Inhibition of NR2B phosphorylation restores alterations in NMDA receptor expression and improves functional recovery following traumatic brain injury in mice

Traumatic brain injury (TBI) triggers a massive glutamate efflux, hyperactivation of N-methyl-D-aspartate receptors (NMDARs) and neuronal cell death. Previously it was demonstrated that, 15 min following experimentally induced closed head injury (CHI), the density of activated NMDARs increases in the hippocampus, and decreases in the cortex at the impact site. Here we show that CHI-induced alterations in activated NMDARs correlate with changes in the expression levels of the major NMDARs subunits. In the hippocampus, the expression of NR1, NR2A, and NR2B subunits as well as the GluR1 subunit of the AMPA receptor (AMPAR) were increased, while in the cortex at the impact site, we found a decrease in the expression of these subunits. We demonstrate that CHI-induced increase in the expression of NMDAR subunits and GluR1 in the hippocampus, but not in the cortex, is associated with an increase in NR2B tyrosine phosphorylation. Furthermore, inhibition of NR2B-phosphorylation by the tyrosine kinase inhibitor PP2 restores the expression of this subunit to its normal levels. Finally, a single injection of PP2, prior to the induction of CHI, resulted in a significant improvement in long-term recovery of motor functions observed in CHI mice. These results provide a new mechanism by which acute trauma contributes to the development of secondary damage and functional deficits in the brain, and suggests a possible role for Src tyrosine kinase inhibitors as preoperative therapy for planned neurosurgical procedures.     

Selective postsynaptic co-localization of MCT2 with AMPA receptor GluR2/3 subunits at excitatory synapses exhibiting AMPA receptor trafficking

MCT2 is the main neuronal monocarboxylate transporter needed by neurons if they are to use lactate as an additional energy substrate. Previous evidence suggested that some MCT2 could be located in postsynaptic elements of glutamatergic synapses. Using post-embedding electron microscopic immunocytochemistry, it is demonstrated that MCT2 is present at postsynaptic density of asymmetric synapses, in the stratum radiatum of both rat hippocampal CA1 and CA3 regions, as well as at parallel fibre-Purkinje cell synapses in mouse cerebellum. MCT2 levels were significantly lower at mossy fibre synapses on CA3 neurons, and MCT2 was almost absent from symmetric synapses on CA1 pyramidal cells. It could also be demonstrated using quantitative double-labeling immunogold cytochemistry that MCT2 and AMPA receptor GluR2/3 subunits have a similar postsynaptic distribution at asymmetric synapses with high levels expressed within the postsynaptic density. In addition, as for AMPA receptors, a significant proportion of MCT2 is located on vesicular membranes within the postsynaptic spine, forming an intracellular pool available for a putative postsynaptic endo/exocytotic trafficking at these excitatory synapses. Altogether, the data presented provide evidence for MCT2 expression in the postsynaptic density area at specific subsets of glutamatergic synapses, and also suggest that MCT2, like AMPA receptors, could undergo membrane trafficking.     

Spinal axonal injury induces brief downregulation of ionotropic glutamate receptors and no stripping of synapses in cord-projection central neurons

