Characterization, distribution, and protein kinase C-mediated regulation of [35S]glutathione binding sites in mouse and human spinal cord

Ferroptosis-Related Genes in Neurodevelopment and Central Nervous System

Ferroptosis, first introduced as a new form of regulated cell death induced by erastin, is accompanied by the accumulation of iron and lipid peroxides, thus it can be inhibited either by iron chelators or by lipophilic antioxidants. In the past decade, multiple studies have introduced the potential importance of ferroptosis in many human diseases, including cancer and neurodegenerative diseases. In this review, we will discuss the genetic association of ferroptosis with neurological disorders and development of the central nervous system.

Nanocarriers for brain specific delivery of anti-retro viral drugs: challenges and achievements

HIV/AIDS is a global pandemic and the deleterious effects of human immunodeficiency virus in the brain cannot be overlooked. Though the current anti-retro viral therapy is able to reduce the virus load in the peripheral tissues of the body, the inability of the anti-retro viral drugs to cross the blood brain barrier, as such, limits its therapeutic effect in the brain. The development of newer, successful nanoparticulate drug delivery systems to enhance the feasibility of the anti-retro viral drugs to the brain, offers a novel strategy to treat the AIDS-related neuronal degradation. This review summarised the neuropathogenesis of neuroAIDS, the challenges and achievements made in the delivery of therapeutics across the BBB and the use of nanocarriers as a safe and effective way for delivering anti-retro viral drugs to the brain.

Gclc deficiency in mouse CNS causes mitochondrial damage and neurodegeneration

Gamma glutamyl cysteine ligase (GCL) is the rate-limiting enzyme for intracellular glutathione (GSH) synthesis. The GSH concentration and GCL activity are declining with age in the central nervous system (CNS), and is accompanied by elevated reactive oxygen species (ROS). To study the biological effects of low GSH levels, we disrupted its synthesis both at birth by breeding a Gclc loxP mouse with a thy1-cre mouse (NEGSKO mouse) and at a later age by breeding with a CaMKII-ERT2-Cre (FIGSKO mouse). NEGSKO mice with deficiency of the Gclc in their entire CNS neuronal cells develop at 4 weeks: progressive motor neuron loss, gait problems, muscle denervation and atrophy, paralysis, and have diminished life expectancy. The observed neurodegeneration in Gclc deficiency is of more chronic rather than acute nature as demonstrated by Gclc targeted single-neuron labeling from the inducible Cre-mediated knockout (SLICK) mice. FIGSKO mice with inducible Gclc deficiency in the forebrain at 23 weeks after tamoxifen induction demonstrate profound brain atrophy, elevated astrogliosis and neurodegeneration, particularly in the hippocampus region. FIGSKO mice also develop cognitive abnormalities, i.e. learning impairment and nesting behaviors based on passive avoidance, T-Maze, and nesting behavior tests. Mechanistic studies show that impaired mitochondrial glutathione homeostasis and subsequent mitochondrial dysfunction are responsible for neuronal cell loss. This was confirmed by mitochondrial electron transporter chain activity analysis and transmission electron microscopy that demonstrate remarkable impairment of state 3 respiratory activity, impaired complex IV function, and mitochondrial swollen morphology in the hippocampus and cerebral cortex. These mouse genetic tools of oxidative stress open new insights into potential pharmacological control of apoptotic signaling pathways triggered by mitochondrial dysfunction.

Targeting brain cells with glutathione-modulated nanoliposomes: in vitro and in vivo study

Background

The blood–brain barrier prevents many drug moieties from reaching the central nervous system. Therefore, glutathione-modulated nanoliposomes have been engineered to enhance the targeting of flucytosine to the brain.

Methods

Glutathione-modulated nanoliposomes were prepared by thin-film hydration technique and evaluated in the primary brain cells of rats. Lecithin, cholesterol, and span 65 were mixed at 1:1:1 molar ratio. The molar percentage of PEGylated glutathione varied from 0 mol% to 0.75 mol%. The cellular binding and the uptake of the targeted liposomes were both monitored by epifluorescent microscope and flow cytometry techniques. A biodistribution and a pharmacokinetic study of flucytosine and flucytosine-loaded glutathione–modulated liposomes was carried out to evaluate the in vivo brain-targeting efficiency.

