested that the input from the primary olfactory nerve is also necessary for the initial expression of the TOH phenotype. In support of this notion, we found that lesions of the olfactory nerve during the first postnatal week caused a significant reduction in the number of TOH-positive juxtaglomerular neurons in the following weeks. Thus, the olfactory nerve appears to be necessary for both the initiation and maintenance of TOH expression in olfactory bulb neurons. These findings suggest that specific cell-cell interactions play a key role in CNS neuronal transmitter phenotype regulation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Stoichiometry and pharmacology of two human α4β2 nicotinic receptor types

The alpha4beta2 nicotinic acetylcholine receptor (nAChR) is the most abundant nAChR subtype in the brain, where it forms the high-affinity binding site for nicotine. The alpha4beta2 nAChR belongs to a gene family of ligand-gated ion channels that also includes muscle nAChRs, GABAA receptors, and glycine receptors and that assembles into pentameric structures. alpha4 and beta2 nAChR subunits expressed heterologously in Xenopus laevis oocytes assemble into a mixture of high- and low-affinity functional receptors, giving rise to biphasic ACh concentration-response curves (Zwart and Vijverberg, 1998; Buisson and Bertrand, 2001; Houlihan et al., 2001). High- and low-affinity alpha4beta2 nAChRs differ significantly in their functional and pharmacological properties (Zwart and Vijverberg, 1998; Buisson and Bertrand, 2001; Houlihan et al., 2001; Nelson et al., 2003) and result from the assembly of alpha4 and beta2 subunits into two distinct stoichiometric arrangements: (alpha4)2(beta2)3(high-affinity subtype) and (alpha4)3(beta2)2 (low-affinity subtype) (Nelson et al., 2003). In this study we have examined the functional and pharmacological properties of high- and low-affinity alpha4beta2 receptors using two-electrode voltage clamp procedures on Xenopus oocytes transfected with high (1:10) or low (10:1) ratios of alpha4/beta2 cDNAs, which yield high (1:10)- or low (10:1)- affinity receptors with monophasic ACh concentration- response curves. Furthermore, to determine the stoichiometry of high- and low-affinity receptors expressed heterologously by Xenopus oocytes, we have determined the stoichiometry of high- and low-affinity alpha4beta2 receptors by mutating a highly conserved hydrophobic residue in the middle (position 9') of the pore-lining domain, which increases agonist potency in a manner that allows predictions on subunit composition (Cooper et al., 1991; Revah et al., 1991; Labarca et al., 1995; Boorman et al., 2000).     

Coexpression and spatial association of nicotinic acetylcholine receptor subunits α7 and α10 in rat sympathetic neurons

Fast excitatory synaptic transmission in sympathetic ganglia is mediated by nicotinic acetylcholine receptors (nAChRs). Although it is known that the nAChR alpha7-subunit occurs in sympathetic ganglia, the expression of the recently cloned subunit alpha10 (Elgoyhen et al., 2001; Lustig et al., 2001; Sgard et al., 2002) has not been analyzed. Until now, functional receptors containing alpha10-subunits have been found only in combination with alpha9-subunits (Elgoyhen et al., 2001; Lustig et al., 2001; Sgard et al., 2002). The alpha9-subunit exhibits a restricted expression pattern, whereas the alpha10-subunit is expressed more widely. This broad distribution resembles more closely that known for subunit alpha7 than for subunit alpha9. On this background, we investigated the distribution of nAChR subunits alpha7, alpha9, and alpha10 in rat sympathetic ganglia and studied a possible interaction between subunit alpha7 and potential partners by double-labeling immunofluorescence and fluorescence resonance energy transfer (FRET) (Kam et al., 1995; Jares-Erijman and Jovin, 2003).     

Developmental expression of the 43K and 58K postsynaptic membrane proteins and nicotinic acetylcholine receptors in Torpedo electrocytes

The expression of the postsynaptic 43-kDa and 58-kDa proteins and actin during development of the Torpedo marmorata electric organ was compared to that of nicotinic acetylcholine receptors (AChRs). Western blot analysis demonstrates that AChRs and proteins of 43 kDa (43K protein) and 58 kDa (58K protein) are all present prior to synaptogenesis. Subsequently, levels of all 3 synaptic proteins increase dramatically during differentiation and innervation of electrocytes. In contrast, actin is present in relatively high concentrations at early times and decreases thereafter. The equimolar ratio of AChRs and the 43K protein found in the adult electric organ is established early in development. Furthermore, the AChR and 43K protein share a common postsynaptic localization in electrocytes following synapse formation. Aggregates of the AChR that form at the ventral pole of the oval-shaped electrocytes prior to innervation, however, show no detectable immunofluorescence staining with anti-43K monoclonal antibodies. Therefore, in some cases, aggregation of AChRs occurs without the 43K protein.     

The use of astrocytes in culture as model systems for evaluating neurotoxic-induced-injury.

The prevailing thought that astrocytes function predominantly as passive metabolic or even physical support for neurons has faded over the last 20 years. Today these stellar shaped cells are credited with an expanded role, playing key functions in CNS development, homeostasis, and pathology. In probing their expanded roles, primary astrocyte culture systems have proven to be an indispensable tool. Astrocytes have been implicated in both a defensive and facilitatory capacity for many toxic injuries. Evidence for a protective role of astrocytes in modulating CNS toxicity is afforded by observations that the toxicity of glutamate to cortical neurons is diminished upon astrocytic enrichment of the cell culture (Rosenberg and Aizenman, 1989). In cultures of rat cerebral cortex in which astrocyte proliferation is stringently suppressed, glutamate neurotoxicity occurs at low glutamate concentrations similar to those which are normally found in the extracellular space in the hippocampus. In the presence of excess astrocytes, concentrations of glutamate one-hundred fold higher are required to produce equivalent neurotoxicity (Rosenberg and Aizenman, 1989). Astrocytes can facilitate the action of neurotoxins via a modulating process which takes place within the astrocyte or by a direct cytotoxic effect. Whereas primary astrocyte cultures remain unaffected by 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP; Marini et al., 1989), they function prominently in the selective destruction of dopaminergic neurons of the nigrostriatal pathway in humans, other primates and rodents (Davis et al. 1979; Langston et al., 1983; Burns et al., 1983; Langston et al., 1984; Heikkila et al., 1984; Jarvis and Wagner, 1985). Thus, while MPTP by itself is not toxic to cerebellar cells in co-culture with cerebellar astrocytes, MPTP is toxic to the granule cells (Marini et al, 1989). This is thought to be due to an astrocyte-mediated conversion of MPTP to its highly polar and toxic metabolite, 1-methyl-4-phenylpyridinium ion (MPP+; Chiba et al. 1984). There is compelling evidence that astrocytes respond directly or indirectly to a number of other neurotoxins. Direct cytotoxic effects on astrocytes constitute the major morphologic feature in hyperammonemia (Norenberg, 1981), a condition implicated as an etiologic factor in several CNS disorders. In addition, a predisposition of astrocytes for methylmercury uptake (Aschner et al., 1990 a,b) offers a possible explanation for the observed neurotoxicity of this heavy metal, since a direct toxic effect on astrocytes would result in failure of astrocyte homeostatic functions, indirectly resulting in neuronal impairment, injury and death.