The neuronal endocannabinoid system is known to depress synaptic inputs retrogradely in an activity‐dependent manner. This mechanism has been generally described for excitatory glutamatergic and inhibitory GABAergic synapses. Here, we report that neurones in the auditory brainstem of the Mongolian gerbil (Meriones unguiculatus) retrogradely regulate the strength of their inputs via the endocannabinoid system. By means of whole‐cell patch‐clamp recordings, we found that retrograde endocannabinoid signalling attenuates both glycinergic and glutamatergic post‐synaptic currents in the same types of neurones. Accordingly, we detected the cannabinoid receptor 1 in excitatory and inhibitory pre‐synapses as well as the endocannabinoid‐synthesising enzymes (diacylglycerol lipase α/β, DAGLα/β) post‐synaptically through immunohistochemical stainings. Our study was performed with animals aged 10–15 days, that is, in the time window around the onset of hearing. Therefore, we suggest that retrograde endocannabinoid signalling has a role in adapting inputs during the functionally important switch from spontaneously generated to sound‐related signals.
In this study, in vitro and in vivo experiments were carried out with the high‐affinity multifunctional D2/D3 agonist D‐512 to explore its potential neuroprotective effects in models of Parkinson's disease and the potential mechanism(s) underlying such properties. Pre‐treatment with D‐512 in vitro was found to rescue rat adrenal Pheochromocytoma PC12 cells from toxicity induced by 6‐hydroxydopamine administration in a dose‐dependent manner. Neuroprotection was found to coincide with reductions in intracellular reactive oxygen species, lipid peroxidation, and DNA damage. In vivo, pre‐treatment with 0.5 mg/kg D‐512 was protective against neurodegenerative phenotypes associated with systemic administration of MPTP, including losses in striatal dopamine, reductions in numbers of DAergic neurons in the substantia nigra (SN), and locomotor dysfunction. These observations strongly suggest that the multifunctional drug D‐512 may constitute a novel viable therapy for Parkinson's disease.
Epidermal fatty acid‐binding protein (E‐FABP/FABP5/DA11) binds and transport long‐chain fatty acids in the cytoplasm and may play a protecting role during neuronal injury. We examined whether E‐FABP protects nerve growth factor‐differentiated PC12 cells (NGFDPC12 cells) from lipotoxic injury observed after palmitic acid (C16:0; PAM) overload. NGFDPC12 cells cultures treated with PAM/bovine serum albumin at 0.3 mM/0.15 mM show PAM‐induced lipotoxicity (PAM‐LTx) and apoptosis. The apoptosis was preceded by a cellular accumulation of reactive oxygen species (ROS) and higher levels of E‐FABP. Antioxidants MCI‐186 and N‐acetyl cysteine prevented E‐FABP's induction in expression by PAM‐LTx, while tert‐butyl hydroperoxide increased ROS and E‐FABP expression. Non‐metabolized methyl ester of PAM, methyl palmitic acid (mPAM), failed to increase cellular ROS, E‐FABP gene expression, or trigger apoptosis. Treatment of NGFDPC12 cultures with siE‐FABP showed reduced E‐FABP levels correlating with higher accumulation of ROS and cell death after exposure to PAM. In contrast, increasing E‐FABP cellular levels by pre‐loading the cells with recombinant E‐FABP diminished the PAM‐induced ROS and cell death. Finally, agonists for PPARβ (GW0742) or PPARγ (GW1929) increased E‐FABP expression and enhanced the resistance of NGFDPC12 cells to PAM‐LTx. We conclude that E‐FABP protects NGFDPC12 cells from lipotoxic injury through mechanisms that involve reduction of ROS.