Results

The size of glutathione-modulated nanoliposomes was <100 nm and the zeta potential was more than −65 mV. The cumulative release reached 70% for certain formulations. The cellular uptake increased as molar percent of glutathione increased to reach the maximum at 0.75 mol%. The uptake of the targeted liposomes by brain cells of the rats was three times greater than that of the nontargeted liposomes. An in vivo study showed that the relative efficiency was 2.632±0.089 and the concentration efficiency was 1.590±0.049, and also, the drug-targeting index was 3.670±0.824.

Conclusion

Overall, these results revealed that glutathione-PEGylated nanoliposomes enhance the effective delivery of flucytosine to brain and could become a promising new therapeutic option for the treatment of the brain infections.

Taurine release in developing mouse hippocampus is modulated by glutathione and glutathione derivatives

Glutathione (reduced form GSH and oxidized form GSSG) constitutes an important defense against oxidative stress in the brain, and taurine is an inhibitory neuromodulator particularly in the developing brain. The effects of GSH and GSSG and glycylglycine, gamma-glutamylcysteine, cysteinylglycine, glycine and cysteine on the release of [(3)H]taurine evoked by K+-depolarization or the ionotropic glutamate receptor agonists glutamate, kainate, 2-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) and N-methyl-D-aspartate (NMDA) were now studied in slices from the hippocampi from 7-day-old mouse pups in a perfusion system. All stimulatory agents (50 mM K(+), 1 mM glutamate, 0.1 mM kainate, 0.1 mM AMPA and 0.1 mM NMDA) evoked taurine release in a receptor-mediated manner. Both GSH and GSSG significantly inhibited the release evoked by 50 mM K+. The release induced by AMPA and glutamate was also inhibited, while the kainate-evoked release was significantly activated by both GSH and GSSG. The NMDA-evoked release proved the most sensitive to modulation: L-Cysteine and glycine enhanced the release in a concentration-dependent manner, whereas GSH and GSSG were inhibitory at low (0.1 mM) but not at higher (1 or 10 mM) concentrations. The release evoked by 0.1 mM AMPA was inhibited by gamma-glutamylcysteine and cysteinylglycine, whereas glycylglycine had no effect. The 0.1 mM NMDA-evoked release was inhibited by glycylglycine and gamma-glutamylcysteine. In turn, cysteinylglycine inhibited the NMDA-evoked release at 0.1 mM, but was inactive at 1 mM. Glutathione exhibited both enhancing and attenuating effects on taurine release, depending on the glutathione concentration and on the agonist used. Both glutathione and taurine act as endogenous neuroprotective effectors during early postnatal life.

Glutathione pathways in the brain

The antioxidant glutathione (GSH) is essential for the cellular detoxification of reactive oxygen species in brain cells. A compromised GSH system in the brain has been connected with the oxidative stress occuring in neurological diseases. Recent data demonstrate that besides intracellular functions GSH has also important extracellular functions in brain. In this respect astrocytes appear to play a key role in the GSH metabolism of the brain, since astroglial GSH export is essential for providing GSH precursors to neurons. Of the different brain cell types studied in vitro only astrocytes release substantial amounts of GSH. In addition, during oxidative stress astrocytes efficiently export glutathione disulfide (GSSG). The multidrug resistance protein 1 participates in both the export of GSH and GSSG from astrocytes. This review focuses on recent results on the export of GSH and GSSG from brain cells as well as on the functions of extracellular GSH in the brain. In addition, implications of disturbed GSH pathways in brain for neurodegenerative diseases will be discussed.

Metabolism and functions of glutathione in brain

The tripeptide glutathione is the thiol compound present in the highest concentration in cells of all organs. Glutathione has many physiological functions including its involvement in the defense against reactive oxygen species. The cells of the human brain consume about 20% of the oxygen utilized by the body but constitute only 2% of the body weight. Consequently, reactive oxygen species which are continuously generated during oxidative metabolism will be generated in high rates within the brain. Therefore, the detoxification of reactive oxygen species is an essential task within the brain and the involvement of the antioxidant glutathione in such processes is very important. The main focus of this review article will be recent results on glutathione metabolism of different brain cell types in culture. The glutathione content of brain cells depends strongly on the availability of precursors for glutathione. Different types of brain cells prefer different extracellular glutathione precursors. Glutathione is involved in the disposal of peroxides by brain cells and in the protection against reactive oxygen species. In coculture astroglial cells protect other neural cell types against the toxicity of various compounds. One mechanism for this interaction is the supply by astroglial cells of glutathione precursors to neighboring cells. Recent results confirm the prominent role of astrocytes in glutathione metabolism and the defense against reactive oxygen species in brain. These results also suggest an involvement of a compromised astroglial glutathione system in the oxidative stress reported for neurological disorders.

