Parkinson's disease is the second most common neurodegenerative disease and its pathogenesis is closely associated with oxidative stress. Deposition of aggregated α‐synuclein (α‐Syn) occurs in familial and sporadic forms of Parkinson's disease. Here, we studied the effect of oligomeric α‐Syn on one of the major markers of oxidative stress, lipid peroxidation, in primary co‐cultures of neurons and astrocytes. We found that oligomeric but not monomeric α‐Syn significantly increases the rate of production of reactive oxygen species, subsequently inducing lipid peroxidation in both neurons and astrocytes. Pre‐incubation of cells with isotope‐reinforced polyunsaturated fatty acids (D‐PUFAs) completely prevented the effect of oligomeric α‐Syn on lipid peroxidation. Inhibition of lipid peroxidation with D‐PUFAs further protected cells from cell death induced by oligomeric α‐Syn. Thus, lipid peroxidation induced by misfolding of α‐Syn may play an important role in the cellular mechanism of neuronal cell loss in Parkinson's disease.
The psychostimulant amphetamine (AMPH) is frequently used to increase catecholamine levels in attention disorders and positron emission tomography imaging studies. Despite the fact that most radiotracers for positron emission tomography studies are characterized in non‐human primates (NHPs), data on regional differences of the effect of AMPH in NHPs are very limited. This study examined the impact of AMPH on extracellular dopamine (DA) levels in the medial prefrontal cortex and the caudate of NHPs using microdialysis. In addition to differences in magnitude, we observed striking differences in the temporal profile of extracellular DA levels between these regions that can likely be attributed to differences in the regulation of dopamine uptake and biosynthesis. The present data suggest that cortical DA levels may remain elevated longer than in the caudate which may contribute to the clinical profile of the actions of AMPH.
Mephedrone (4‐methylmethcathinone) is a synthetic cathinone designer drug that alters pre‐synaptic dopamine (DA) activity like many psychostimulants. However, little is known about the post‐synaptic dopaminergic impacts of mephedrone. The neuropeptide neurotensin (NT) provides inhibitory feedback for basal ganglia and limbic DA pathways, and post‐synaptic D1‐like and D2‐like receptor activity affects NT tissue levels. This study evaluated how mephedrone alters basal ganglia and limbic system NT content and the role of NT receptor activation in drug consumption behavior. Four 25 mg/kg injections of mephedrone increased NT content in basal ganglia (striatum, substantia nigra and globus pallidus) and the limbic regions (nucleus accumbens core), while a lower dosage (5 mg/kg/injection) only increased striatal NT content. Mephedrone‐induced increases in basal ganglia NT levels were mediated by D1‐like receptors in the striatum and the substantia nigra by both D1‐like and D2‐like receptors in the globus pallidus. Mephedrone increased substance P content, another neuropeptide, in the globus pallidus, but not in the dorsal striatum or substantia nigra. Finally, the NT receptor agonist PD149163 blocked mephedrone self‐administration, suggesting reduced NT release, as indicated by increased tissue levels, likely contributing to patterns of mephedrone consumption.
Atypical antipsychotic drugs (AAPDs) have been suggested to be more effective in improving cognitive impairment in schizophrenia than typical APDs, a conclusion supported by differences in receptor affinities and neurotransmitter efflux in the cortex and the hippocampus. More potent serotonin (5‐HT)2A than dopamine (DA) D2 receptors antagonism, and direct or indirect 5‐HT1A agonism, characterize almost all AAPDs. Blonanserin, an AAPD, has slightly greater affinity for D2 than 5‐HT2A receptors. Using microdialysis and ultra performance liquid chromatography‐mass spectrometry/mass spectrometry, we compared the abilities of the typical APD, haloperidol, three AAPDs, blonanserin, lurasidone, and olanzapine, and a selective 5‐HT1A partial agonist, tandospirone, and all, except haloperidol, were found to ameliorate the cognitive deficits produced by the N‐methyl‐d‐aspartate antagonist, phencyclidine, altering the efflux of neurotransmitters and metabolites in the rat cortex and nucleus accumbens. Blonanserin, lurasidone, olanzapine, and tandospirone, but not haloperidol, increased the efflux of cortical DA and its metabolites, homovanillic acid and 3,4‐dihydroxyphenylacetic acid. Olanzapine and lurasidone increased the efflux of acetylcholine; lurasidone increased glutamate as well. None of the compounds significantly altered the efflux of 5‐HT or its metabolite, 5‐hydroxyindole acetic acid, or GABA, serine, and glycine. The ability to increase cortical DA efflux was the only shared effect of the compounds which ameliorates the deficit in cognition in rodents following phencyclidine.
