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.
Chromogranin A and B (Cgs) are considered to be master regulators of cargo sorting for the regulated secretory pathway (RSP ) and dense‐core vesicle (DCV ) biogenesis. To test this, we analyzed the release of neuropeptide Y (NPY )‐pH luorin, a live RSP reporter, and the distribution, number, and appearance of DCV s, in mouse hippocampal neurons lacking expression of CHGA and CHGB genes. qRT ‐PCR analysis showed that expression of other granin family members was not significantly altered in CgA/B?/? neurons. As synaptic maturation of developing neurons depends on secretion of trophic factors in the RSP , we first analyzed neuronal development in standardized neuronal cultures. Surprisingly, dendritic and axonal length, arborization, synapse density, and synaptic vesicle accumulation in synapses were all normal in CgA/B?/? neurons. Moreover, the number of DCV s outside the soma, stained with endogenous marker Secretogranin II , the number of NPY ‐pH luorin puncta, and the total amount of reporter in secretory compartments, as indicated by pH ‐sensitive NPY ‐pH luorin fluorescence, were all normal in CgA/B?/? neurons. Electron microscopy revealed that synapses contained a normal number of DCV s, with a normal diameter, in CgA/B?/? neurons. In contrast, CgA/B?/? chromaffin cells contained fewer and smaller secretory vesicles with a smaller core size, as previously reported. Finally, live‐cell imaging at single vesicle resolution revealed a normal number of fusion events upon bursts of action potentials in CgA/B?/? neurons. These events had normal kinetics and onset relative to the start of stimulation. Taken together, these data indicate that the two chromogranins are dispensable for cargo sorting in the RSP and DCV biogenesis in mouse hippocampal neurons.
Characterization of the molecular signaling pathways underlying protein synthesis‐dependent forms of synaptic plasticity, such as late long‐term potentiation (L‐LTP ), can provide insights not only into memory expression/maintenance under physiological conditions but also potential mechanisms associated with the pathogenesis of memory disorders. Here, we report in mice that L‐LTP failure induced by the mammalian (mechanistic) target of rapamycin complex 1 (mTORC 1) inhibitor rapamycin is reversed by brain‐specific genetic deletion of PKR ‐like ER kinase, PERK (PERK KO ), a kinase for eukaryotic initiation factor 2α (eIF 2α). In contrast, genetic removal of general control non‐derepressible‐2, GCN 2 (GCN 2 KO ), another eIF 2α kinase, or treatment of hippocampal slices with the PERK inhibitor GSK 2606414, does not rescue rapamycin‐induced L‐LTP failure, suggesting mechanisms independent of eIF 2α phosphorylation. Moreover, we demonstrate that phosphorylation of eukaryotic elongation factor 2 (eEF 2) is significantly decreased in PERK KO mice but unaltered in GCN 2 KO mice or slices treated with the PERK inhibitor. Reduction in eEF 2 phosphorylation results in increased general protein synthesis, and thus could contribute to the mTORC 1‐independent L‐LTP in PERK KO mice. We further performed experiments on mutant mice with genetic removal of eEF 2K (eEF 2K KO ), the only known kinase for eEF 2, and found that L‐LTP in eEF 2K KO mice is insensitive to rapamycin. These data, for the first time, connect reduction in PERK activity with the regulation of translation elongation in enabling L‐LTP independent of mTORC 1. Thus, our findings indicate previously unrecognized levels of complexity in the regulation of protein synthesis‐dependent synaptic plasticity.
Read the Editorial Highlight for this article on page 119 . Cover Image for this issue: doi: 10.1111/jnc.14185 . 相似文献
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.
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.