Specific glutathione binding sites in pig cerebral cortical synaptic membranes

Glutathione (gamma-glutamylcysteinylglycine) is a neuromodulator at glutamate receptors, but may also act as a neurotransmitter at sites of its own. The Na+-independent binding of [3H]glutathione to pig cortical synaptic membranes was characterized here using glycine, cysteine analogs, dipeptides and glutathione derivatives, and ligands selective for known glutamate receptors. L-Glutamate, pyroglutamate, quinolinate, (S)-5-fluorowillardiine and 6-nitro-7-sulfamoylbenzo[f]quinoxaline-2,3-dione were weak inhibitors at concentrations of 0.5 or 1 mM. D-Glutamate, L- and D-aspartate, glutamine, quisqualate, kynurenate, other N-methyl-D-aspartate receptor ligands and non-N-methyl-D-aspartate receptor ligands failed to displace [3H]glutathione. Except for weak inhibition by D-serine (0.5 mM), glycine and other ligands of the glycine co-activatory site in the N-methyl-D-aspartate receptors had no displacing effect. Similarly, metabotropic glutamate group I, II and III receptor agonists and antagonists and compounds acting at the glutamate uptake sites were generally inactive. Glutathione, oxidized glutathione, S-nitrosoglutathione, gamma-L-glutamylcysteine, cysteinylglycine, cysteine, cysteamine and cystamine were the most potent displacers (IC50 values in the micromolar range), followed by dithiothreitol, glutathione sulfonate and the S-alkyl derivatives of glutathione (S-methyl-, -ethyl-, -propyl-, -butyl- and -pentylglutathione). L-Homocysteinate and aminomethanesulfonate exhibited a moderate efficacy. Thiokynurenate, a cysteine analog and an antagonist at the N-methyl-D-aspartate receptor glycine co-activatory site, was a potent activator of glutathione binding. At 1 mM, some dipeptides also slightly activated the binding, gamma-L-glutamylleucine and gamma-L-glutamyl-GABA being the most effective. The specific binding sites for glutathione in brain synaptic membranes are not identical to any known excitatory amino acid receptor. The cysteinyl moiety is crucial in the binding of glutathione. The oxidation or alkylation of the cysteine thiol group reduces the binding affinity. The strong activation by thiokynurenate may indicate that the glutathione receptor protein contains a modulatory site to which co-agonists may bind and allosterically activate glutathione binding. The novel population of specific binding sites of glutathione gives rise to the possibility that they may have profound effects on synaptic functions in the mammalian central nervous system. The glutathione binding sites may be an important, and for the most part unrecognized, component in signal transduction in the brain.

Glutathione and signal transduction in the mammalian CNS

The tripeptide glutathione (GSH) has been thoroughly investigated in relation to its role as antioxidant and free radical scavenger. In recent years, novel actions of GSH in the nervous system have also been described, suggesting that GSH may serve additionally both as a neuromodulator and as a neurotransmitter. In the present article, we describe our studies to explore further a potential role of GSH as neuromodulator/neurotransmitter. These studies have used a combination of methods, including radioligand binding, synaptic release and uptake assays, and electrophysiological recording. We report here the characteristics of GSH binding sites, the interrelationship of GSH with the NMDA receptor, and the effects of GSH on neural activity. Our results demonstrate that GSH binds via its gamma-glutamyl moiety to ionotropic glutamate receptors. At micromolar concentrations GSH displaces excitatory agonists, acting to halt their physiological actions on target neurons. At millimolar concentrations, GSH, acting through its free cysteinyl thiol group, modulates the redox site of NMDA receptors. As such modulation has been shown to increase NMDA receptor channel currents, this action may play a significant role in normal and abnormal synaptic activity. In addition, GSH in the nanomolar to micromolar range binds to at least two populations of binding sites that appear to be distinct from all known excitatory amino acid receptor subtypes. GSH bound to these sites is not displaceable by glutamatergic agonists or antagonists. These binding sites, which we believe to be distinct receptor populations, appear to recognize the cysteinyl moiety of the GSH molecule. Like NMDA receptors, the GSH binding sites possess a coagonist site(s) for allosteric modulation. Furthermore, they appear to be linked to sodium ionophores, an interpretation supported by field potential recordings in rat cerebral cortex that reveal a dose-dependent depolarization to applied GSH that is blocked by the absence of sodium but not by lowering calcium or by NMDA or (S)-2-amino-3-hydroxy-5-methyl-4-isoxazolepropionate antagonists. The present data support a reevaluation of the role of GSH in the nervous system in which GSH may be involved both directly and indirectly in synaptic transmission. A full accounting of the actions of GSH may lead to more comprehensive understanding of synaptic function in normal and disease states.

