Xenon-mediated neuroprotection in response to sustained, low-level excitotoxic stress.

Noble gases such as xenon and argon have been reported to provide neuroprotection against acute brain ischemic/anoxic injuries. Herein, we wished to evaluate the protective potential of these two gases under conditions relevant to the pathogenesis of chronic neurodegenerative disorders. For that, we established cultures of neurons typically affected in Alzheimer's disease (AD) pathology, that is, cortical neurons and basal forebrain cholinergic neurons and exposed them to L-trans-pyrrolidine-2,4-dicarboxylic acid (PDC) to generate sustained, low-level excitotoxic stress. Over a period of 4 days, PDC caused a progressive loss of cortical neurons which was prevented substantially when xenon replaced nitrogen in the cell culture atmosphere. Unlike xenon, argon remained inactive. Xenon acted downstream of the inhibitory and stimulatory effects elicited by PDC on glutamate uptake and efflux, respectively. Neuroprotection by xenon was mimicked by two noncompetitive antagonists of NMDA glutamate receptors, memantine and ketamine. Each of them potentiated xenon-mediated neuroprotection when used at concentrations providing suboptimal rescue to cortical neurons but most surprisingly, no rescue at all. The survival-promoting effects of xenon persisted when NMDA was used instead of PDC to trigger neuronal death, indicating that NMDA receptor antagonism was probably accountable for xenon's effects. An excess of glycine failed to reverse xenon neuroprotection, thus excluding a competitive interaction of xenon with the glycine-binding site of NMDA receptors. Noticeably, antioxidants such as Trolox and N-acetylcysteine reduced PDC-induced neuronal death but xenon itself lacked free radical-scavenging activity. Cholinergic neurons were also rescued efficaciously by xenon in basal forebrain cultures. Unexpectedly, however, xenon stimulated cholinergic traits and promoted the morphological differentiation of cholinergic neurons in these cultures. Memantine reproduced some of these neurotrophic effects, albeit with less efficacy than xenon. In conclusion, we demonstrate for the first time that xenon may have a therapeutic potential in AD.

Piperazine derivatives as iron chelators: a potential application in neurobiology.

Polysubstituted piperazine derivatives, designed as new iron chelators, were synthesized and fully characterized by nuclear magnetic resonance and mass spectroscopy. Their potential to prevent iron-induced neurotoxicity was assessed using a cellular model of Parkinson disease. We demonstrated their ability to provide sustained neuroprotection to dopaminergic neurons that are vulnerable in this pathology. The iron chelating properties of the new compounds were determined by spectrophotometric titration illustrating that high affinity for iron is not associated with important neuroprotective effects.

In search of innovative therapeutics for neuropsychiatric disorders: the case of neurodegenerative diseases.

The recent medical literature highlights the lack of new drugs able to prevent or treat neurodegenerative diseases such as Alzheimer disease or Parkinson disease. Yet, the prevalence of these diseases is growing, related to increasing life expectancy, and is leading to a rise in their economic and social cost. At the same time, pharmaceutical companies are reducing or halting their investment in neuropharmacological research. Why have advances in basic neuroscience and our understanding of these diseases not allowed innovative discoveries in drug research? This review will try to explain this failure and suggest possible solutions: develop basic and clinical research but with the emphasis on translational and truly collaborative research; improve preclinical studies by developing more appropriate animal models, using new biomarkers and methodologies such as imaging suitable for clinical trials, providing worthwhile information on the ability of the drug to reach its intended target and induce significant pharmacological changes; build a new system of research management, based on stronger interdisciplinary relations between preclinical and clinical research and including the introduction of international precompetitive research between academic teams, start-up companies and pharmaceutical laboratories; hold early discussions with the regulatory authorities during preclinical studies and at the beginning of clinical trials in order to validate the methodological approaches; involve patients' associations in this new organization of research. These changes should help to ensure the discovery of effective treatments for these pathologies.

Iron transport in Parkinson's disease.

Dopaminergic cell death in the substantia nigra (SN) is central to Parkinson's disease (PD) but the neurodegenerative mechanisms have not been completely elucidated. Iron accumulation in dopaminergic neurons and glial cells in the SN of PD patients may contribute to the generation of oxidative stress, protein aggregation and neuronal death. However, the mechanisms involved in iron accumulation remain unclear. In previous studies we excluded a role of transferrin and its receptor in iron accumulation while we showed that lactoferrin receptors were overexpressed in blood vessels and dopaminergic neurons in Parkinson's disease. We recently also described an increase in the expression of the divalent metal transporter 1 (DMT1/Nramp2/Slc11a2) in the SN of PD patients. Using the PD animal model of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) intoxication in mice, we showed that DMT1 expression increased in the ventral mesencephalon of intoxicated animals, concomitant with iron accumulation, oxidative stress and dopaminergic cell loss. A mutation in DMT1 that impairs iron transport protected rodents against parkinsonism-inducing neurotoxins MPTP and 6-hydroxydopamine (6-OHDA). This study supports a critical role for DMT1 in iron-mediated neurodegeneration in PD.