(R)‐3‐[2,6‐cis‐Di(4‐methoxyphenethyl)piperidin‐1‐yl]propane‐1,2‐diol (GZ‐793A) inhibits methamphetamine‐evoked dopamine release from striatal slices and methamphetamine self‐administration in rats. GZ‐793A potently and selectively inhibits dopamine uptake at the vesicular monoamine transporter‐2 (VMAT2). This study determined GZ‐793A's ability to evoke [3H]dopamine release and inhibit methamphetamine‐evoked [3H]dopamine release from isolated striatal synaptic vesicles. Results show GZ‐793A concentration‐dependent [3H]dopamine release; nonlinear regression revealed a two‐site model of interaction with VMAT2 (High‐ and Low‐EC50 = 15.5 nM and 29.3 μM, respectively). Tetrabenazine and reserpine completely inhibited GZ‐793A‐evoked [3H]dopamine release, however, only at the High‐affinity site. Low concentrations of GZ‐793A that interact with the extravesicular dopamine uptake site and the High‐affinity intravesicular DA release site also inhibited methamphetamine‐evoked [3H]dopamine release from synaptic vesicles. A rightward shift in the methamphetamine concentration‐response was evident with increasing concentrations of GZ‐793A, and the Schild regression slope was 0.49 ± 0.08, consistent with surmountable allosteric inhibition. These results support a hypothetical model of GZ‐793A interaction at more than one site on the VMAT2 protein, which explains its potent inhibition of dopamine uptake, dopamine release via a High‐affinity tetrabenazine‐ and reserpine‐sensitive site, dopamine release via a Low‐affinity tetrabenazine‐ and reserpine‐insensitive site, and a low‐affinity interaction with the dihydrotetrabenazine binding site on VMAT2. GZ‐793A inhibition of the effects of methamphetamine supports its potential as a therapeutic agent for the treatment of methamphetamine abuse.
Dopamine (DA), a highly significant neurotransmitter in the mammalian central nervous system, operates on multiple time scales to affect a diverse array of physiological functions. The significance of DA in human health is heightened by its role in a variety of pathologies. Voltammetric measurements of electrically evoked DA release have brought to light the existence of a patchwork of DA kinetic domains in the dorsal striatum (DS) of the rat. Thus, it becomes necessary to consider how these domains might be related to specific aspects of DA's functions. Responses evoked in the fast and slow domains are distinct in both amplitude and temporal profile. Herein, we report that responses evoked in fast domains can be further classified into four distinct types, types 1–4. The DS, therefore, exhibits a total of at least five distinct evoked responses (four fast types and one slow type). All five response types conform to kinetic models based entirely on first‐order rate expressions, which indicates that the heterogeneity among the response types arises from kinetic diversity within the DS terminal field. We report also that functionally distinct subregions of the DS express DA kinetic diversity in a selective manner. Thus, this study documents five response types, provides a thorough kinetic explanation for each of them, and confirms their differential association with functionally distinct subregions of this key DA terminal field.