Potentiation of excitotoxic injury by high concentrations of extracellular reduced glutathione

Glutathione is present in the central nervous system in millimolar concentrations, and is a predominant intracellular antioxidant and detoxicant. In addition, glutathione is released into the extracellular space via a depolarization-enhanced process. Although the role of extracellular glutathione has not been precisely defined, a growing body of experimental evidence suggests that it has multifaceted electrophysiological effects. At low micromolar concentrations, glutathione depolarizes neurons by binding to its own receptors and modulates glutamatergic excitatory neurotransmission by displacing glutamate from its ionotropic receptors. At higher concentrations, reduced glutathione may increase N-methyl-D-aspartate receptor responses by interacting with its redox sites. In this study, the effect of extracellular glutathione on excitotoxic neuronal injury was quantitatively assessed in murine cortical cell cultures. Neuronal death due to 20-25 h exposure to 6-9 microM N-methyl-D-aspartate was not altered by 10-100 microM reduced glutathione but was markedly enhanced by 300-1000 microM reduced glutathione; kainate neurotoxicity was unaffected. Two related compounds that lack a sulfhydryl group, oxidized glutathione and S-hexylglutathione, had no significant effect on N-methyl-D-aspartate neurotoxicity alone but completely blocked the effect of reduced glutathione. Mercaptoethanol, a sulfhydryl reducing agent that increases N-methyl-D-aspartate receptor responses by interacting with redox sites, increased N-methyl-D-aspartate neurotoxicity to a degree comparable to that of reduced glutathione; this effect was also blocked by equimolar S-hexylglutathione or oxidized glutathione. Addition of reduced glutathione to mercaptoethanol did not further increase N- methyl-D-aspartate-induced neuronal death. These results suggest that release of reduced glutathione from central nervous system cells that are subjected to traumatic or ischemic insults may enhance excitotoxic neuronal loss. Although multiple mechanisms may account for this phenomenon, the high concentrations required suggest that it is at least partly mediated by reduction of N-methyl-D-aspartate receptor redox sites.

Evidence of glutathione transporter in rat brain synaptosomal membrane vesicles

Glutathione (GSH) transport was studied in synaptosomal membrane vesicles (SMV) of rat cerebral cortex. The present study shows that GSH uptake into SMV occurs very quickly in a time-dependent manner into an osmotically active intravesicular space. The initial rate of transport followed Michealis-Menten saturation kinetics with a Km 4.5+/-0.8 microM that shows a high affinity of the transporter for GSH. Therefore GSH uptake in SMV occurs by a mediated transport system which can be activated by either an inward gradient of cations, like Na+ or K+, or membrane depolarization. These results, together with those obtained by valinomycin-induced K+ diffusion potential, indicate that GSH synaptosomal transport is electrogenic by a negative charge transfer. The increase of GSH uptake measured by trans-stimulation experiments confirms a GSH bidirectional mediated transport which seems susceptible of modulation by changes in ionic fluxes and in the membrane potential. These results may indicate a possible involvement of this transporter in the role suggested for GSH in synaptic neurotransmission; also considering that GSH precursor of neuroactive aminoacids (glycine, glutamate), may contribute to regulate their level in synapses. Finally, a GSH transporter in synaptosomes may contribute to maintaining the GSH homeostasis in cerebral cortex, where decreases of GSH levels have been related to susceptibility to neuropathologies.