Spinal cord injury often damages the axons of cord-projecting central neurons. To determine whether their excitatory inputs are altered following axonal injury, we used rat rubrospinal neurons as a model and examined their excitatory input following upper cervical axotomy. Anterograde tracing showed that the primary afferents from the cerebellum terminated in a pattern similar to that of control animals. Ultrastructurally, neurons in the injured nucleus were contacted by excitatory synapses of normal appearance, with no sign of glial stripping. Since cerebellar fibers are glutamatergic, we examined the expression of ionotropic receptor subunits GluR1-4 and NR1 for AMPA and NMDA receptors, respectively, in control and injured neurons using immunolabeling methods. In control neurons, GluR2 appeared to be low as compared to GluR1, GluR3, and GluR4, while NR1 labeling was intense. Following unilateral tractotomy, the levels of expression of each subunit in axotomized neurons appeared to be normal, with the exception that they were lower than those of control neurons of the nonlesioned side at 2-6 days postinjury. These findings suggest that axotomized neurons are only temporarily protected from excitotoxicity. This is in sharp contrast to the responses of central neurons that innervate peripheral targets, in which both synaptic stripping and reduction of their ionotropic glutamate receptor subunits persist following axotomy. The absence of an injury-induced trimming of afferents and stripping of synapses and the lack of a persistent downregulation of postsynaptic receptors might enable injured cord-projection neurons to continue to control their supraspinal targets during most of their postinjury survival. Although this may support neurons by providing trophic influences, it nevertheless may subject them to excitotoxicity and ultimately lead to their degenerative fate.     

Mechanical loading modulates glutamate receptor subunit expression in bone

The cellular mechanisms coupling mechanical loading with bone remodeling remain unclear. In the CNS, the excitatory amino acid glutamate (Glu) serves as a potent neurotransmitter exerting its effects via various membrane Glu receptors (GluR). Nerves containing Glu exist close to bone cells expressing functional GluRs. Demonstration of a mechanically sensitive glutamate/aspartate transporter protein and the ability of glutamate to stimulate bone resorption in vitro suggest a role for glutamate linking mechanical load and bone remodeling. We used immunohistochemical techniques to identify the expression of N-methyl-d-aspartate acid (NMDA) and non-NMDA (AMPA or kainate) ionotropic GluR subunits on bone cells in vivo. In bone sections from young adult rats, osteoclasts expressed numerous GluR subunits including AMPA (GluR2/3 and GluR4), kainic acid (GluR567) and NMDA (NMDAR2A, NMDAR2B and NMDAR2C) receptor subtypes. Bone lining cells demonstrated immunoexpression for NMDAR2A, NMDAR2B, NMDAR2C, GluR567, GluR23, GluR2 and GluR4 subunits. Immunoexpression was not evident on osteocytes, chondrocytes or vascular channels. To investigate the effects of mechanical loading on GluR expression, we used a Materials Testing System (MTS) to apply 10 N sinusoidal axial compressive loads percutaneously to the right limbs (radius/ulna, tibia/fibula) of rats. Each limb underwent 300-load cycles/day (cycle rate, 1 Hz) for 4 consecutive days. Contralateral, non-loaded limbs served as controls. Mechanically loaded limbs revealed a load-induced loss of immunoexpression for GluR2/3, GluR4, GluR567 and NMDAR2A on osteoclasts and NMDAR2A, NMDAR2B, GluR2/3 and GluR4 on bone lining cells. Both neonatal rabbit and rat osteoclasts were cultured on bone slices to investigate the effect of the NMDA receptor antagonist, MK801, and the AMPA/kainic acid receptor antagonist, NBQX, on osteoclast resorptive activity in vitro. The inhibition of resorptive function seen suggested that both NMDAR and kainic acid receptor function are required for normal osteoclast function. While the exact role of ionotropic GluRs in skeletal tissue remains unclear, the modulation of GluR subunit expression by mechanical loading lends further support for participation of Glu as a mechanical loading effector. These ionotropic receptors appear to be functionally relevant to normal osteoclast resorptive activity.     

Colocalization of glutamate ionotropic receptor subunits in the human temporal neocortex