Increased mRNA expression of cytochrome oxidase in dorsal raphe nucleus of depressive suicide victims.

Suicidal behavior is a problem with important social repercussions. Some groups of the population show a higher risk of suicide; for example, depression, alcoholism, psychosis or drug abuse frequently precedes suicidal behavior. However, the relationship between metabolic alterations in the brain and premorbid clinical symptoms of suicide remains uncertain. The serotonergic and noradrenergic systems have frequently been, implicated in suicidal behavior and the amount of serotonin in the brain and CSF of suicide victims has been found to be low compared with normal subjects. However, there are contradictory results regarding the role of noradrenergic neurons in the mediation of suicide attempts, possibly reflecting the heterogeneity of conditions that lead to a common outcome. In the present work we focus on the subgroup of suicide victims that share a common diagnosis of major depression. Based on post-mortem studies analyzing mRNA expression by in situ hybridization, serotonergic neurons from the dorsal raphe nucleus (DRN) from depressive suicide victims are seen to over-express cytochrome oxidase mRNA. However, no corresponding changes were found in the expression of tyrosine hydroxylase (TH) mRNA in the noradrenergic neurons of the Locus Coeruleus (LC). These results suggest that, despite of the low levels of serotonin described in suicide victims, the activity of DRN neurons could increase in the suicidally depressed, probably due to the over activation of serotonin re-uptake. No alteration was found in noradrenergic neurons, suggesting that they play no crucial role in the suicidal behavior of depressive patients.

Animal models in neurodegenerative diseases.

Ideally, animal models of neurodegenerative diseases should reproduce the clinical manifestation of the disease and a selective neuronal loss. In this review we will take as an example Parkinson's disease because its pathophysiology is well known and the neuronal loss well characterized. Indeed, Parkinson's disease is characterized by a loss of some but not all dopaminergic neurons, a loss of some non dopaminergic neurons and alpha-synuclein positive inclusions resembling Lewy bodies. There are at least two ways to develop animal models of PD based on the etiology of the disease and consist in 1) reproducing in animals the mutations seen in inherited forms of PD; 2) intoxicating animals with putative environmental toxins causing PD. In this review we discuss the advantages and the drawbacks in term of neuroproction of the currently used models.

Localization of D1a dopamine receptors on cell bodies and axonal endings in the substantia nigra pars reticulata of the rat.

In the present study, we analyzed the localization of D1a receptors within the rat substantia nigra pars reticulata (SNr) using specific D1a immunochemistry at the ultrastructural level and RT-PCR. At the electron microscopic level, D1a receptors were strongly associated with axons and axonal endings in the SNr, but also with numerous glutamic acid decarboxylase-positive dendrites and neuronal cell bodies. This neuronal expression of D1a receptors was confirmed using RT-PCR. G(alphaolf) protein-specific immunostaining displayed a similar distribution in dendrites and cell bodies to that of D1a receptors. The localization of D1a receptors in both GABAergic cell bodies and terminals is in accordance with the well known complex action of dopamine in the SNr. Moreover, the intracytoplasmic localization of D1a receptors in cell bodies and dendrites that we observed suggests that these receptors are only effective in specific conditions, or are transported to different nigral targets where they may have a presynaptic function.

Atypical parkinsonism in Guadeloupe: a common risk factor for two closely related phenotypes?

