NMDA receptor dysfunction contributes to impaired brain‐derived neurotrophic factor‐induced facilitation of hippocampal synaptic transmission in a Tau transgenic model

While the spatiotemporal development of Tau pathology has been correlated with occurrence of cognitive deficits in Alzheimer's patients, mechanisms underlying these deficits remain unclear. Both brain‐derived neurotrophic factor (BDNF) and its tyrosine kinase receptor TrkB play a critical role in hippocampus‐dependent synaptic plasticity and memory. When applied on hippocampal slices, BDNF is able to enhance AMPA receptor‐dependent hippocampal basal synaptic transmission through a mechanism involving TrkB and N‐methyl‐d‐Aspartate receptors (NMDAR). Using THY‐Tau22 transgenic mice, we demonstrated that hippocampal Tau pathology is associated with loss of synaptic enhancement normally induced by exogenous BDNF. This defective response was concomitant to significant memory impairments. We show here that loss of BDNF response was due to impaired NMDAR function. Indeed, we observed a significant reduction of NMDA‐induced field excitatory postsynaptic potential depression in the hippocampus of Tau mice together with a reduced phosphorylation of NR2B at the Y1472, known to be critical for NMDAR function. Interestingly, we found that both NR2B and Src, one of the NR2B main kinases, interact with Tau and are mislocalized to the insoluble protein fraction rich in pathological Tau species. Defective response to BDNF was thus likely related to abnormal interaction of Src and NR2B with Tau in THY‐Tau22 animals. These are the first data demonstrating a relationship between Tau pathology and synaptic effects of BDNF and supporting a contribution of defective BDNF response and impaired NMDAR function to the cognitive deficits associated with Tauopathies.     

Adenosine A2A receptors are required for glutamate mGluR5‐ and dopamine D1 receptor‐evoked ERK1/2 phosphorylation in rat hippocampus: involvement of NMDA receptor

Interaction between mGluR5 and NMDA receptors (NMDAR ) is vital for synaptic plasticity and cognition. We recently demonstrated that stimulation of mGluR5 enhances NMDAR responses in hippocampus by phosphorylating NR2B(Tyr1472) subunit, and this reaction was enabled by adenosine A_2A receptors (A_2AR) (J Neurochem, 135, 2015, 714). In this study, by using in vitro phosphorylation and western blot analysis in hippocampal slices of male Wistar rats, we show that mGluR5 stimulation or mGluR5/NMDAR s co‐stimulation synergistically activate ERK 1/2 signaling leading to c‐Fos expression. Interestingly, both reactions are under the permissive control of endogenous adenosine acting through A_2ARs. Moreover, mGluR5‐mediated ERK 1/2 phosphorylation depends on NMDAR , which however exhibits a metabotropic way of function, since no ion influx through its ion channel is required. Furthermore, our results demonstrate that mGluR5 and mGluR5/NMDAR ‐evoked ERK 1/2 activation correlates well with the mGluR5/NMDAR ‐evoked NR2B(Tyr1472) phosphorylation, since both phenomena coincide temporally, are Src dependent, and are both enabled by A_2ARs. This indicates a functional involvement of NR2B(Tyr1472) phosphorylation in the ERK 1/2 activation. Our biochemical results are supported by electrophysiological data showing that in CA 1 region of hippocampus, the theta burst stimulation (TBS)‐induced long‐term potentiation coincides temporally with an increase in ERK 1/2 activation and both phenomena are dependent on the tripartite A_2A, mGlu5, and NMDAR s. Furthermore, we show that the dopamine D1 receptors evoked ERK 1/2 activation as well as the NR2B(Tyr1472) phosphorylation are also regulated by endogenous adenosine and A_2ARs. In conclusion, our results highlight the A_2ARs as a crucial regulator not only for NMDAR responses, but also for regulating ERK 1/2 signaling and its downstream pathways, leading to gene expression, synaptic plasticity, and memory consolidation.