Methyl‐β‐cyclodextrin (MβCD) is a reagent that depletes cholesterol and disrupts lipid rafts, a type of cholesterol‐enriched cell membrane microdomain. Lipid rafts are essential for neuronal functions such as synaptic transmission and plasticity, which are sensitive to even low doses of MβCD. However, how MβCD changes synaptic function, such as N‐methyl‐d ‐aspartate receptor (NMDA‐R) activity, remains unclear. We monitored changes in synaptic transmission and plasticity after disrupting lipid rafts with MβCD. At low concentrations (0.5 mg/mL), MβCD decreased basal synaptic transmission and miniature excitatory post‐synaptic current without changing NMDA‐R‐mediated synaptic transmission and the paired‐pulse facilitation ratio. Interestingly, low doses of MβCD failed to deplete cholesterol or affect α‐amino‐3‐hydroxy‐5‐methyl‐4‐isoxazolepropionic acid receptor (AMPA‐R) and NMDA‐R levels, while clearly reducing GluA1 levels selectively in the synaptosomal fraction. Low doses of MβCD decreased the inhibitory effects of NASPM, an inhibitor for GluA2‐lacking AMPA‐R. MβCD successfully decreased NMDA‐R‐mediated long‐term potentiation but did not affect the formation of either NMDA‐R‐mediated or group I metabotropic glutamate receptor‐dependent long‐term depression. MβCD inhibited de‐depression without affecting de‐potentiation. These results suggest that MβCD regulates GluA1‐dependent synaptic potentiation but not synaptic depression in a cholesterol‐independent manner.
The nucleus accumbens is highly heterogeneous, integrating regionally distinct afferent projections and accumbal interneurons, resulting in diverse local microenvironments. Dopamine (DA) neuron terminals similarly express a heterogeneous collection of terminal receptors that modulate DA signaling. Cyclic voltammetry is often used to probe DA terminal dynamics in brain slice preparations; however, this method traditionally requires electrical stimulation to induce DA release. Electrical stimulation excites all of the neuronal processes in the stimulation field, potentially introducing simultaneous, multi‐synaptic modulation of DA terminal release. We used optogenetics to selectively stimulate DA terminals and used voltammetry to compare DA responses from electrical and optical stimulation of the same area of tissue around a recording electrode. We found that with multiple pulse stimulation trains, optically stimulated DA release increasingly exceeded that of electrical stimulation. Furthermore, electrical stimulation produced inhibition of DA release across longer duration stimulations. The GABAB antagonist, CGP 55845, increased electrically stimulated DA release significantly more than light stimulated release. The nicotinic acetylcholine receptor antagonist, dihydro‐β‐erythroidine hydrobromide, inhibited single pulse electrically stimulated DA release while having no effect on optically stimulated DA release. Our results demonstrate that electrical stimulation introduces local multi‐synaptic modulation of DA release that is absent with optogenetically targeted stimulation.
In this report, we describe the localization of diacylglycerol lipase‐α (DAGLα) in nuclei from adult cortical neurons, as assessed by double‐immunofluorescence staining of rat brain cortical sections and purified intact nuclei and by western blot analysis of subnuclear fractions. Double‐labeling assays using the anti‐DAGLα antibody and NeuN combined with Hoechst staining showed that only nuclei of neuronal origin were DAGLα positive. At high resolution, DAGLα‐signal displayed a punctate pattern in nuclear subdomains poor in Hoechst's chromatin and lamin B1 staining. In contrast, SC‐35‐ and NeuN‐signals (markers of the nuclear speckles) showed a high overlap with DAGLα within specific subdomains of the nuclear matrix. Among the members of the phospholipase C‐β (PLCβ) family, PLCβ1, PLCβ2, and PLCβ4 exhibited the same distribution with respect to chromatin, lamin B1, SC‐35, and NeuN as that described for DAGLα. Furthermore, by quantifying the basal levels of 2‐arachidonoylglycerol (2‐AG) by liquid chromatography and mass spectrometry (LC‐MS), and by characterizing the pharmacology of its accumulation, we describe the presence of a mechanism for 2‐AG production, and its PLCβ/DAGLα‐dependent biosynthesis in isolated nuclei. These results extend our knowledge about subcellular distribution of neuronal DAGLα, providing biochemical grounds to hypothesize a role for 2‐AG locally produced within the neuronal nucleus.