Most ingested ethanol is metabolized in the liver to acetaldehyde and then to acetate, which can be oxidized by the brain. This project assessed whether chronic exposure to alcohol can increase cerebral oxidation of acetate. Through metabolism, acetate may contribute to long‐term adaptation to drinking. Two groups of adult male Sprague–Dawley rats were studied, one treated with ethanol vapor and the other given room air. After 3 weeks the rats received an intravenous infusion of [2‐13C]ethanol via a lateral tail vein for 2 h. As the liver converts ethanol to [2‐13C]acetate, some of the acetate enters the brain. Through oxidation the 13C is incorporated into the metabolic intermediate α‐ketoglutarate, which is converted to glutamate (Glu), glutamine (Gln), and GABA. These were observed by magnetic resonance spectroscopy and found to be 13C‐labeled primarily through the consumption of ethanol‐derived acetate. Brain Gln, Glu, and, GABA 13C enrichments, normalized to 13C‐acetate enrichments in the plasma, were higher in the chronically treated rats than in the ethanol‐naïve rats, suggesting increased cerebral uptake and oxidation of circulating acetate. Chronic ethanol exposure increased incorporation of systemically derived acetate into brain Gln, Glu, and GABA, key neurochemicals linked to brain energy metabolism and neurotransmission.
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.
A major hallmark feature of Alzheimer's disease is the accumulation of amyloid β (Aβ), whose formation is regulated by the γ‐secretase complex and its activating protein (also known as γ‐secretase activating protein, or GSAP). Because GSAP interacts with the γ‐secretase without affecting the cleavage of Notch, it is an ideal target for a viable anti‐Aβ therapy. GSAP derives from a C‐terminal fragment of a larger precursor protein of 98 kDa via a caspase 3‐mediated cleavage. However, the mechanism(s) involved in its degradation remain unknown. In this study, we show that GSAP has a short half‐life of approximately 5 h. Neuronal cells treated with proteasome inhibitors markedly prevented GSAP protein degradation, which was associated with a significant increment in Aβ levels and γ‐secretase cleavage products. In contrast, treatment with calpain blocker and lysosome inhibitors had no effect. In addition, we provide experimental evidence that GSAP is ubiquitinated. Taken together, our findings reveal that GSAP is degraded through the ubiquitin–proteasome system. Modulation of the GSAP degradation pathway may be implemented as a viable target for a safer anti‐Aβ therapeutic approach in Alzheimer's disease.
Radiotherapy is the major treatment modality for primary and metastatic brain tumors which involves the exposure of brain to ionizing radiation. Ionizing radiation can induce various detrimental pathophysiological effects in the adult brain, and Alzheimer's disease and related neurodegenerative disorders are considered to be late effects of radiation. In this study, we investigated whether ionizing radiation causes changes in tau phosphorylation in cultured primary neurons similar to that in Alzheimer's disease. We demonstrated that exposure to 0.5 or 2 Gy γ rays causes increased phosphorylation of tau protein at several phosphorylation sites in a time‐ and dose‐dependent manner. Consistently, we also found ionizing radiation causes increased activation of GSK3β, c‐Jun N‐terminal kinase and extracellular signal‐regulated kinase before radiation‐induced increase in tau phosphorylation. Specific inhibitors of these kinases almost fully blocked radiation‐induced tau phosphorylation. Our studies further revealed that oxidative stress plays an important role in ionizing radiation‐induced tau phosphorylation, likely through the activation of c‐Jun N‐terminal kinase and extracellular signal‐regulated kinase, but not GSK3β. Overall, our studies suggest that ionizing radiation may cause increased risk for development of Alzheimer's disease by promoting abnormal tau phosphorylation.
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.