     

Surface dynamics of GluN2B‐NMDA receptors controls plasticity of maturing glutamate synapses

NMDA‐type glutamate receptors (NMDAR) are central actors in the plasticity of excitatory synapses. During adaptive processes, the number and composition of synaptic NMDAR can be rapidly modified, as in neonatal hippocampal synapses where a switch from predominant GluN2B‐ to GluN2A‐containing receptors is observed after the induction of long‐term potentiation (LTP). However, the cellular pathways by which surface NMDAR subtypes are dynamically regulated during activity‐dependent synaptic adaptations remain poorly understood. Using a combination of high‐resolution single nanoparticle imaging and electrophysiology, we show here that GluN2B‐NMDAR are dynamically redistributed away from glutamate synapses through increased lateral diffusion during LTP in immature neurons. Strikingly, preventing this activity‐dependent GluN2B‐NMDAR surface redistribution through cross‐linking, either with commercial or with autoimmune anti‐NMDA antibodies from patient with neuropsychiatric symptoms, affects the dynamics and spine accumulation of CaMKII and impairs LTP. Interestingly, the same impairments are observed when expressing a mutant of GluN2B‐NMDAR unable to bind CaMKII. We thus uncover a non‐canonical mechanism by which GluN2B‐NMDAR surface dynamics plays a critical role in the plasticity of maturing synapses through a direct interplay with CaMKII.     

Phosphorylation of Tyrosine 1070 at the GluN2B Subunit Is Regulated by Synaptic Activity and Critical for Surface Expression of N-Methyl-d-aspartate (NMDA) Receptors

The number and subunit composition of synaptic N-methyl-d-aspartate receptors (NMDARs) play critical roles in synaptic plasticity, learning, and memory and are implicated in neurological disorders. Tyrosine phosphorylation provides a powerful means of regulating NMDAR function, but the underling mechanism remains elusive. In this study we identified a tyrosine site on the GluN2B subunit, Tyr-1070, which was phosphorylated by a proto-oncogene tyrosine-protein (Fyn) kinase and critical for the surface expression of GluN2B-containing NMDARs. The phosphorylation of GluN2B at Tyr-1070 was required for binding of Fyn kinase to GluN2B, which up-regulated the phosphorylation of GluN2B at Tyr-1472. Moreover, our results revealed that the phosphorylation change of GluN2B at Tyr-1070 accompanied the Tyr-1472 phosphorylation and Fyn associated with GluN2B in synaptic plasticity induced by both chemical and contextual fear learning. Taken together, our findings provide a new mechanism for regulating the surface expression of NMDARs with implications for synaptic plasticity.     

lac‐1 and lag‐1 with ras‐1 affect aging and the biological clock in Neurospora crassa

Using an automated cell counting technique developed previously (Case et al., Ecology and Evolution 2014; 4: 3494), we explore the lifespan effects of lac‐1, a ceramide synthase gene paralogous to lag‐1 in Neurospora crassa in conjunction with the band bd (ras‐1) gene. We find that the replicative lifespan of a lac‐1^KO bd double mutants is short, about one race tube cycle, and this double mutant lacks a strong ~21‐hr clock cycle as shown by race tube and fluorometer analysis of fluorescent strains including lac‐1^KO. This short replicative lifespan phenotype is contrasted with a very long estimated chronological lifespan for lac‐1^KO bd double mutants from 247 to 462 days based on our regression analyses on log viability, and for the single mutant lac‐1^KO, 161 days. Both of these estimated lifespans are much higher than that of previously studied WT and bd single mutant strains. In a lac‐1 rescue and induction experiment, the expression of lac‐1⁺ as driven by a quinic acid‐dependent promoter actually decreases the median chronological lifespan of cells down to only 7 days, much lower than the 34‐day median lifespan found in control bd conidia also grown on quinic acid media, which we interpret as an effect of balancing selection acting on ceramide levels based on previous findings from the literature. Prior work has shown phytoceramides can act as a signal for apoptosis in stressed N. crassa cells. To test this hypothesis of balancing selection on phytoceramide levels, we examine the viability of WT, lag‐1^KO bd, and lac‐1^KO bd strains following the dual stresses of heat and glycolysis inhibition, along with phytoceramide treatments of different dosages. We find that the phytoceramide dosage–response curve is altered in the lag‐1^KO bd mutant, but not in the lac‐1^KO bd mutant. We conclude that phytoceramide production is responsible for the previously reported longevity effects in the lag‐1^KO bd mutant, but a different ceramide may be responsible for the longevity effect observed in the lac‐1^KO bd mutant.     