The molecular mechanisms of iron trafficking in neurons have not been elucidated. In this study, we characterized the expression and localization of ferrous iron transporters Zip8, Zip14 and divalent metal transporter 1 (DMT1), and ferrireductases Steap2 and stromal cell‐derived receptor 2 in primary rat hippocampal neurons. Steap2 and Zip8 partially co‐localize, indicating these two proteins may function in Fe3+ reduction prior to Fe2+ permeation. Zip8, DMT1, and Steap2 co‐localize with the transferrin receptor/transferrin complex, suggesting they may be involved in transferrin receptor/transferrin‐mediated iron assimilation. In brain interstitial fluid, transferring‐bound iron (TBI) and non‐transferrin‐bound iron (NTBI) exist as potential iron sources. Primary hippocampal neurons exhibit significant iron uptake from TBI (Transferrin‐59Fe3+) and NTBI, whether presented as 59Fe2+‐citrate or 59Fe3+‐citrate; reductase‐independent 59Fe2+ uptake was the most efficient uptake pathway of the three. Kinetic analysis of Zn2+ inhibition of Fe2+ uptake indicated that DMT1 plays only a minor role in the uptake of NTBI. In contrast, localization and knockdown data indicate that Zip8 makes a major contribution. Data suggest also that cell accumulation of 59Fe from TBI relies at least in part on an endocytosis‐independent pathway. These data suggest that Zip8 and Steap2 play a major role in iron accumulation from NTBI and TBI by hippocampal neurons.
Brain damage after insult and cognitive decline are related to excitotoxicity and strongly influenced by aging, yet mechanisms of aging‐dependent susceptibility to excitotoxicity are poorly known. Several non‐steroidal anti‐inflammatory drugs (NSAIDs) may prevent excitotoxicity and cognitive decline in the elderly by an unknown mechanism. Interestingly, after several weeks in vitro, hippocampal neurons display important hallmarks of neuronal aging in vivo. Accordingly, rat hippocampal neurons cultured for several weeks were used to investigate mechanisms of aging‐related susceptibility to excitotoxicity and neuroprotection by NSAIDs. We found that NMDA increased cytosolic Ca2+ concentration in young, mature and aged neurons but only promoted apoptosis in aged neurons. Resting Ca2+ levels and responses to NMDA increased with time in culture which correlated with changes in expression of NMDA receptor subunits. In addition, NMDA promoted mitochondrial Ca2+ uptake only in aged cultures. Consistently, specific inhibition of mitochondrial Ca2+ uptake decreased apoptosis. Finally, we found that a series of NSAIDs depolarized mitochondria and inhibited mitochondrial Ca2+ overload, thus preventing NMDA‐induced apoptosis in aged cultures. We conclude that mitochondrial Ca2+ uptake is critical for age‐related susceptibility to excitotoxicity and neuroprotection by NSAIDs.
Thrombolysis with tissue plasminogen activator (tPA) increases matrix metalloproteinase‐9 (MMP‐9) activity in the ischemic brain, which exacerbates blood‐brain barrier injury and increases the risk of symptomatic cerebral hemorrhage. The mechanism through which tPA enhances MMP‐9 activity is not well understood. Here we report an important role of caveolin‐1 in mediating tPA‐induced MMP‐9 synthesis. Brain microvascular endothelial cell line bEnd3 cells were incubated with 5 or 20 μg/ml tPA for 24 hrs before analyzing MMP‐9 levels in the conditioned media and cellular extracts by gelatin zymography. tPA at a dose of 20 μg/mL tPA, but not 5 μg/mL, significantly increased MMP‐9 level in cultured media while decreasing it in cellular extracts. Concurrently, tPA treatment induced a 2.3‐fold increase of caveolin‐1 protein levels in endothelial cells. Interestingly, knockdown of Cav‐1 with siRNA inhibited tPA‐induced MMP‐9 mRNA up‐regulation and MMP‐9 increase in the conditioned media, but did not affect MMP‐9 decrease in cellular extracts. These results suggest that caveolin‐1 critically contributes to tPA‐mediated MMP‐9 up‐regulation, but may not facilitate MMP‐9 secretion in endothelial cells.