alpha-Amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA), kainate and N-methyl-D-aspartate (NMDA) receptors represent major classes of glutamate receptors (GluR) which play fundamental roles in normal excitatory synaptic activity and, probably, in the etiology of several brain diseases. These receptors are composed of multiple receptor subunit proteins, and the differential expression of these subunits in cortical neurons is considered to be one of the substrates for the functional diversity of cortical excitatory circuitry. In the monkey neocortex, different subpopulations of neurons have been identified on the basis of immunocytochemical colocalization studies using subunit-specific antibodies, but no comparable investigations have been made in the human neocortex. The aim of the present study was to determine quantitatively GluR subunit combinations in the human temporal neocortex by double-labeling immunocyto- chemical experiments. We quantified the neuronal populations expressing different receptor subtypes with fluorescent tags visualizing them with confocal laser microscopy. We studied AMPA, kainate- and NMDA-receptor subunits, using antibodies against GluR1, GluR2, GluR2/3, GluR2/4, GluR5/6/7 and NMDAR1 subunits. A high degree of colocalization (93-100%) using combinations of antibodies against GluR2 with GluR2/3, GluR2/3 with GluR2/4, and GluR2 or GluR2/4 with NMDAR1 was found, whereas for other combinations the degree of colocalization varied between 38% and 88%. Some of the percentages reported here are similar to those found in the monkey cortex, whereas others differ considerably. These results emphasize the diversity of excitatory circuits in the human neocortex, and suggest species differences with regard to some of these GluR-mediated circuits.     

D4 dopamine receptors modulate NR2B NMDA receptors and LTP in stratum oriens of hippocampal CA1

Dopamine plays an important role in synaptic plasticity and learning and is involved in the pathogenesis of various neurological and psychiatric disorders. Here, we reveal staining of dopaminergic fibers in stratum oriens of the mouse hippocampal CA1 region, a finding that is consistent with earlier reports. Furthermore, we examined the effect of dopamine agonists on NMDAR-dependent early long-term potentiation (LTP) (40 min) during γ-aminobutyric acid (GABA)(A)-mediated blockade. LTP of the AMPA component was strongly reduced in stratum oriens but barely affected in stratum radiatum. This layer-specific effect was caused by D4 receptor activation, which augmented the inactivation of synaptic NMDAR-mediated currents (NMDA EPSCs) during LTP induction through a Ca(2+)-dependent G-protein-independent mechanism. A similar dopaminergic modulation of both NMDA EPSCs and LTP was also observed in mice constitutively lacking NR2A but was absent in mice lacking NR2B in principal forebrain neurons. Together, these experiments strongly indicate that dopaminergic modulation of early LTP in stratum oriens occurs through NMDARs containing NR2B subunits via D4Rs. Thus, a dopamine hyperfunction in stratum oriens may result in NMDAR hypofunction that could affect both normal and pathological conditions.     

切口痛-瑞芬太尼痛觉过敏大鼠脊髓总蛋白及膜蛋白NMDA受体NRl 、NR2A及NR2B亚基表达的变化

目的 评价切口痛-瑞芬太尼痛觉过敏大鼠脊髓总蛋白及膜蛋白NMDA受体NR1、NR2A及NR2B亚基表达的变化.方法 尾静脉置管成功的雄性SD大鼠32只,体重240～260 g,月龄2～3月,采用随机数字表法,将大鼠随机分为4组(n=8):对照组(C组)静脉输注等容量生理盐水60 min,瑞芬太尼组(R组)静脉输注瑞芬太尼1.2μg·kg-1·min-1 60 min;切口痛组(I组)建立切口痛模型,同时静脉输注等容量生理盐水60 min;瑞芬太尼+切口痛组(R+I组)建立切口痛模型,同时静脉输注瑞芬太尼1.2 μg· kg-1 ·min-1 60 min.于生理盐水或瑞芬太尼给药前24h、给药后2、6、24和48 h时测定机械刺激缩足阈值(PWT)和热刺激缩足潜伏期(PWL),最后一次测定痛阈后处死取脊髓L4～6节段,采用Western blot法测定脊髓总蛋白及膜蛋白NMDA受体NR1、NR2A及NR2B亚基的表达,并计算膜蛋白中NR2B/NR2A比值.结果 与C组比较,I组、R组和R+I组PWT降低,PWL缩短,总蛋白及膜蛋白NMDA受体NR1和NR2B亚基表达上调,膜蛋白中NR2B/NR2A比值增加(P＜0.05).与R组和I组比较,R+I组PWT降低,PWL缩短,总蛋白及膜蛋白NMDA受体NR1和NR2B亚基表达上调,膜蛋白中NR2B/NR2A比值增加(P＜0.05).各组总蛋白及膜蛋白NMDA受体NR2A亚基表达差异无统计学意义(P＞0.05).结论 大鼠切口痛-瑞芬太尼痛觉过敏的形成可能与脊髓总蛋白及膜蛋白NMDA受体NR1和NR2B亚基表达上调和膜蛋白中NMDA受体NR2B亚基组成比例的增加有关.     