Differential regulation of CaMKIIα interactions with mGluR5 and NMDA receptors by Ca2+ in neurons

Two glutamate receptors, metabotropic glutamate receptor 5 (mGluR5), and ionotropic NMDA receptors (NMDAR), functionally interact with each other to regulate excitatory synaptic transmission in the mammalian brain. In exploring molecular mechanisms underlying their interactions, we found that Ca²⁺/calmodulin‐dependent protein kinase IIα (CaMKIIα) may play a central role. The synapse‐enriched CaMKIIα directly binds to the proximal region of intracellular C terminal tails of mGluR5 in vitro. This binding is state‐dependent: inactive CaMKIIα binds to mGluR5 at a high level whereas the active form of the kinase (following Ca²⁺/calmodulin binding and activation) loses its affinity for the receptor. Ca²⁺ also promotes calmodulin to bind to mGluR5 at a region overlapping with the CaMKIIα‐binding site, resulting in a competitive inhibition of CaMKIIα binding to mGluR5. In rat striatal neurons, inactive CaMKIIα constitutively binds to mGluR5. Activation of mGluR5 Ca²⁺‐dependently dissociates CaMKIIα from the receptor and simultaneously promotes CaMKIIα to bind to the adjacent NMDAR GluN2B subunit, which enables CaMKIIα to phosphorylate GluN2B at a CaMKIIα‐sensitive site. Together, the long intracellular C‐terminal tail of mGluR5 seems to serve as a scaffolding domain to recruit and store CaMKIIα within synapses. The mGluR5‐dependent Ca²⁺ transients differentially regulate CaMKIIα interactions with mGluR5 and GluN2B in striatal neurons, which may contribute to cross‐talk between the two receptors.

     

Age‐dependent alterations of the NMDA receptor developmental profile and adult behavior in postnatally ketamine‐treated mice

Ketamine is a NMDA receptor (NMDAR) antagonist used in pediatric anesthesia. Given the role of glutamatergic signaling during brain maturation, we studied the effects of a single ketamine injection (40 mg/kg s.c) in mouse neonates depending on postnatal age at injection (P2, P5, or P10) on cortical NMDAR subunits expression and association with Membrane‐Associated Guanylate Kinases PSD95 and SAP102. The effects of ketamine injection at P2, P5, or P10 on motor activity were compared in adulthood. Ketamine increased GluN2A and GluN2B mRNA levels in P2‐treated mice without change in proteins, while it decreased GluN2B protein in P10‐treated mice without change in mRNA. Ketamine reduced GluN2A mRNA and protein levels in P5‐treated mice without change in GluN2B and GluN1. Ketamine affected the GluN2A/PSD95 association regardless of the age at injection, while GluN2B/PSD95 association was enhanced only in P5‐treated mice. Microdissection of ketamine‐treated mouse cortex showed a decrease in GluN2A mRNA level in superficial layers (I–IV) and an increase in all subunit expressions in deep layers (V–VI) in P5‐ and P10‐treated mice, respectively. Our data suggest that ketamine impairs cortical NMDAR subunit developmental profile and delays the synaptic targeting of GluN2A‐enriched NMDAR. Ketamine injection at P2 or P10 resulted in hyperlocomotion in adult male mice in an open field, without change in females. Voluntary running‐wheel exercise showed age‐ and sex‐dependent alterations of the mouse activity, especially during the dark phase. Overall, a single neonatal ketamine exposure led to short‐term NMDAR cortical developmental profile impairments and long‐term motor activity alterations persisting in adulthood. © 2014 Wiley Periodicals, Inc. Develop Neurobiol 75: 315–333, 2015     

Activity-induced synaptic delivery of the GluN2A-containing NMDA receptor is dependent on endoplasmic reticulum chaperone Bip and involved in fear memory

