Peripheral myelin protein 22 (PMP 22) is a component of compact myelin in the peripheral nervous system. The amount of PMP 22 in myelin is tightly regulated, and PMP 22 over or under‐expression cause Charcot‐Marie‐Tooth 1A (CMT 1A) and Hereditary Neuropathy with Pressure Palsies (HNPP ). Despite the importance of PMP 22 , its function remains largely unknown. It was reported that PMP 22 interacts with the β4 subunit of the laminin receptor α6β4 integrin, suggesting that α6β4 integrin and laminins may contribute to the pathogenesis of CMT 1A or HNPP . Here we asked if the lack of α6β4 integrin in Schwann cells influences myelin stability in the HNPP mouse model. Our data indicate that PMP 22 and β4 integrin may not interact directly in myelinating Schwann cells, however, ablating β4 integrin delays the formation of tomacula, a characteristic feature of HNPP . In contrast, ablation of integrin β4 worsens nerve conduction velocities and non‐compact myelin organization in HNPP animals. This study demonstrates that indirect interactions between an extracellular matrix receptor and a myelin protein influence the stability and function of myelinated fibers.
Mature brain‐derived neurotrophic factor (mBDNF) plays a vital role in the nervous system, whereas proBDNF elicits neurodegeneration and neuronal apoptosis. Although current enzyme‐linked immunosorbent assay (ELISA) has been widely used to measure BDNF levels, it cannot differentiate mBDNF from proBDNF. As the function of proBDNF differs from mBDNF, it is necessary to establish an ELISA assay specific for the detection of mBDNF. Therefore, we aimed to establish a new mBDNF‐specific sandwich ELISA. In this study, we have screened and found a combination of antibodies for a sandwich ELISA. A monoclonal antibody and sheep anti‐BDNF were chosen as capture and detection antibody for sandwich ELISA respectively. The new ELISA showed no cross‐reactivity to human recombinant NT‐3, NT‐4, nerve growth factor and negligible cross‐reactivity (0.99–4.99%) for proBDNF compared to commercial ELISA kits (33.18–91.09%). The application of the new mBDNF ELISA was shown through the measurement of mBDNF levels in different brain regions of rats and in the brain of β‐site amyloid precursor protein cleaving enzyme 1 (BACE1)?/? and WT mice and compared to western blot. Overall, this new ELISA will be useful for the measurement of mBDNF levels with high specificity.
Recent studies have highlighted the role of mitochondria in dendritic protrusion growth and plasticity. However, the detailed mechanisms that mitochondria regulate dendritic filopodia morphogenesis remain elusive. Cyclophilin D (CypD, gene name: Ppif ) controls the opening of mitochondrial permeability transition pore. Although the pathological relevance of CypD has been intensively investigated, little is known about its physiological function in neurons. Here, we have found that genetic depletion of or pharmaceutical inhibition of CypD blunts the outgrowth of dendritic filopodia in response to KC l‐stimulated neuronal depolarization. Further cell biological studies suggest that such inhibitory effect of CypD loss‐of‐function is closely associated with compromised flexibility of dendritic mitochondrial calcium regulation during neuronal depolarization, as well as the resultant changes in intradendritic calcium homeostasis, calcium signaling activation, dendritic mitochondrial motility and redistribution. Interestingly, loss of CypD attenuates oxidative stress‐induced mitochondrial calcium perturbations and dendritic protrusion injury. Therefore, our study has revealed the physiological function of CypD in dendritic plasticity by acting as a fine‐tuner of mitochondrial calcium homeostasis. Moreover, CypD plays distinct roles in neuronal physiology and pathology.