In Guadeloupe, there is an abnormally high frequency of atypical parkinsonism. Only one-third of the patients that develop parkinsonian symptoms were reported to present the classical features of idiopathic Parkinson disease and one-third a syndrome resembling progressive supranuclear palsy (PSP). The others were unclassifiable, according to established criteria. We carried out a cross-sectional study of 160 parkinsonian patients to: (i) define more precisely the clinical phenotypes of the PSP-like syndrome and the parkinsonism that was considered unclassifiable in comparison with previously known disorders; (ii) define the neuropsychological and brain imaging features of these patients; (iii) evaluate to what extent a candidate aetiological factor, the mitochondrial complex I inhibitor annonacin contained in the fruit and leaves of the tropical plant Annona muricata (soursop) plays a role in the neurological syndrome. Neuropsychological tests and MRI were used to classify the patients into those with Parkinson's disease (31%), Guadeloupean PSP-like syndrome (32%), Guadeloupean parkinsonism-dementia complex (PDC, 31%) and other parkinsonism-related disorders (6%). Patients with a PSP-like syndrome developed levodopa-resistant parkinsonism, associated with early postural instability and supranuclear oculomotor dysfunction. They differed, however, from classical PSP patients by the frequency of tremor (>50%), dysautonomia (50%) and the occurrence of hallucinations (59%). PDC patients had levodopa-resistant parkinsonism associated with frontosubcortical dementia, 52% of these patients had hallucinations, but, importantly, none had oculomotor dysfunction. The pattern of neuropsychological deficits was similar in both subgroups. Cerebral atrophy was seen in the majority of the PSP-like and PDC patients, with enlargement of the third ventricle and marked T2-hypointensity in the basal ganglia, particularly the substantia nigra. Consumption of soursop was significantly greater in both PSP-like and PDC patients than in controls and Parkinson's disease patients. In conclusion, atypical Guadeloupean parkinsonism comprises two forms of parkinsonism and dementia that differ clinically by the presence of oculomotor signs, but have similar cognitive profiles and neuroimaging features, suggesting that they may constitute a single disease entity, and both were similarly exposed to annonaceous neurotoxins, notably annonacin.

How to improve neuroprotection in Parkinson's disease?

Several factors involved in the etiology of Parkinson's disease (PD) have been proposed, including genetic and environmental factors or even a combination of both. Thus, multiple cellular hits are likely to contribute to neurodegeneration in PD. If such a mechanism happens to occur, our therapeutic intervention may perhaps require a cocktail of molecules acting on various pathways simultaneously. Furthermore, recent evidence suggests that PD may progress even when the initial cause of neurodegeneration has disappeared, suggesting that toxic substances released by the glial cells may be involved in the perpetuation of neuronal degeneration. This may thus represent a therapeutic target for PD.

Is atypical parkinsonism in the Caribbean caused by the consumption of Annonacae?

An abnormally frequent atypical levodopa-unresponsive, akinetic-rigid syndrome with some similarity to PSP was identified in the Caribbean island Guadeloupe, and was associated with the consumption of plants of the Annonacea family, especially Annona muricata (corossol, soursop) suggesting a possible toxic etiology. Annonaceae contain two groups of potential toxins, alkaloids and acetogenins. Both alkaloids and annonacin, the most abundant acetogenin, were toxic in vitro to dopaminergic and other neurons. However we have focused our work on annonacin for two reasons: (1) annonacin was toxic in nanomolar concentrations, whereas micromolar concentrations of the alkaloids were needed, (2) acetogenins are potent mitochondrial poisons, like other parkinsonism-inducing compounds. We have also shown that high concentrations of annonacin are present in the fruit or aqueous extracts of the leaves of A. muricata, can cross the blood brain barrier since it was detected in brain parenchyma of rats treated chronically with the molecule, and induced neurodegeneration of basal ganglia in these animals, similar to that observed in atypical parkinsonism. These studies reinforce the concept that consumption of Annonaceae may contribute to the pathogenesis of atypical parkinsonism in Guadeloupe.

How to judge animal models of Parkinson's disease in terms of neuroprotection.

Ideally, animal models of Parkinson's should reproduce the clinical manifestation of the disease, a loss of some but not all dopaminergic neurons, a loss of some non dopaminergic neurons and alpha-synuclein positive inclusions resembling Lewy bodies. There are at least three ways to develop animal models of PD. The first two are based on the etiology of the disease and consist in 1) reproducing in animals the mutations seen in inherited forms of PD; 2) intoxicating animals with putative environmental toxins causing PD. The last method currently used, which is not exclusive of the first two, is to try to reproduce the molecular or biochemical changes seen post-mortem in the brain of patients with PD. In this review we discuss the advantages and the drawbacks in term of neuroprotection of the currently used models.

The rotenone model of parkinsonism--the five years inspection.

Treatment of rats with rotenone has been proposed in the year 2000 to provide an animal model of idiopathic Parkinson's disease. We review here the experience that has been gained meanwhile with this model. The published data suggest that the model does not ideally reproduce the pathophysiology of Parkinson's disease, that Rotenone treatment does not cause a purely neurodegenerative concondition, that the Rotenone model does not ideally recapitulate the motor symptoms of Parkinson's disease, that degeneration of the dopaminergic neurons is highly variable, that striatal neurons appear to degenerate more consistently than neurons in the substantia nigra, and that cytoplasmic accumulation of the tau protein is more abundant than alpha-synuclein aggregation in severely lesioned animals. In summary, these data suggest that Rotenone-treated rats model atypical Parkinsonism rather than idiopathic Parkinson's disease.