The N-methyl-D-aspartate receptor (NMDAR) in adult forebrain is a heterotetramer mainly composed of two GluN1 subunits and two GluN2A and/or GluN2B subunits. The synaptic expression and relative numbers of GluN2A- and GluN2B-containing NMDARs play critical roles in controlling Ca²⁺-dependent signaling and synaptic plasticity. Previous studies have suggested that the synaptic trafficking of NMDAR subtypes is differentially regulated, but the precise molecular mechanism is not yet clear. In this study, we demonstrated that Bip, an endoplasmic reticulum (ER) chaperone, selectively interacted with GluN2A and mediated the neuronal activity-induced assembly and synaptic incorporation of the GluN2A-containing NMDAR from dendritic ER. Furthermore, the GluN2A-specific synaptic trafficking was effectively disrupted by peptides interrupting the interaction between Bip and GluN2A. Interestingly, fear conditioning in mice was disrupted by intraperitoneal injection of the interfering peptide before training. In summary, we have uncovered a novel mechanism for the activity-dependent supply of synaptic GluN2A-containing NMDARs, and demonstrated its relevance to memory formation.     

Reversal of aging‐associated hippocampal synaptic plasticity deficits by reductants via regulation of thiol redox and NMDA receptor function

Deficits in learning and memory accompanied by age‐related neurodegenerative diseases are closely related to the impairment of synaptic plasticity. In this study, we investigated the role of thiol redox status in the modulation of the N‐methyl‐d ‐aspartate receptor (NMDAR)‐dependent long‐term potentiation (LTP) in CA1 areas of hippocampal slices. Our results demonstrated that the impaired LTP induced by aging could be reversed by acute administration of reductants that can regulate thiol redox status directly, such as dithiothreitol or β‐mercaptoethanol, but not by classical anti‐oxidants such as vitamin C or trolox. This repair was mediated by the recruitment of aging‐related deficits in NMDAR function induced by these reductants and was mimicked by glutathione, which can restore the age‐associated alterations in endogenous thiol redox status. Moreover, antioxidant prevented but failed to reverse H₂O₂‐induced impairment of NMDAR‐mediated synaptic plasticity. These results indicate that the restoring of thiol redox status may be a more effective strategy than the scavenging of oxidants in the treatment of pre‐existing oxidative injury in learning and memory.     

A deficiency of the GluN2C subunit of the N-methyl-D-aspartate receptor is neuroprotective in a mouse model of ischemic stroke

The N-methyl-D-aspartate receptor (NMDAR) ion channel plays a pivotal role in the pathology of ischemic stroke. The functional receptor consists of two GluN1 subunits (a-h) and two GluN2 subunits (A/B/C/D), the expression of which are spatially and temporally regulated in pathological and physiological conditions. While the roles of the GluN2A and GluN2B subunit in ischemic stroke have been well developed, the role of the GluN2C subunit in ischemia is not well understood. Following middle carotid artery occlusion (MCAO), GluN2C^-/- male mice displayed similar volumes of infarct as wild-type (WT) mice. However, GluN2C^-/- mice showed decreased cerebral edema and an enhanced rate of neurological recovery compared to WT mice. The ischemic penumbra of GluN2C^-/- mice showed fewer cytoarchitectural deficits and decreased tauopathy relative to WT mice. These neuroprotective changes in GluN2C^-/- mice also corresponded with decreased expression of Fyn kinase and decreased phosphorylation of GluN2B subunit at Tyr1336. Lastly, a GluN2C deficiency modified the NMDAR/pro-survival signaling axis, as shown by increased levels of nuclear CREB(P-Ser133). Thus, the GluN2C subunit enhances ischemic stroke pathology by promoting neuronal dysfunction in the penumbra region.     