Cover Image for this issue: doi: 10.1111/jnc.14189 . 相似文献
Proper neuronal function requires essential biological cargoes to be packaged within membranous vesicles and transported, intracellularly, through the extensive outgrowth of axonal and dendritic fibers. The precise spatiotemporal movement of these cargoes is vital for neuronal survival and, thus, is highly regulated. In this study we test how the axonal movement of a neuropeptide‐containing dense‐core vesicle (DCV ) responds to alcohol stressors. We found that ethanol induces a strong anterograde bias in vesicle movement. Low doses of ethanol stimulate the anterograde movement of neuropeptide‐DCV while high doses inhibit bi‐directional movement. This process required the presence of functional kinesin‐1 motors as reduction in kinesin prevented the ethanol‐induced stimulation of the anterograde movement of neuropeptide‐DCV . Furthermore, expression of inactive glycogen synthase kinase 3 (GSK ‐3β) also prevented ethanol‐induced stimulation of neuropeptide‐DCV movement, similar to pharmacological inhibition of GSK ‐3β with lithium. Conversely, inhibition of PI 3K/AKT signaling with wortmannin led to a partial prevention of ethanol‐stimulated transport of neuropeptide‐DCV . Taken together, we conclude that GSK ‐3β signaling mediates the stimulatory effects of ethanol. Therefore, our study provides new insight into the physiological response of the axonal movement of neuropeptide‐DCV to exogenous stressors.
Cover Image for this Issue: doi: 10.1111/jnc.14165 . 相似文献
The mechanism by which extracellular molecules control serotonergic cell fate remains elusive. Recently, we showed that noggin, which inactivates bone morphogenetic proteins (BMPs), induces serotonergic differentiation of mouse embryonic (ES) and induced pluripotent stem cells with coordinated gene expression along the serotonergic lineage. Here, we created a rapid assay for serotonergic induction by generating knock‐in ES cells expressing a naturally secreted Gaussia luciferase driven by the enhancer of Pet‐1/Fev, a landmark of serotonergic differentiation. Using these cells, we performed candidate‐based screening and identified BMP type I receptor kinase inhibitors LDN‐193189 and DMH1 as activators of luciferase. LDN‐193189 induced ES cells to express the genes encoding Pet‐1, tryptophan hydroxylase 2, and the serotonin transporter, and increased serotonin release without altering dopamine release. In contrast, TGF‐β receptor inhibitor SB‐431542 selectively inhibited serotonergic differentiation, without changing overall neuronal differentiation. LDN‐193189 inhibited expression of the BMP signaling target gene Id, and induced the TGF‐β target gene Lefty, whereas the opposite effect was observed with SB‐431542. This study thus provides a new tool to investigate serotonergic differentiation and suggests that inhibition of BMP type I receptors and concomitant activation of TGF‐β receptor signaling are implicated in serotonergic differentiation.
Secondary neuronal death is a serious stroke complication. This process is facilitated by the conversion of glial cells to the reactive pro‐inflammatory phenotype that induces neurodegeneration. Therefore, regulation of glial activation is a compelling strategy to reduce brain damage after stroke. However, drugs have difficulties to access the CNS , and to specifically target glial cells. In the present work, we explored the use core‐shell polyamidoamine tecto‐dendrimer (G5G2.5 PAMAM ) and studied its ability to target distinct populations of stroke‐activated glial cells. We found that G5G2.5 tecto‐dendrimer is actively engulfed by primary glial cells in a time‐ and dose‐dependent manner showing high cellular selectivity and lysosomal localization. In addition, oxygen‐glucose deprivation or lipopolysaccharides exposure in vitro and brain ischemia in vivo increase glial G5G2.5 uptake; not being incorporated by neurons or other cell types. We conclude that G5G2.5 tecto‐dendrimer is a highly suitable carrier for targeted drug delivery to reactive glial cells in vitro and in vivo after brain ischemia.
Lower levels of the cognitively beneficial docosahexaenoic acid (DHA) are often observed in Alzheimer's disease (AD) brains. Brain DHA levels are regulated by the blood‐brain barrier (BBB) transport of plasma‐derived DHA, a process facilitated by fatty acid‐binding protein 5 (FABP5). This study reports a 42.1 ± 12.6% decrease in the BBB transport of 14C‐DHA in 8‐month‐old AD transgenic mice (APPswe,PSEN1?E9) relative to wild‐type mice, associated with a 34.5 ± 6.7% reduction in FABP5 expression in isolated brain capillaries of AD mice. Furthermore, short‐term spatial and recognition memory deficits were observed in AD mice on a 6‐month n‐3 fatty acid‐depleted diet, but not in AD mice on control diet. This intervention led to a dramatic reduction (41.5 ± 11.9%) of brain DHA levels in AD mice. This study demonstrates FABP5 deficiency and impaired DHA transport at the BBB are associated with increased vulnerability to cognitive deficits in mice fed an n‐3 fatty acid‐depleted diet, in line with our previous studies demonstrating a crucial role of FABP5 in BBB transport of DHA and cognitive function.