Vesicular glutamate and GABA transporters sort to distinct sets of vesicles in a population of presynaptic terminals

Vesicular glutamate transporters (VGLUTs) 1 and 2 are expressed by neurons generally accepted to release glutamate as a neurotransmitter, whereas VGLUT3 appears in populations usually associated with a different classical transmitter. We now demonstrate VGLUT2 as well as the vesicular GABA transporter (VGAT) in a subset of presynaptic terminals in the dentate gyrus of the rat hippocampal formation. The terminals are distributed in a characteristic band overlapping with the outer part of the granule cell layer and the inner zone of the molecular layer. Within the terminals, which make asymmetric as well as symmetric synapses onto the somatodendritic compartment of the dentate granule cells, the 2 transporters localize to distinct populations of synaptic vesicles. Moreover, the axons forming these terminals originate in the supramammillary nucleus (SuM). Our data reconcile previous apparently conflicting reports on the physiology of the dentate afferents from SuM and demonstrate that both glutamate and GABA may be released from a single nerve terminal.     

Functional and anatomical identification of a vesicular transporter mediating neuronal ATP release

ATP is known to be coreleased with glutamate at certain central synapses. However, the nature of its release is controversial. Here, we demonstrate that ATP release from cultured rat hippocampal neurons is sensitive to RNAi-mediated knockdown of the recently identified vesicular nucleotide transporter (VNUT or SLC17A9). In the intact brain, light microscopy showed particularly strong VNUT immunoreactivity in the cerebellar cortex, the olfactory bulb, and the hippocampus. Using immunoelectron microscopy, we found VNUT immunoreactivity colocalized with synaptic vesicles in excitatory and inhibitory terminals in the hippocampal formation. Moreover, VNUT immunolabeling, unlike that of the vesicular glutamate transporter VGLUT1, was enriched in preterminal axons and present in postsynaptic dendritic spines. Immunoisolation of synaptic vesicles indicated presence of VNUT in a subset of VGLUT1-containing vesicles. Thus, we conclude that VNUT mediates transport of ATP into synaptic vesicles of hippocampal neurons, thereby conferring a purinergic phenotype to these cells.     

Synaptic distinction of laminar-specific prefrontal-temporal pathways in primates

Prefrontal pathways exert diverse effects in widespread cortical areas, issuing projections both to the middle layers and to layer I, which are anatomically and functionally distinct. Here we addressed the still unanswered question of whether cortical pathways that terminate in different layers are distinct at the synaptic level. We addressed this issue using as a model system the robust and functionally significant pathways from prefrontal areas 10 and 32 to superior temporal areas in rhesus monkeys. Boutons from prefrontal axons synapsing in the middle layers of superior temporal cortex were significantly larger than boutons synapsing in layer I. Most synapses were on spines in both layers, which are found on dendrites of excitatory neurons. The less prevalent synapses on smooth dendrites, characteristic of inhibitory interneurons, were more common in the middle cortical layers than in layer I. Bouton volume was linearly related to vesicular and mitochondrial content in both layers, though a subset of small boutons, found mostly in layer I, contained no mitochondria. The systematic laminar-specific presynaptic differences in stable cortical synapses in adult primates were independent of their origin in the functionally distinct prefrontal areas 10 and 32, or their destination in architectonically distinct superior temporal areas. This synaptic distinction suggests differences in efficacy of synaptic transmission and metabolic demands in laminar-specific pathways that may be selectively recruited in behavior.     