It has been postulated that the accumulation of extracellular α‐synuclein (α‐syn) might alter the neuronal membrane by formation of ‘pore‐like structures’ that will lead to alterations in ionic homeostasis. However, this has never been demonstrated to occur in brain neuronal plasma membranes. In this study, we show that α‐syn oligomers rapidly associate with hippocampal membranes in a punctate fashion, resulting in increased membrane conductance (5 fold over control) and the influx of both calcium and a fluorescent glucose analogue. The enhancement in intracellular calcium (1.7 fold over control) caused a large increase in the frequency of synaptic transmission (2.5 fold over control), calcium transients (3 fold over control), and synaptic vesicle release. Both primary hippocampal and dissociated nigral neurons showed rapid increases in membrane conductance by α‐syn oligomers. In addition, we show here that α‐syn caused synaptotoxic failure associated with a decrease in SV2, a membrane protein of synaptic vesicles associated with neurotransmitter release. In conclusion, extracellular α‐syn oligomers facilitate the perforation of the neuronal plasma membrane, thus explaining, in part, the synaptotoxicity observed in neurodegenerative diseases characterized by its extracellular accumulation.
Hyperglycemia is known to induce microvascular complications, thereby altering blood–brain barrier (BBB) permeability. This study investigated the role of matrix metalloproteinases (MMPs) and their endogenous inhibitors in increased BBB permeability and evaluated the protective effect of S‐nitrosoglutathione (GSNO) in diabetes. Diabetes was induced in mice by intraperitoneal injection of streptozotocin (40 mg/kg body weight) for 5 days and GSNO was administered orally (100 μg/kg body weight) daily for 8 weeks after the induction of diabetes. A significant decline in cognitive functions was observed in diabetic mice assessed by Morris water maze test. Increased permeability to different molecular size tracers accompanied by edema and ion imbalance was observed in cortex and hippocampus of diabetic mice. Furthermore, activity of both pro and active MMP‐9 was found to be significantly elevated in diabetic animals. Increased in situ gelatinase activity was observed in tissue sections and isolated microvessels from diabetic mice brain. The increase in activity of MMP‐9 was attributed to increased mRNA and protein expression in diabetic mice. In addition, a significant decrease in mRNA and protein expression of tissue inhibitor of matrix metalloproteinase‐1 was also observed in diabetic animals. However, GSNO supplementation to diabetic animals was able to abridge MMP‐9 activation as well as tissue inhibitor of matrix metalloproteinase‐1 levels, restoring BBB integrity and also improving learning and memory. Our findings clearly suggest that GSNO could prevent hyperglycemia‐induced disruption of BBB by suppressing MMP‐9 activity.
Striatal‐enriched tyrosine phosphatase (STEP) is an important regulator of neuronal synaptic plasticity, and its abnormal level or activity contributes to cognitive disorders. One crucial downstream effector and direct substrate of STEP is extracellular signal‐regulated protein kinase (ERK), which has important functions in spine stabilisation and action potential transmission. The inhibition of STEP activity toward phospho‐ERK has the potential to treat neuronal diseases, but the detailed mechanism underlying the dephosphorylation of phospho‐ERK by STEP is not known. Therefore, we examined STEP activity toward para‐nitrophenyl phosphate, phospho‐tyrosine‐containing peptides, and the full‐length phospho‐ERK protein using STEP mutants with different structural features. STEP was found to be a highly efficient ERK tyrosine phosphatase that required both its N‐terminal regulatory region and key residues in its active site. Specifically, both kinase interaction motif (KIM) and kinase‐specific sequence of STEP were required for ERK interaction. In addition to the N‐terminal kinase‐specific sequence region, S245, hydrophobic residues L249/L251, and basic residues R242/R243 located in the KIM region were important in controlling STEP activity toward phospho‐ERK. Further kinetic experiments revealed subtle structural differences between STEP and HePTP that affected the interactions of their KIMs with ERK. Moreover, STEP recognised specific positions of a phospho‐ERK peptide sequence through its active site, and the contact of STEP F311 with phospho‐ERK V205 and T207 were crucial interactions. Taken together, our results not only provide the information for interactions between ERK and STEP, but will also help in the development of specific strategies to target STEP‐ERK recognition, which could serve as a potential therapy for neurological disorders.
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.