Parkinson's disease (PD) is a progressive neurodegenerative disorder, of which 1% of the hereditary cases are linked to mutations in DJ‐1, an oxidative stress sensor. The pathological hallmark of PD is intercellular inclusions termed Lewy Bodies, composed mainly of α‐Synuclein (α‐Syn) protein. Recent findings have shown that α‐Syn can be transmitted from cell to cell, suggesting an important role of microglia, as the main scavenger cells of the brain, in clearing α‐Syn. We previously reported that the knock down (KD) of DJ‐1 in microglia increased cells’ neurotoxicity to dopaminergic neurons. Here, we discovered that α‐Syn significantly induced elevated secretion of the proinflammatory cytokines IL‐6 and IL‐1β and a significant dose‐dependent elevation in the production of nitric oxide in DJ‐1 KD microglia, compared to control microglia. We further investigated the ability of DJ‐1 KD microglia to uptake and degrade soluble α‐Syn, and discovered that DJ‐1 KD reduces cell‐surface lipid raft expression in microglia and impairs their ability to uptake soluble α‐Syn. Autophagy is an important mechanism for degradation of intracellular proteins and organelles. We discovered that DJ‐1 KD microglia exhibit an impaired autophagy‐dependent degradation of p62 and LC3 proteins, and that manipulation of autophagy had less effect on α‐Syn uptake and clearance in DJ‐1 KD microglia, compared to control microglia. Further studies of the link between DJ‐1, α‐Syn uptake and autophagy may provide useful insights into the role of microglia in the etiology of the PD.
Airborne particulate matter (PM) from urban vehicular aerosols altered glutamate receptor functions and induced glial inflammatory responses in rodent models after chronic exposure. Potential neurotoxic mechanisms were analyzed in vitro. In hippocampal slices, 2 h exposure to aqueous nanosized PM (nPM) selectively altered post‐synaptic proteins in cornu ammonis area 1 (CA1) neurons: increased GluA1, GluN2A, and GluN2B, but not GluA2, GluN1, or mGlur5; increased post synaptic density 95 and spinophilin, but not synaptophysin, while dentate gyrus (DG) neurons were unresponsive. In hippocampal slices and neurons, MitoSOX red fluorescence was increased by nPM, implying free radical production. Specifically, N? production by slices was increased within 15 min of exposure to nPM with dose dependence, 1–10 μg/mL. Correspondingly, CA1 neurons exhibited increased nitrosylation of the GluN2A receptor and dephosphorylation of GluN2B (S1303) and of GluA1 (S831 & S845). Again, DG neurons were unresponsive to nPM. The induction of N? and nitrosylation were inhibited by AP5, an NMDA receptor antagonist, which also protects neurite outgrowth in vitro from inhibition by nPM. Membrane injury (EthidiumD‐1 uptake) showed parallel specificity. Finally, nPM decreased evoked excitatory post‐synaptic currents of CA1 neurons. These findings further document the selective impact of nPM on glutamatergic functions and identify novel responses of NMDA receptor‐stimulated N? production and nitrosylation reactions during nPM‐mediated neurotoxicity.
It is essential to study the molecular architecture of post‐synaptic density (PSD ) to understand the molecular mechanism underlying the dynamic nature of PSD , one of the bases of synaptic plasticity. A well‐known model for the architecture of PSD of type I excitatory synapses basically comprises of several scaffolding proteins (scaffold protein model). On the contrary, ‘PSD lattice’ observed through electron microscopy has been considered a basic backbone of type I PSD s. However, major constituents of the PSD lattice and the relationship between the PSD lattice and the scaffold protein model, remain unknown. We purified a PSD lattice fraction from the synaptic plasma membrane of rat forebrain. Protein components of the PSD lattice were examined through immuno‐gold negative staining electron microscopy. The results indicated that tubulin, actin, α‐internexin, and Ca2+/calmodulin‐dependent kinase II are major constituents of the PSD lattice, whereas scaffold proteins such as PSD ‐95, SAP 102, GKAP , Shank1, and Homer, were rather minor components. A similar structure was also purified from the synaptic plasma membrane of forebrains from 7‐day‐old rats. On the basis of this study, we propose a ‘PSD lattice‐based dynamic nanocolumn’ model for PSD molecular architecture, in which the scaffold protein model and the PSD lattice model are combined and an idea of dynamic nanocolumn PSD subdomain is also included. In the model, cytoskeletal proteins, in particular, tubulin, actin, and α‐internexin, may play major roles in the construction of the PSD backbone and provide linker sites for various PSD scaffold protein complexes/subdomains.