Neuronal and glial localization of NR1 and NR2A/B subunits of the NMDA receptor in the human cerebral cortex

N-Methyl-D-aspartate (NMDA) receptors play a critical role in many cortical functions and are implicated in several neuropsychiatric diseases. In this study, the cellular expression of the NMDAR1 (NR1) and NMDAR2A and B (NR2A and B) subunits was investigated in the human cerebral cortex by immunocytochemistry with antibodies that recognize the NR1 or the NR2A and B subunits of the NMDA receptor. In frontal (areas 10 and 46) and temporal (area 21) association cortices and the cingulofrontal transition cortex (area 32), NR1 and NR2A/B immunoreactivity (ir) were similar and were localized to numerous neurons in all cortical layers. NR1- and NR2A/B-positive neurons were mostly pyramidal cells, but some nonpyramidal neurons were also labeled. Electron-microscopic observations showed that NR1 and NR2A/B ir were similar. In all cases, labeling of dendrites and dendritic spines was intense. In addition, both NR1 and NR2A/B were consistently found in the axoplasm of some axon terminals and in distal astrocytic processes. This investigation revealed that numerous NMDA receptors are localized to dendritic spines, and that they are also localized to axon terminals and astrocytic processes. These findings suggest that the effects of cortical NMDA activation in the human cortex do not depend exclusively on the opening of NMDA channels located at postsynaptic sites, and that the localization of NMDA receptors is similar in a variety of mammalian species.     

Reduced sensitivity to ketamine and pentobarbital in mice lacking the N-methyl-D-aspartate receptor GluRepsilon1 subunit

Ketamine is an IV anesthetic with N-methyl-d-aspartate receptor (NMDAR)-blocking properties. However, it is still unclear whether ketamine's general anesthetic actions are mediated primarily via blockade of NMDAR. Functional NMDARs are composed by the assembly of a GluRzeta1 (NR1) subunit with GluRepsilon (GluRepsilon1-4; NR2A-D) subunits, which confer unique properties on native NMDARs. We hypothesized that animals deficient in GluRepsilon1, an abundant and ubiquitously postnatally expressed NMDAR subunit, might be resistant to the effects of ketamine. Here, we evaluated a righting reflex to determine the general anesthetic/hypnotic potency of ketamine administered intraperitoneally to GluRepsilon1 knockout mice and compared these results with those for wild-type mice. Mutant mice were more resistant to ketamine than control mice. Unexpectedly, mutant mice were also more resistant to pentobarbital, which is thought not to interact with NMDAR at clinically relevant concentrations. Although these data in no way eliminate the possibility of the involvement of the NMDAR GluRepsilon1 subunit in mediation of ketamine anesthesia/hypnosis, they suggest the difficulties with interpretation of altered anesthetic sensitivity in knockout animal models.     

The human temporal cortex: characterization of neurons expressing nitric oxide synthase, neuropeptides and calcium-binding proteins, and their glutamate receptor subunit profiles.

Immunocytochemical techniques were used to examine the distribution of neurons immunoreactive (-ir) for nitric oxide synthase (nNOS), somatostatin (SOM), neuropeptide Y (NPY), parvalbumin (PV), calbindin (CB) and calretinin (CR), in the inferotemporal gyrus (Brodmann's area 21) of the human neocortex. Neurons that colocalized either nNOS or SOM with PV, CB or CR were also identified by double-labeling techniques. Furthermore, glutamate receptor subunit profiles (GluR1, GluR2/3, GluR2/4, GluR5/6/7 and NMDAR1) were also determined for these cells. The number and distribution of cells containing nNOS, SOM, NPY, PV, CB or CR differed for each antigen. In addition, distinct subpopulations of neurons displayed different degrees of colocalization of these antigens depending on which antigens were compared. Moreover, cells that contained nNOS, SOM, NPY, PV, CB or CR expressed different receptor subunit profiles. These results show that specific subpopulations of neurochemically identified nonpyramidal cells may be activated via different receptor subtypes. As these different subpopulations of cells project to specific regions of pyramidal cells, facilitation of subsets of these cells via different receptor subunits may activate different inhibitory circuits. Thus, various distinct, but overlapping, inhibitory circuits may act in concert in the modulation of normal cortical function, plasticity and disease.     