Anxiety disorders are associated with a high social burden worldwide. Recently, increasing evidence suggests that nuclear factor kappa B (NF‐κB) has significant implications for psychiatric diseases, including anxiety and depressive disorders. However, the molecular mechanisms underlying the role of NF‐κB in stress‐induced anxiety behaviors are poorly understood. In this study, we show that chronic mild stress (CMS) and glucocorticoids dramatically increased the expression of NF‐κB subunits p50 and p65, phosphorylation and acetylation of p65, and the level of nuclear p65 in vivo and in vitro , implicating activation of NF‐κB signaling in chronic stress‐induced pathological processes. Using the novelty‐suppressed feeding (NSF) and elevated‐plus maze (EPM) tests, we found that treatment with pyrrolidine dithiocarbamate (PDTC; intra‐hippocampal infusion), an inhibitor of NF‐κB, rescued the CMS‐ or glucocorticoid‐induced anxiogenic behaviors in mice. Microinjection of PDTC into the hippocampus reversed CMS‐induced up‐regulation of neuronal nitric oxide synthase (nNOS), carboxy‐terminal PDZ ligand of nNOS (CAPON), and dexamethasone‐induced ras protein 1 (Dexras1) and dendritic spine loss of dentate gyrus (DG) granule cells. Moreover, over‐expression of CAPON by infusing LV‐CAPON‐L‐GFP into the hippocampus induced nNOS‐Dexras1 interaction and anxiety‐like behaviors, and inhibition of NF‐κB by PDTC reduced the LV‐CAPON‐L‐GFP‐induced increases in nNOS‐Dexras1 complex and anxiogenic‐like effects in mice. These findings indicate that hippocampal NF‐κB mediates anxiogenic behaviors, probably via regulating the association of nNOS‐CAPON‐Dexras1, and uncover a novel approach to the treatment of anxiety disorders.
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
Chronic stress represents a major environmental risk factor for mood disorders in vulnerable individuals. The neurobiological mechanisms underlying these disorders involve serotonergic and endocannabinoid systems. In this study, we have investigated the relationships between these two neurochemical systems in emotional control using genetic and imaging tools. CB1 cannabinoid receptor knockout mice (KO) and wild‐type littermates (WT) were exposed to chronic restraint stress. Depressive‐like symptoms (anhedonia and helplessness) were produced by chronic stress exposure in WT mice. CB1 KO mice already showed these depressive‐like manifestations in non‐stress conditions and the same phenotype was observed after chronic restraint stress. Chronic stress similarly impaired long‐term memory in both genotypes. In addition, brain levels of serotonin transporter (5‐HTT) were assessed using positron emission tomography. Decreased brain 5‐HTT levels were revealed in CB1 KO mice under basal conditions, as well as in WT mice after chronic stress. Our results show that chronic restraint stress induced depressive‐like behavioral alterations and brain changes in 5‐HTT levels similarly to those revealed in CB1 KO mice in non‐stressed conditions. These results underline the relevance of chronic environmental stress on serotonergic and endocannabinoid transmission for the development of depressive symptoms.
The anterior piriform cortex (APC) is activated by, and is the brain area most sensitive to, essential (indispensable) amino acid (IAA) deficiency. The APC is required for the rapid (20 min) behavioral rejection of IAA deficient diets and increased foraging, both crucial adaptive functions supporting IAA homeostasis in omnivores. The biochemical mechanisms signaling IAA deficiency in the APC block initiation of translation in protein synthesis via uncharged tRNA and the general amino acid control kinase, general control nonderepressing kinase 2. Yet, how inhibition of protein synthesis activates the APC is unknown. The neuronal K+Cl? cotransporter, neural potassium chloride co‐transporter (KCC2), and GABAA receptors are essential inhibitory elements in the APC with short plasmalemmal half‐lives that maintain control in this highly excitable circuitry. After a single IAA deficient meal both proteins were reduced (vs. basal diet controls) in western blots of APC (but not neocortex or cerebellum) and in immunohistochemistry of APC. Furthermore, electrophysiological analyses support loss of inhibitory elements such as the GABAA receptor in this model. As the crucial inhibitory function of the GABAA receptor depends on KCC2 and the Cl? transmembrane gradient it establishes, these results suggest that loss of such inhibitory elements contributes to disinhibition of the APC in IAA deficiency.
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.
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