Amyloid beta (Aβ) protein is the primary proteinaceous deposit found in the brains of patients with Alzheimer's disease (AD). Evidence suggests that Aβ plays a central role in the development of AD pathology. Here, we show in PC12 cells, Aβ impairs tropomyosin receptor kinase A (TrkA) ubiquitination, phosphorylation, and its association with p75NTR, p62, and TRAF6 induced by nerve growth factor. The ubiquitination and tyrosine phosphorylation of TrkA was also found to be impaired in postmortem human AD hippocampus compared to control. Interestingly, the nitrotyrosylation of TrkA was increased in AD hippocampus and this explains why the phosphotyrosylation and ubiquitination of TrkA was impaired. In AD brain, the production of matrix metalloproteinase‐7 (MMP‐7), which cleaves proNGF, was reduced, thereby leading to the accumulation of pro‐NGF and a decrease in the level of active NGF. TrkA signaling events, including Ras/MAPK and phosphatidylinositol 3‐kinase (PI3K)/Akt pathways, are deactivated with Aβ and in the human AD hippocampus. Findings show that Aβ blocks the TrkA ubiquitination and downstream signaling similar to AD hippocampus.
Both dopamine and glutamate are critically involved in cognitive processes such as working memory. Astrocytes, which express dopamine receptors, are essential elements in the termination of glutamatergic signaling: the astrocytic glutamate transporter GLT‐1 is responsible for > 90% of cortical glutamate uptake. The effect of dopamine depletion on glutamate transporters in the prefrontal cortex (PFC) remains unknown. In an effort to determine if astrocytes are a locus of cortical dopamine–glutamate interactions, we examined the effects of chronic dopamine denervation on PFC protein and mRNA levels of glutamate transporters. PFC dopamine denervation elicited a marked increase in GLT‐1 protein levels, but had no effect on levels of other glutamate transporters; high‐affinity glutamate transport was positively correlated with the extent of dopamine depletion. GLT‐1 gene expression was not altered. Our data suggest that dopamine depletion may lead to post‐translational modifications that result in increased expression and activity of GLT‐1 in PFC astrocytes.
Nitric oxide (NO) plays an important role in phase‐shifting of circadian neuronal activities in the suprachiasmatic nucleus and circadian behavior activity rhythms. In the retina, NO production is increased in a light‐dependent manner. While endogenous circadian oscillators in retinal photoreceptors regulate their physiological states, it is not clear whether NO also participates in the circadian regulation of photoreceptors. In this study, we demonstrate that NO is involved in the circadian phase‐dependent regulation of L‐type voltage‐gated calcium channels (L‐VGCCs). In chick cone photoreceptors, the L‐VGCCα1 subunit expression and the maximal L‐VGCC currents are higher at night, and both Ras‐mitogen‐activated protein kinase (MAPK)‐extracellular signal‐regulated kinase (Erk) and Ras‐phosphatidylinositol 3 kinase (PI3K)‐protein kinase B (Akt) are part of the circadian output pathways regulating L‐VGCCs. The NO‐cGMP‐protein kinase G (PKG) pathway decreases L‐VGCCα1 subunit expression and L‐VGCC currents at night, but not during the day, and exogenous NO donor or cGMP decreases the phosphorylation of Erk and Akt at night. The protein expression of neural NO synthase (nNOS) is also under circadian control, with both nNOS and NO production being higher during the day. Taken together, NO/cGMP/PKG signaling is involved as part of the circadian output pathway to regulate L‐VGCCs in cone photoreceptors.
This study has shown that purified recombinant human α‐synuclein (20 μM) causes membrane depolarization and loss of phosphorylation capacity of isolated purified rat brain mitochondria by activating permeability transition pore complex. In intact SHSY5Y (human neuroblastoma cell line) cells, lactacystin (5 μM), a proteasomal inhibitor, causes an accumulation of α‐synuclein with concomitant mitochondrial dysfunction and cell death. The effects of lactacystin on intact SHSY5Y cells are, however, prevented by knocking down α‐synuclein expression by specific siRNA. Furthermore, in wild‐type (non‐transfected) SHSY5Y cells, the effects of lactacystin on mitochondrial function and cell viability are also prevented by cyclosporin A (1 μM) which blocks the activity of the mitochondrial permeability transition pore. Likewise, in wild‐type SHSY5Y cells, typical mitochondrial poison like antimycin A (50 nM) produces loss of cell viability comparable to that of lactacystin (5 μM). These data, in combination with those from isolated brain mitochondria, strongly suggest that intracellularly accumulated α‐synuclein can interact with mitochondria in intact SHSY5Y cells causing dysfunction of the organelle which drives the cell death under our experimental conditions. The results have clear implications in the pathogenesis of sporadic Parkinson's disease.