Epilepsy is a chronic brain disease affecting millions of individuals. Kainate receptors, especially kainate‐type of ionotropic glutamate receptor 2 (GluK2), play an important role in epileptogenesis. Recent data showed that GluK2 could undergo post‐translational modifications in terms of S‐nitrosylation (SNO ), and affect the signaling pathway of cell death in cerebral ischemia‐reperfusion. However, it is unclear whether S‐nitrosylation of GluK2 (SNO ‐GluK2) contributes to cell death induced by epilepsy. Here, we report that kainic acid‐induced SNO ‐GluK2 is mediated by GluK2 itself, regulated by neuronal nitric oxide synthase (nNOS ) and the level of cytoplasmic calcium in vivo and in vitro hippocampus neurons. The whole‐cell patch clamp recordings showed the influence of SNO ‐GluK2 on ion channel characterization of GluK2‐Kainate receptors. Moreover, immunohistochemistry staining results showed that inhibition of SNO ‐GluK2 by blocking nNOS or GluK2 or by reducing the level of cytoplasmic calcium‐protected hippocampal neurons from kainic acid‐induced injury. Finally, immunoprecipitation and western blotting data revealed the involvement of assembly of a GluK2‐PSD 95‐nNOS signaling complex in epilepsy. Taken together, our results showed that the SNO ‐GluK2 plays an important role in neuronal injury of epileptic rats by forming GluK2‐PSD 95‐nNOS signaling module in a cytoplasmic calcium‐dependent way, suggesting a potential therapeutic target site for epilepsy.
The formation of neurotoxic prion protein (PrP) oligomers is thought to be a key step in the development of prion diseases. Recently, it was determined that the sonication and shaking of recombinant PrP can convert PrP monomers into β‐state oligomers. Herein, we demonstrate that β‐state oligomeric PrP can be generated through protein misfolding cyclic amplification from recombinant full‐length hamster, human, rabbit, and mutated rabbit PrP, and that these oligomers can be used for subsequent research into the mechanisms of PrP‐induced neurotoxicity. We have characterized protein misfolding cyclic amplification‐induced monomer‐to‐oligomer conversion of PrP from three species using western blotting, circular dichroism, size‐exclusion chromatography, and resistance to proteinase K (PK) digestion. We have further shown that all of the resulting β‐oligomers are toxic to primary mouse cortical neurons independent of the presence of PrPC in the neurons, whereas the corresponding monomeric PrP were not toxic. In addition, we found that this toxicity is the result of oligomer‐induced apoptosis via regulation of Bcl‐2, Bax, and caspase‐3 in both wild‐type and PrP?/? cortical neurons. It is our hope that these results may contribute to our understanding of prion transformation within the brain.
Peripherin is a type III intermediate filament protein, the expression of which is associated with the acquisition and maintenance of a terminally differentiated neuronal phenotype. Peripherin up‐regulation occurs during acute neuronal injury and in degenerating motor neurons of amyotrophic lateral sclerosis. The functional role(s) of peripherin during normal, injurious, and disease conditions remains unknown, but may be related to differential expression of spliced isoforms. To better understand peripherin function, we performed a yeast two‐hybrid screen on a mouse brain cDNA library using an assembly incompetent peripherin isoform, Per‐61, as bait. We identified new peripherin interactors with roles in vesicular trafficking, signal transduction, DNA/RNA processing, protein folding, and mitochondrial metabolism. We focused on the interaction of Per‐61 and the constitutive isoform, Per‐58, with SNAP25 interacting protein 30 (SIP30), a neuronal protein involved in SNAP receptor‐dependent exocytosis. We found that peripherin and SIP30 interacted through coiled‐coil domains and colocalized in cytoplasmic aggregates in SW13vim(?) cells. Interestingly, Per‐61 and Per‐58 differentially altered the subcellular distribution of SIP30 and SNAP25 in primary motor neurons. Our findings suggest a novel role of peripherin in vesicle trafficking.