Aggregation of amyloid beta (Aβ) peptides and the subsequent neural plaque formation is a central aspect of Alzheimer's disease. Various strategies to reduce Aβ load in the brain are therefore intensely pursued. It has been hypothesized that reducing Aβ peptides in the periphery, that is in organs outside the brain, would be a way to diminish Aβ levels and plaque load in the brain. In this report, we put this peripheral sink hypothesis to test by investigating how selective inhibition of Aβ production in the periphery using a β‐secretase (BACE)1 inhibitor or reduced BACE1 gene dosage affects Aβ load in the brain. Selective inhibition of peripheral BACE1 activity in wild‐type mice or mice over‐expressing amyloid precursor protein (APPswe transgenic mice; Tg2576) reduced Aβ levels in the periphery but not in the brain, not even after chronic treatment over several months. In contrast, a BACE1 inhibitor with improved brain disposition reduced Aβ levels in both brain and periphery already after acute dosing. Mice heterozygous for BACE1, displayed a 62% reduction in plasma Aβ40, whereas brain Aβ40 was only lowered by 11%. These data suggest that reduction of Aβ in the periphery is not sufficient to reduce brain Aβ levels and that BACE1 is not the rate‐limiting enzyme for Aβ processing in the brain. This provides evidence against the peripheral sink hypothesis and suggests that a decrease in Aβ via BACE1 inhibition would need to be carried out in the brain.
Localized translation of axonal mRNAs contributes to developmental and regenerative axon growth. Although untranslated regions (UTRs) of many different axonal mRNAs appear to drive their localization, there has been no consensus RNA structure responsible for this localization. We recently showed that limited expression of ZBP1 protein restricts axonal localization of both β‐actin and GAP‐43 mRNAs. β‐actin 3′UTR has a defined element for interaction with ZBP1, but GAP‐43 mRNA shows no homology to this RNA sequence. Here, we show that an AU‐rich regulatory element (ARE) in GAP‐43′s 3′UTR is necessary and sufficient for its axonal localization. Axonal GAP‐43 mRNA levels increase after in vivo injury, and GAP‐43 mRNA shows an increased half‐life in regenerating axons. GAP‐43 mRNA interacts with both HuD and ZBP1, and HuD and ZBP1 co‐immunoprecipitate in an RNA‐dependent fashion. Reporter mRNA with the GAP‐43 ARE competes with endogenous β‐actin mRNA for axonal localization and decreases axon length and branching similar to the β‐actin 3′UTR competing with endogenous GAP‐43 mRNA. Conversely, over‐expressing GAP‐43 coding sequence with its 3′UTR ARE increases axonal elongation and this effect is lost when just the ARE is deleted from GAP‐43′s 3′UTR.
Glucose is the main energy substrate for neurons, and ketone bodies are known to be alternative substrates. However, the capacity of ketone bodies to support different neuronal functions is still unknown. Thus, a change in energy substrate from glucose alone to a combination of glucose and β‐hydroxybutyrate might change neuronal function as there is a known coupling between metabolism and neurotransmission. The purpose of this study was to shed light on the effects of the ketone body β‐hydroxybutyrate on glycolysis and neurotransmission in cultured murine glutamatergic neurons. Previous studies have shown an effect of β‐hydroxybutyrate on glucose metabolism, and the present study further specified this by showing attenuation of glycolysis when β‐hydroxybutyrate was present in these neurons. In addition, the NMDA receptor‐induced calcium responses in the neurons were diminished in the presence of β‐hydroxybutyrate, whereas a direct effect of the ketone body on transmitter release was absent. However, the presence of β‐hydroxybutyrate augmented transmitter release induced by the KATP channel blocker glibenclamide, thus giving an indirect indication of the involvement of KATP channels in the effects of ketone bodies on transmitter release.