Extracellular reduced glutathione increases neuronal vulnerability to combined chemical hypoxia and glucose deprivation

In addition to its intracellular antioxidant role, reduced glutathione (GSH) is released by CNS cells and may mediate or modulate excitatory neurotransmission. Although extracellular GSH levels rise in the ischemic cortex, its effect on the viability of energy-compromised neurons has not been defined. In this study, we tested the hypothesis that exogenous GSH would increase the vulnerability of cultured cortical neurons to azide-induced chemical hypoxia combined with glucose deprivation. Thirty minutes azide exposure in a glucose-free buffer was tolerated by most neurons, with release of less than 10% of neuronal LDH over the subsequent 21-25 h. Concomitant treatment with 10-100 microM GSH increased cell death in a concentration-dependent fashion, to 71.6+/-5.1% of neurons at 100 microM; GSH alone was nontoxic. Injury was blocked by the selective N-methyl-d-aspartate (NMDA) antagonist MK-801 but not by the AMPA/kainate antagonist NBQX. The sulfhydryl reducing agent mercaptoethanol (10-100 microM) mimicked the action of GSH; however, the zinc chelator ethylenediaminetetraacetic acid (EDTA) was ineffective. Two GSH analogues that lack a sulfhydryl group, S-hexylglutathione (SHG) and oxidized glutathione (GSSG), were inactive per se but attenuated the effect of both GSH and mercaptoethanol. These results suggest that micromolar concentrations of GSH enhance neuronal loss due to energy depletion by altering the extracellular redox state, resulting in increased NMDA receptor activation.

Interference of S-alkyl derivatives of glutathione with brain ionotropic glutamate receptors

The effects of glutathione, glutathione sulfonate and S-alkyl derivatives of glutathione on the binding of glutamate and selective ligands of ionotropic N-methyl-D-aspartate (NMDA) and non-NMDA receptors were studied with mouse synaptic membranes. The effects of glutathione and its analogues on 45Ca2+ influx were also estimated in cultured rat cerebellar granule cells. Reduced and oxidized glutathione, glutathione sulfonate, S-methyl-, -ethyl-, -propyl-, -butyl- and -pentylglutathione inhibited the Na+-independent binding of L-[3H]glutamate. They strongly inhibited also the binding of (S)-2-amino-3-hydroxy-5-[3H]methyl-4-isoxazolepropionate [3H]AMPA (IC50 values: 0.8-15.9 microM). S-Alkylation of glutathione rendered the derivatives unable to inhibit [3H]kainate binding. The NMDA-sensitive binding of L-[3H]glutamate and the binding of 3-[(R)-2-carboxypiperazin-4-yl][1,2-(3)H]propyl-1-phosphonate ([3H]CPP, a competitive antagonist at NMDA sites) were inhibited by the peptides at micromolar concentrations. The strychnine-insensitive binding of the NMDA coagonist [3H]glycine was attenuated only by oxidized glutathione and glutathione sulfonate. All peptides slightly enhanced the use-dependent binding of [3H]dizocilpine (MK-801) to the NMDA-gated ionophores. This effect was additive with the effect of glycine but not with that of saturating concentrations of glutamate or glutamate plus glycine. The glutamate- and NMDA-evoked influx of 45Ca2+ into cerebellar granule cells was inhibited by the S-alkyl derivatives of glutathione. We conclude that besides glutathione the endogenous S-methylglutathione and glutathione sulfonate and the synthetic S-alkyl derivatives of glutathione act as ligands of the AMPA and NMDA receptors. In the NMDA receptor-ionophore these glutathione analogues bind preferably to the glutamate recognition site via their gamma-glutamyl moieties.

Neurodegenerative disorders in humans: the role of glutathione in oxidative stress-mediated neuronal death

Oxidative stress has been implicated in both normal aging and in various neurodegenerative disorders and may be a common mechanism underlying various forms of cell death including necrosis, apoptosis, and excitotoxicity. In this review, we develop the hypothesis that oxidative stress-mediated neuronal loss may be initiated by a decline in the antioxidant molecule glutathione (GSH). GSH plays multiple roles in the nervous system including free radical scavenger, redox modulator of ionotropic receptor activity, and possible neurotransmitter. GSH depletion can enhance oxidative stress and may also increase the levels of excitotoxic molecules; both types of action can initiate cell death in distinct neuronal populations. Evidence for a role of oxidative stress and diminished GSH status is presented for Lou Gehrig's disease (ALS), Parkinson's disease, and Alzheimer's disease. Potential links to the Guamanian variant of these diseases (ALS-PD complex) are discussed. In context to the above, we provide a GSH-depletion model of neurodegenerative disorders, suggest experimental verifications of this model, and propose potential therapeutic approaches for preventing or halting these diseases.