Altered regulation of iron transport and storage in Parkinson's disease.

Parkinson's disease (PD) is characterized by the death of dopaminergic neurons in the substantia nigra. This neuronal degeneration is associated with a strong microglial activation and iron accumulation in the affected brain structures. The increased iron content may result from an increased iron penetration into the brain parenchyma due to a higher expression of lactoferrin and lactoferrin receptors at the level of the blood vessels and dopaminergic neurons in the substantia nigra in PD. Iron may also accumulate in microglial cells after phagocytosis of dopaminergic neurons. These effects may be reinforced by a lack of up-regulation of the iron storage protein ferritin, as suggested by an absence of change in iron regulatory protein 1 (IRP-1) control of ferritin mRNA translation in PD. Thus, a dysregulation of the labile iron pool may participate in the degenerative process affecting dopaminergic neurons in PD.

Changes in vascularization in substantia nigra pars compacta of monkeys rendered parkinsonian.

The degeneration of nigral dopaminergic neurons in Parkinson's disease is believed to be associated with a glial reaction and inflammatory changes. In turn, local factors may induce changes in vascularization and contribute to neuronal vulnerability. Among these factors, Vascular Endothelial Growth Factor (VEGF) is released in adults under pathological conditions and is thought to induce angiogenesis. In order to determine whether changes in brain vasculature are observed in the affected brain regions in parkinsonism, we quantitatively analysed the VEGF-expressing cells and blood vessels in the substantia nigra of monkeys rendered parkinsonian by MPTP injection and compared the results with those obtained in control monkeys. Using stereological methods, we observed an increase in the number of VEGF-expressing neurons and an increase of the number of blood vessels and their volume occupying the substantia nigra pars compacta of monkeys rendered parkinsonian by chronic MPTP intoxication. These changes in vascularization may therefore modify the neuronal availability of blood nutrients, blood cells or toxic substances and neuronal susceptibility to parkinsonism.

Ultrastructural localization of parkin in the rat brainstem, thalamus and basal ganglia.

The parkin gene encodes a 52 kd putative E3 ubiquitin-protein ligase involved in an autosomal recessive form of early onset parkinsonism. Parkin ultrastructural localization was studied by immunohistochemistry in the adult rat brain and in a parkin inducible PC12 cell line (HS22). In the rat brain, parkin immunoreactivity was detected in neuronal and glial cell bodies and in nerve processes. In the neurons, it was mostly localized on the periphery of large vesicles, some rare mitochondria and endoplasmic reticulum in the cell bodies, and on the periphery of large vesicles in the dendrites and terminals of the neurons. In addition, parkin immunoreactivity was also found around synaptic vesicles in the presynaptic elements of some axons. In HS22 cells over-expressing parkin, the distribution of the protein was similar to that observed in the perikarya of the labeled neurons.

The mitochondrial complex I inhibitor annonacin is toxic to mesencephalic dopaminergic neurons by impairment of energy metabolism.

The death of dopaminergic neurons induced by systemic administration of mitochondrial respiratory chain complex I inhibitors such as 1-methyl-4-phenylpyridinium (MPP(+); given as the prodrug 1-methyl-1,2,3,6-tetrahydropyridine) or the pesticide rotenone have raised the question as to whether this family of compounds are the cause of some forms of Parkinsonism. We have examined the neurotoxic potential of another complex I inhibitor, annonacin, the major acetogenin of Annona muricata (soursop), a tropical plant suspected to be the cause of an atypical form of Parkinson disease in the French West Indies (Guadeloupe). When added to mesencephalic cultures for 24 h, annonacin was much more potent than MPP(+) (effective concentration [EC(50)]=0.018 versus 1.9 microM) and as effective as rotenone (EC(50)=0.034 microM) in killing dopaminergic neurons. The uptake of [(3)H]-dopamine used as an index of dopaminergic cell function was similarly reduced. Toxic effects were seen at lower concentrations when the incubation time was extended by several days whereas withdrawal of the toxin after a short-term exposure (<6 h) arrested cell demise. Unlike MPP(+) but similar to rotenone, the acetogenin also reduced the survival of non-dopaminergic neurons. Neuronal cell death was not excitotoxic and occurred independently of free radical production. Raising the concentrations of either glucose or mannose in the presence of annonacin restored to a large extent intracellular ATP synthesis and prevented neuronal cell demise. Deoxyglucose reversed the effects of both glucose and mannose. Other hexoses such as galactose and fructose were not protective. Attempts to restore oxidative phosphorylation with lactate or pyruvate failed to provide protection to dopaminergic neurons whereas idoacetate, an inhibitor of glycolysis, inhibited the survival promoting effects of glucose and mannose indicating that these two hexoses acted independently of mitochondria by stimulating glycolysis. In conclusion, our study demonstrates that annonacin promotes dopaminergic neuronal death by impairment of energy production. It also underlines the need to address its possible role in the etiology of some atypical forms of Parkinsonism in Guadeloupe.