The 19‐transmembrane, multisubunit γ‐secretase complex generates the amyloid β‐peptide (Aβ) of Alzheimer's disease (AD) by an unusual intramembrane proteolysis of the β‐amyloid precursor protein. The complex, which similarly processes many other type 1 transmembrane substrates, is composed of presenilin, Aph1, nicastrin, and presenilin enhancer (Pen‐2), all of which are necessary for proper complex maturation and enzymatic activity. Obtaining a high‐resolution atomic structure of the intact complex would greatly aid the rational design of compounds to modulate activity but is a very difficult task. A complementary method is to generate structures for each individual subunit to allow one to build a model of the entire complex. Here, we describe a method by which recombinant human Pen‐2 can be purified from bacteria to > 95% purity at milligram quantities per liter, utilizing a maltose binding protein tag to both increase solubility and facilitate purification. Expressing the same construct in mammalian cells, we show that the large N‐terminal maltose binding protein tag on Pen‐2 still permits incorporation into the complex and subsequent presenilin‐1 endoproteolysis, nicastrin glycosylation and proteolytic activity. These new methods provide valuable tools to study the structure and function of Pen‐2 and the γ‐secretase complex.
The β‐amyloid precursor protein (APP) has been extensively studied for its role as the precursor of the β‐amyloid protein (Aβ) of Alzheimer's disease. However, the normal function of APP remains largely unknown. This article reviews studies on the structure, expression and post‐translational processing of APP, as well as studies on the effects of APP in vitro and in vivo. We conclude that the published data provide strong evidence that APP has a trophic function. APP is likely to be involved in neural stem cell development, neuronal survival, neurite outgrowth and neurorepair. However, the mechanisms by which APP exerts its actions remain to be elucidated. The available evidence suggests that APP interacts both intracellularly and extracellularly to regulate various signal transduction mechanisms.
Mephedrone (4‐methylmethcathinone) is a β‐ketoamphetamine stimulant drug of abuse with close structural and mechanistic similarities to methamphetamine. One of the most powerful actions associated with mephedrone is the ability to stimulate dopamine (DA) release and block its re‐uptake through its interaction with the dopamine transporter (DAT). Although mephedrone does not cause toxicity to DA nerve endings, its ability to serve as a DAT blocker could provide protection against methamphetamine‐induced neurotoxicity like other DAT inhibitors. To test this possibility, mice were treated with mephedrone (10, 20, or 40 mg/kg) prior to each injection of a neurotoxic regimen of methamphetamine (four injections of 2.5 or 5.0 mg/kg at 2 h intervals). The integrity of DA nerve endings of the striatum was assessed through measures of DA, DAT, and tyrosine hydroxylase levels. The moderate to severe DA toxicity associated with the different doses of methamphetamine was not prevented by any dose of mephedrone but was, in fact, significantly enhanced. The hyperthermia caused by combined treatment with mephedrone and methamphetamine was the same as seen after either drug alone. Mephedrone also enhanced the neurotoxic effects of amphetamine and 3,4‐methylenedioxymethamphetamine on DA nerve endings. In contrast, nomifensine protected against methamphetamine‐induced neurotoxicity. As mephedrone increases methamphetamine neurotoxicity, the present results suggest that it interacts with the DAT in a manner unlike that of other typical DAT inhibitors. The relatively innocuous effects of mephedrone alone on DA nerve endings mask a potentially dangerous interaction with drugs that are often co‐abused with it, leading to heightened neurotoxicity. 相似文献
DJ‐1 is an oxidative stress sensor that localizes to the mitochondria when the cell is exposed to oxidative stress. DJ‐1 mutations that result in gene deficiency are linked to increased risk of Parkinson's disease (PD). Activation of microglial stress conditions that are linked to PD may result in neuronal death. We postulated that DJ‐1 deficiency may increase microglial neurotoxicity. We found that down‐regulation of DJ‐1 in microglia using an shRNA approach increased cell sensitivity to dopamine as measured by secreted pro‐inflammatory cytokines such as IL‐1β and IL‐6. Furthermore, we discovered that DJ‐1‐deficient microglia had increased monoamine oxidase activity that resulted in elevation of intracellular reactive oxygen species and nitric oxide leading to increased dopaminergic neurotoxicity. Rasagaline, a monoamine oxidase inhibitor approved for treatment of PD, reduced the microglial pro‐inflammatory phenotype and significantly reduced neurotoxicity. Moreover, we discovered that DJ‐1‐deficient microglia have reduced expression of triggering receptor expressed on myeloid cells 2 (TREM2), previously suggested as a risk factor for pro‐inflammation in neurodegenerative diseases. Further studies of DJ‐1‐mediated cellular pathways in microglia may contribute useful insights into the development of PD providing future avenues for therapeutic intervention.