Insulin induces phosphorylation of the AMPA receptor subunit GluR1, reversed by ZIP,and over‐expression of Protein Kinase M zeta,reversed by amyloid beta

Insulin receptor (IR) in the brain plays a role in synaptic plasticity and cognitive functions. Phosphorylation of α‐amino‐3‐hydroxy‐5‐methylisoxazole‐4‐propionic acid (AMPA) receptors GluR1 subunit at Serine 831 is regulated by calcium–calmodulin‐dependent protein kinase II and protein kinase C that underlie long‐term potentiation and learning/memory. Recent studies have shown that the novel Protein Kinase M zeta (PKMζ) underlies synaptic plasticity and may regulate AMPAr. In this study, we show that insulin induces phosphorylation of Serine 831 GluR1 subunit of AMPAr and induces over‐expression of PKMζ; pre‐treatment with either the IR inhibitor 3‐Bromo‐5‐t‐butyl‐4‐hydroxy‐benzylidenemalonitrile (AG1024) or PKMζ inhibitor protein kinase C zeta pseudo‐substrate inhibitor returned the phosphorylation value of GluR1 to control level. Amyloid beta (Aβ) peptide in the form of oligomers interferes with IR signaling. Pre‐treating neuronal cultures with Aβ following incubation with insulin, we found a reduction of insulin‐dependent PKMζ over‐expression and MAPK/Erk (1/2) phosphorylation, i.e., signaling pathways involved in synaptic plasticity and learning/memory. These results indicate a new intracellular insulin signaling pathway, and, additionally, that insulin resistance in Alzheimer's disease is a response to the production and accumulation of Aβ.

     

The mitochondrial uncoupler DNP triggers brain cell mTOR signaling network reprogramming and CREB pathway up‐regulation

Mitochondrial metabolism is highly responsive to nutrient availability and ongoing activity in neuronal circuits. The molecular mechanisms by which brain cells respond to an increase in cellular energy expenditure are largely unknown. Mild mitochondrial uncoupling enhances cellular energy expenditure in mitochondria and can be induced with 2,4‐dinitrophenol (DNP), a proton ionophore previously used for weight loss. We found that DNP treatment reduces mitochondrial membrane potential, increases intracellular Ca²⁺ levels and reduces oxidative stress in cerebral cortical neurons. Gene expression profiling of the cerebral cortex of DNP‐treated mice revealed reprogramming of signaling cascades that included suppression of the mammalian target of rapamycin (mTOR) and insulin – PI3K – MAPK pathways, and up‐regulation of tuberous sclerosis complex 2, a negative regulator of mTOR. Genes encoding proteins involved in autophagy processes were up‐regulated in response to DNP. CREB (cAMP‐response element‐binding protein) signaling, Arc and brain‐derived neurotrophic factor, which play important roles in synaptic plasticity and adaptive cellular stress responses, were up‐regulated in response to DNP, and DNP‐treated mice exhibited improved performance in a test of learning and memory. Immunoblot analysis verified that key DNP‐induced changes in gene expression resulted in corresponding changes at the protein level. Our findings suggest that mild mitochondrial uncoupling triggers an integrated signaling response in brain cells characterized by reprogramming of mTOR and insulin signaling, and up‐regulation of pathways involved in adaptive stress responses, molecular waste disposal, and synaptic plasticity.

     

Neuronal‐specific proteasome augmentation via Prosβ5 overexpression extends lifespan and reduces age‐related cognitive decline

Cognitive function declines with age throughout the animal kingdom, and increasing evidence shows that disruption of the proteasome system contributes to this deterioration. The proteasome has important roles in multiple aspects of the nervous system, including synapse function and plasticity, as well as preventing cell death and senescence. Previous studies have shown neuronal proteasome depletion and inhibition can result in neurodegeneration and cognitive deficits, but it is unclear if this pathway is a driver of neurodegeneration and cognitive decline in aging. We report that overexpression of the proteasome β5 subunit enhances proteasome assembly and function. Significantly, we go on to show that neuronal‐specific proteasome augmentation slows age‐related declines in measures of learning, memory, and circadian rhythmicity. Surprisingly, neuronal‐specific augmentation of proteasome function also produces a robust increase of lifespan in Drosophila melanogaster. Our findings appear specific to the nervous system; ubiquitous proteasome overexpression increases oxidative stress resistance but does not impact lifespan and is detrimental to some healthspan measures. These findings demonstrate a key role of the proteasome system in brain aging.     