Changes in GAD67 mRNA expression evidenced by in situ hybridization in the brain of R6/2 transgenic mice.

Huntington's disease is an autosomal dominant disorder with degeneration of medium size striatal neurones. As the disease evolves, other neuronal populations are also progressively affected. A transgenic mouse model of the disease (R6/2) that expresses exon 1 of the human Huntington gene with approximately 150 CAG repeats has been developed, but GABA concentrations are reported to be normal in the striatum of these animals. In the present study, we analysed the status of GABAergic systems by means of glutamic acid decarboxylase (GAD)67 mRNA in situ hybridization in the brain of R6/2 transgenic mice and wild-type littermates. We show that GAD67 expression is normal in the striatum, cerebellum and septum but decreased in the frontal cortex, parietal cortex, globus pallidus, entopeduncular nucleus and substantia nigra pars reticulata of R6/2 mice. These data, which may, in part, account for the behavioural changes seen in these animals, indicate that at 12.5 weeks of age the pathological features seen in the mice differ from those seen in humans with Huntington's disease.

Animal models of Parkinson's disease in rodents induced by toxins: an update.

The development of animal models of Parkinson's disease is of great importance in order to test substitutive or neuroprotective strategies for Parkinson's disease. Such models should reproduce the main characteristics of the disease, such as a selective lesion of dopaminergic neurons that evolves over time and the presence of neuronal inclusions known as Lewy bodies. Optimally, such models should also reproduce the lesion of non-dopaminergic neurons observed in a great majority of patients with Parkinson's disease. From a behavioral point of view, a parkinsonian syndrome should be observed, ideally with akinesia, rigidity and rest tremor. These symptoms should be alleviated by dopamine replacement therapy, which may in turn lead to side effects such as dyskinesia. In this review, we analyze the main characteristics of experimental models of Parkinson's disease induced by neurotoxic compounds such as 6-hydroxydopamine, MPTP and rotenone. We show that, whereas MPTP and 6-hydroxydopamine induce a selective loss of catecholaminergic neurons that in most cases evolves over a short period of time, rotenone infusion by osmotic pumps can induce a chronically progressive degeneration of dopaminergic neurons and also of non-dopaminergic neurons in both the basal ganglia and the brainstem.

The role of glial reaction and inflammation in Parkinson's disease.

The glial reaction is generally considered to be a consequence of neuronal death in neurodegenerative diseases such as Alzheimer's disease, Huntington's disease, and Parkinson's disease. In Parkinson's disease, postmortem examination reveals a loss of dopaminergic neurons in the substantia nigra associated with a massive astrogliosis and the presence of activated microglial cells. Recent evidence suggests that the disease may progress even when the initial cause of neuronal degeneration has disappeared, suggesting that toxic substances released by the glial cells may be involved in the propagation and perpetuation of neuronal degeneration. Glial cells can release deleterious compounds such as proinflammatory cytokines (TNF-alpha, Il-1beta, IFN-gamma), which may act by stimulating nitric oxide production in glial cells, or which may exert a more direct deleterious effect on dopaminergic neurons by activating receptors that contain intracytoplasmic death domains involved in apoptosis. In line with this possibility, an activation of proteases such as caspase-3 and caspase-8, which are known effectors of apoptosis, has been reported in Parkinson's disease. Yet, caspase inhibitors or invalidation of TNF-alpha receptors does not protect dopaminergic neurons against degeneration in experimental models of the disease, suggesting that manipulation of a single signaling pathway may not be sufficient to protect dopaminergic neurons. In contrast, the antiinflammatory drugs pioglitazone, a PPAR-gamma agonist, and the tetracycline derivative minocycline have been shown to reduce glial activation and protect the substantia nigra in an animal model of the disease. Inhibition of the glial reaction and the inflammatory processes may thus represent a therapeutic target to reduce neuronal degeneration in Parkinson's disease.