Compensatory mechanisms in dopamine (DA) signaling have long been proposed to delay onset of locomotor symptoms during Parkinson's disease progression until ~ 80% loss of striatal DA occurs. Increased striatal dopamine turnover has been proposed to be a part of this compensatory response, but may occur after locomotor symptoms. Increased tyrosine hydroxylase (TH) activity has also been proposed as a mechanism, but the impact of TH protein loss upon site‐specific TH phosphorylation in conjunction with the impact on DA tissue content is not known. The tissue content of DA was determined against TH protein loss in the striatum and substantia nigra (SN) following 6‐hydroxydopamine lesion in the medial forebrain bundle in young Sprague–Dawley male rats. Although DA predictably decreased in both regions following 6‐hydroxydopamine, there was a significant difference in DA loss between the striatum (75%) and SN (40%), despite similar TH protein loss. Paradoxically, there was a significant decrease in DA against remaining TH protein in striatum, but a significant increase in DA against remaining TH in SN. In the SN, increased DA per remaining TH protein was matched by increased ser31, but not ser40, TH phosphorylation. In striatum, both ser31 and ser40 phosphorylation decreased, reflecting decreased DA per TH. However, in control nigral and striatal tissue, only ser31 phosphorylation correlated with DA per TH protein. Combined, these results suggest that the phosphorylation of ser31 in the SN may be a mechanism to increase DA biosynthesis against TH protein loss in an in vivo model of Parkinson's disease.
GABAA receptors are pentameric ligand‐gated ion channels that mediate inhibitory fast synaptic transmission in the central nervous system. Consistent with recent pentameric ligand‐gated ion channels structures, sequence analysis predicts an α‐helix near the N‐terminus of each GABAA receptor subunit. Preceding each α‐helix are 8–36 additional residues, which we term the N‐terminal extension. In homomeric GABAC receptors and nicotinic acetylcholine receptors, the N‐terminal α‐helix is functionally essential. Here, we determined the role of the N‐terminal extension and putative α‐helix in heteromeric α1β2γ2 GABAA receptors. This role was most prominent in the α1 subunit, with deletion of the N‐terminal extension or further deletion of the putative α‐helix both dramatically reduced the number of functional receptors at the cell surface. Conversely, deletion of the β2 or γ2 N‐terminal extension had little effect on the number of functional cell surface receptors. Additional deletion of the putative α‐helix in the β2 or γ2 subunits did, however, decrease both functional cell surface receptors and incorporation of the γ2 subunit into mature receptors. In the β2 subunit only, α‐helix deletions affected GABA sensitivity and desensitization. Our findings demonstrate that N‐terminal extensions and α‐helices make key subunit‐specific contributions to assembly, consistent with both regions being involved in inter‐subunit interactions.
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