Cocaine is a recreational drug of abuse that binds to the dopamine transporter, preventing reuptake of dopamine into pre‐synaptic terminals. The increased presence of synaptic dopamine results in stimulation of both pre‐ and post‐synaptic dopamine receptors, considered an important mechanism by which cocaine elicits its reinforcing properties. However, the effects of acute cocaine administration on pre‐synaptic dopamine function remain unclear. Non‐invasive imaging techniques such as positron emission tomography have revealed impaired pre‐synaptic dopamine function in chronic cocaine users. Similar impairments have been seen in animal studies, with microdialysis experiments indicating decreased basal dopamine release. Here we use micro positron emission tomography imaging techniques in mice to measure dopamine synthesis capacity and determine the effect of acute cocaine administration of pre‐synaptic dopamine function. We show that a dose of 20 mg/kg cocaine is sufficient to elicit hyperlocomotor activity, peaking 15–20 min post treatment (p < 0.001). However, dopamine synthesis capacity in the striatum was not significantly altered by acute cocaine treatment (: 0.0097 per min vs. 0.0112 per min in vehicle controls, p > 0.05). Furthermore, expression levels of two key enzymes related to dopamine synthesis, tyrosine hydroxylase and aromatic l ‐amino acid decarboxylase, within the striatum of scanned mice were not significantly affected by acute cocaine pre‐treatment (p > 0.05). Our findings suggest that while the regulation of dopamine synthesis and release in the striatum have been shown to change with chronic cocaine use, leading to a reduced basal tone, these adaptations to pre‐synaptic dopaminergic neurons are not initiated following a single exposure to the drug.
Developing oligodendrocytes, collectively termed ‘pre‐myelinating oligodendrocytes’ (preOLs), are vulnerable to hypoxic or ischemic insults. The underlying mechanism of this vulnerability remains unclear. Previously, we showed that Bcl‐2?E1B‐19K‐interacting protein 3 (BNIP3), a proapoptotic member of the Bcl‐2 family proteins, induced neuronal death in a caspase‐independent manner in stroke. In this study, we investigated the role of BNIP3 in preOL cell death induced by hypoxia or ischemia. In primary oligodendrocyte progenitor cell (OPC) cultures exposed to oxygen–glucose deprivation, we found that BNIP3 was upregulated and levels of BNIP3 expression correlated with the death of OPCs. Up‐regulation of BNIP3 was observed in preOLs in the white matter in a neonatal rat model of stroke. Knockout of BNIP3 significantly reduced death of preOLs in the middle cerebral artery occlusion model in mice. Our results demonstrate a role of BNIP3 in mediating preOLs cell death induced by hypoxia or ischemia, and suggest that BNIP3 may be a new target for protecting oligodendrocytes from death after stroke.
EphrinA/EphA‐dependent axon repulsion is crucial for synaptic targeting in developing neurons but downstream molecular mechanisms remain obscure. Here, it is shown that ephrinA5/EphA3 triggers proteolysis of the neural cell adhesion molecule (NCAM) by the metalloprotease a disintegrin and metalloprotease (ADAM)10 to promote growth cone collapse in neurons from mouse neocortex. EphrinA5 induced ADAM10 activity to promote ectodomain shedding of polysialic acid‐NCAM in cortical neuron cultures, releasing a ~ 250 kDa soluble fragment consisting of most of its extracellular region. NCAM shedding was dependent on ADAM10 and EphA3 kinase activity as shown in HEK293T cells transfected with dominant negative ADAM10 and kinase‐inactive EphA3 (K653R) mutants. Purified ADAM10 cleaved NCAM at a sequence within the E‐F loop of the second fibronectin type III domain (Leu671‐Lys672/Ser673‐Leu674) identified by mass spectrometry. Mutations of NCAM within the ADAM10 cleavage sequence prevented EphA3‐induced shedding of NCAM in HEK293T cells. EphrinA5‐induced growth cone collapse was dependent on ADAM10 activity, was inhibited in cortical cultures from NCAM null mice, and was rescued by WT but not ADAM10 cleavage site mutants of NCAM. Regulated proteolysis of NCAM through the ephrin5/EphA3/ADAM10 mechanism likely impacts synapse development, and may lead to excess NCAM shedding when disrupted, as implicated in neurodevelopmental disorders such as schizophrenia.
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