Zinc transporter‐1: a novel NMDA receptor‐binding protein at the postsynaptic density

Zinc (Zn²⁺) is believed to play a relevant role in the physiology and pathophysiology of the brain. Hence, Zn²⁺ homeostasis is critical and involves different classes of molecules, including Zn²⁺ transporters. The ubiquitous Zn²⁺ transporter‐1 (ZNT‐1) is a transmembrane protein that pumps cytosolic Zn²⁺ to the extracellular space, but its function in the central nervous system is not fully understood. Here, we show that ZNT‐1 interacts with GluN2A‐containing NMDA receptors, suggesting a role for this transporter at the excitatory glutamatergic synapse. First, we found that ZNT‐1 is highly expressed at the hippocampal postsynaptic density (PSD) where NMDA receptors are enriched. Two‐hybrid screening, coimmunoprecipitation experiments and clustering assay in COS‐7 cells demonstrated that ZNT‐1 specifically binds the GluN2A subunit of the NMDA receptor. GluN2A deletion mutants and pull‐down assays indicated GluN2A(1390–1464) domain as necessary for the binding to ZNT‐1. Most importantly, ZNT‐1/GluN2A complex was proved to be dynamic, since it was regulated by induction of synaptic plasticity. Finally, modulation of ZNT‐1 expression in hippocampal neurons determined a significant change in dendritic spine morphology, PSD‐95 clusters and GluN2A surface levels, supporting the involvement of ZNT‐1 in the dynamics of excitatory PSD.

     

Differential association of postsynaptic signaling protein complexes in striatum and hippocampus

Distinct physiological stimuli are required for bidirectional synaptic plasticity in striatum and hippocampus, but differences in the underlying signaling mechanisms are poorly understood. We have begun to compare levels and interactions of key excitatory synaptic proteins in whole extracts and subcellular fractions isolated from micro‐dissected striatum and hippocampus. Levels of multiple glutamate receptor subunits, calcium/calmodulin‐dependent protein kinase II (CaMKII), a highly abundant serine/threonine kinase, and spinophilin, a F‐actin and protein phosphatase 1 (PP1) binding protein, were significantly lower in striatal extracts, as well as in synaptic and/or extrasynaptic fractions, compared with similar hippocampal extracts/fractions. However, CaMKII interactions with spinophilin were more robust in striatum compared with hippocampus, and this enhanced association was restricted to the extrasynaptic fraction. NMDAR GluN2B subunits associate with both spinophilin and CaMKII, but spinophilin‐GluN2B complexes were enriched in extrasynaptic fractions whereas CaMKII‐GluN2B complexes were enriched in synaptic fractions. Notably, the association of GluN2B with both CaMKII and spinophilin was more robust in striatal extrasynaptic fractions compared with hippocampal extrasynaptic fractions. Selective differences in the assembly of synaptic and extrasynaptic signaling complexes may contribute to differential physiological regulation of excitatory transmission in striatum and hippocampus.     

Protease‐activated receptor‐1 modulates hippocampal memory formation and synaptic plasticity

Protease‐activated receptor‐1 (PAR1) is an unusual G‐protein coupled receptor (GPCR) that is activated through proteolytic cleavage by extracellular serine proteases. Although previous work has shown that inhibiting PAR1 activation is neuroprotective in models of ischemia, traumatic injury, and neurotoxicity, surprisingly little is known about PAR1's contribution to normal brain function. Here, we used PAR1?/? mice to investigate the contribution of PAR1 function to memory formation and synaptic function. We demonstrate that PAR1?/? mice have deficits in hippocampus‐dependent memory. We also show that while PAR1?/? mice have normal baseline synaptic transmission at Schaffer collateral‐CA1 synapses, they exhibit severe deficits in N‐methyl‐d ‐aspartate receptor (NMDAR)‐dependent long‐term potentiation (LTP). Mounting evidence indicates that activation of PAR1 leads to potentiation of NMDAR‐mediated responses in CA1 pyramidal cells. Taken together, this evidence and our data suggest an important role for PAR1 function in NMDAR‐dependent processes subserving memory formation and synaptic plasticity.