Synaptic impairment rather than neuronal loss may be the leading cause of cognitive dysfunction in brain aging. Certain small Rho‐GTPases are involved in synaptic plasticity, and their dysfunction is associated with brain aging and neurodegeneration. Rho‐GTPases undergo prenylation by attachment of geranylgeranylpyrophosphate (GGPP) catalyzed by GGTase‐I. We examined age‐related changes in the abundance of Rho and Rab proteins in membrane and cytosolic fractions as well as of GGTase‐I in brain tissue of 3‐ and 23‐month‐old C57BL/6 mice. We report a shift in the cellular localization of Rho‐GTPases toward reduced levels of membrane‐associated and enhanced cytosolic levels of those proteins in aged mouse brain as compared with younger mice. The age‐related reduction in membrane‐associated Rho proteins was associated with a reduction in GGTase‐Iβ levels that regulates binding of GGPP to Rho‐GTPases. Proteins prenylated by GGTase‐II were not reduced in aged brain indicating a specific targeting of GGTase‐I in the aged brain. Inhibition of GGTase‐I in vitro modeled the effects of aging we observed in vivo. We demonstrate for the first time a decrease in membrane‐associated Rho proteins in aged brain in association with down‐regulation of GGTase‐Iβ. This down‐regulation could be one of the mechanisms causing age‐related weakening of synaptic plasticity.
Expressions of vascular endothelial growth factor (VEGF) receptors in astrocytes are increased in damaged brains. To clarify the regulatory mechanisms of VEGF receptors, the effects of endothelin‐1 (ET‐1) were examined in rat cultured astrocytes. Expressions of VEGF‐R1 and ‐R2 receptor mRNA were at similar levels, whereas the mRNA expressions of VEGF‐R3 and Tie‐2, a receptor for angiopoietins, were lower. Placenta growth factor, a selective agonist of the VEGF‐R1 receptor, induced phosphorylation of focal adhesion kinase (FAK) and extracellular signal regulated kinase 1/2 (ERK1/2). Phosphorylations of FAK and ERK 1/2 were also stimulated by VEGF‐E, a selective VEGF‐R2 agonist. Increased phosphorylations of FAK and ERK1/2 by VEGF165 were reduced by selective antagonists for VEGF‐R1 and ‐R2. Treatment with ET‐1 increased VEGF‐R1 mRNA and protein levels. The effects of ET‐1 on VEGF‐R1 mRNA were mimicked by Ala1,3,11,15‐ET‐1, a selective agonist for ETB receptors, and inhibited by BQ788, an ETB antagonist. ET‐1 did not affect the mRNA levels of VEGF‐R2, ‐R3, and Tie‐2. Pre‐treatment with ET‐1 potentiated the effects of placenta growth factor on phosphorylations of FAK and ERK1/2. These findings suggest that ET‐1 induces up‐regulation of VEGF‐R1 receptors in astrocytes, and potentiates VEGF signals in damaged nerve tissues.
The receptor for advanced glycation end products (RAGE) gene expresses two major alternative splicing isoforms, full‐length membrane‐bound RAGE (mRAGE) and secretory RAGE (esRAGE). Both isoforms play important roles in Alzheimer's disease (AD) pathogenesis, either via interaction of mRAGE with β‐amyloid peptide (Aβ) or inhibition of the mRAGE‐activated signaling pathway. In the present study, we showed that heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1) and Transformer2β‐1 (Tra2β‐1) were involved in the alternative splicing of mRAGE and esRAGE. Functionally, two factors had an antagonistic effect on the regulation. Glucose deprivation induced an increased ratio of mRAGE/esRAGE via up‐regulation of hnRNP A1 and down‐regulation of Tra2β‐1. Moreover, the ratios of mRAGE/esRAGE and hnRNP A1/Tra2β‐1 were increased in peripheral blood mononuclear cells from AD patients. The results provide a molecular basis for altered splicing of mRAGE and esRAGE in AD pathogenesis.
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