Glutathione is an endogenous ligand of rat brain N-methyl-D-aspartate (NMDA) and 2-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) receptors

A study was made of the effects of reduced (GSH) and oxidized (GSSG) glutathione on the Na(+)-independent and N-methyl-D-aspartate (NMDA) displaceable bindings of glutamate, on the binding of kainate, 2-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA), and ligand of the brain NMDA receptor-ionophore complex: glycine, dizocilpine (MK-801) and (+/-)-3-(2-carboxypiperazin-4-yl)propyl-1-phosphonate (CPP). GSH and GSSG strongly inhibited the binding of glutamate, CPP and AMPA, kainate and glycine binding being less affected. Both peptides enhanced the binding of dizocilpine in a time- and concentration-dependent manner. This activatory effect was not additive to that of saturating concentrations of glutamate or glutamate plus glycine. The activation of dizocilpine binding by GSH and GSSG was prevented by the competitive NMDA and glycine antagonists DL-2-amino-5-phosphonovalerate and 7-chlorokynurenate. GSH and GSSG may be endogenous ligands of AMPA and NMDA receptors, binding preferably to the glutamate recognition site via their gamma-glutamyl moieties. In addition to this, at millimolar concentrations they may regulate the redox state of the NMDA receptor-ionophore complex.

The gamma-glutamyl transpeptidase inhibitor acivicin preserves glutathione released by astroglial cells in culture

The release of glutathione from astroglial cells was investigated using astroglia-rich primary cultures prepared from the brains of newborn rats. These cells release glutathione after onset of an incubation in a glucose-containing minimal medium. The amount of extracellular glutathione increased with the time of incubation, although the accumulation slowed down gradually. An elevated rate of increase of the glutathione concentration in the incubation medium was found if the astroglial ectoenzyme gamma-glutamyl transpeptidase was inhibited by acivicin. The activity of gamma-glutamyl transpeptidase in astroglia-rich primary cultures, which was found to be 1.9 +/- 0.3 nmol/(min x mg protein), was markedly reduced if the cells had been incubated in the presence of acivicin. After 2 h of incubation with acivicin half-maximal and maximal inhibition of gamma-glutamyl transpeptidase activity was found at concentrations of about 5 microM and 50 microM, respectively. In the presence of acivicin at a concentration above 10 microM the glutathione content found released from astroglial cells apparently increased almost proportional to time for up to 10 h. Under these conditions the average rate of release was 2.1 +/- 0.3 nmol/(h x mg protein) yielding after a 10 h incubation an extracellular glutathione content three times that of the medium of cells incubated without inhibitor. Half-maximal and maximal effects on the level of extracellular glutathione were found at 4 microM and 50 microM acivicin, respectively. After a 10 h incubation with acivicin the intracellular content of glutathione was reduced to 75% of the level of untreated astroglial cultures. These results suggest that glutathione released from astroglial cells can serve as substrate for the ectoenzyme gamma-glutamyl transpeptidase of these cells.

Amyotrophic lateral sclerosis: the involvement of intracellular Ca2+ and protein kinase C

The neurodegenerative disease, amyotrophic lateral sclerosis (ALS), is characterized by the selective death of motoneurones and corticospinal tract neurones. Abnormalities in excitatory amino acids and their receptors, as well as disordered function of voltage-dependent Ca2+ channels and superoxide dismutase have been reported in ALS patients. Furthermore, the activity of protein kinase C (PKC), a Ca2+, phospholipid-dependent enzyme, is also substantially increased in tissue from ALS patients, suggesting that alterations in intracellular free Ca2+ may be central to many of the diverse pathogenic mechanisms potentially responsible for ALS as discussed here by Charles Krieger and colleagues. Increased PKC activity, in turn, may have direct or indirect effects on neuronal viability and influence the pathogenic process in ALS by modifying the phosphorylation of voltage-dependent Ca2+ channels, neurotransmitter receptors and structural proteins.

Immunocytochemical evidence for the presence of high levels of reduced glutathione in radial glial cells and horizontal cells in the rabbit retina

Reduced glutathione is an antioxidant; it is thought to be essential for normal functioning of the central nervous system. We have examined by means of immunocytochemistry, the distribution of reduced glutathione in the retina of the rabbit. Strong immunoreactivity was present in the radial glial cells (Müller cells) and in the horizontal cells. Other neuronal elements contained only low, or no detectable levels of immunoreactivity for reduced glutathione. The presence of an abundance of reduced glutathione in glial cells suggests that glia play a critical role in regulating the content of potentially damaging oxidative species in the central nervous system.