Propofol inhibits phosphorylation of N-methyl-D-aspartate receptor NR1 subunits in neurons

BACKGROUND: Anesthetics may interact with ionotropic glutamate receptors to produce some of their biologic actions. Cellular studies reveal that the ionotropic glutamate receptors, N-methyl-D-aspartate receptors (NMDARs), can be phosphorylated on their NR1 subunits at the C-terminal serine residues, which is a major mechanism for the regulation of NMDAR functions. It is currently unknown whether anesthetics have any modulatory effects on NMDAR NR1 subunit phosphorylation. METHODS: The possible effect of a general anesthetic propofol on phosphorylation of NR1 subunits at serine 897 (pNR1S897) and 896 (pNR1S896) was detected in cultured rat cortical neurons. RESULTS: Propofol consistently reduced basal levels of pNR1S897 and pNR1S896 in a concentration-dependent manner. This reduction was rapid as the reliable reduction of pNR1S896 developed 1 min after propofol administration. Pretreatment of cultures with the protein phosphatase 2A inhibitors okadaic acid or calyculin A blocked the effect of propofol on the NR1 phosphorylation, whereas okadaic acid or calyculin A alone did not alter basal pNR1S897 and pNR1S896 levels. In addition, propofol decreased tyrosine phosphorylation of protein phosphatase 2A at tyrosine 307, resulting in an increase in protein phosphatase 2A activity. In the presence of propofol, the NMDAR agonist-induced intracellular Ca2+ increase was impaired in neurons with dephosphorylated NR1 subunits. CONCLUSIONS: Together, these data indicate an inhibitory effect of a general anesthetic propofol on NMDAR NR1 subunit phosphorylation in neurons. This inhibition was mediated through a signaling mechanism involving activation of protein phosphatase 2A.     

Propofol Inhibits Phosphorylation of N-methyl-d-aspartate Receptor NR1 Subunits in Neurons

Background: Anesthetics may interact with ionotropic glutamate receptors to produce some of their biologic actions. Cellular studies reveal that the ionotropic glutamate receptors, N-methyl-d-aspartate receptors (NMDARs), can be phosphorylated on their NR1 subunits at the C-terminal serine residues, which is a major mechanism for the regulation of NMDAR functions. It is currently unknown whether anesthetics have any modulatory effects on NMDAR NR1 subunit phosphorylation.

Methods: The possible effect of a general anesthetic propofol on phosphorylation of NR1 subunits at serine 897 (pNR1S897) and 896 (pNR1S896) was detected in cultured rat cortical neurons.

Results: Propofol consistently reduced basal levels of pNR1S897 and pNR1S896 in a concentration-dependent manner. This reduction was rapid as the reliable reduction of pNR1S896 developed 1 min after propofol administration. Pretreatment of cultures with the protein phosphatase 2A inhibitors okadaic acid or calyculin A blocked the effect of propofol on the NR1 phosphorylation, whereas okadaic acid or calyculin A alone did not alter basal pNR1S897 and pNR1S896 levels. In addition, propofol decreased tyrosine phosphorylation of protein phosphatase 2A at tyrosine 307, resulting in an increase in protein phosphatase 2A activity. In the presence of propofol, the NMDAR agonist-induced intracellular Ca2+ increase was impaired in neurons with dephosphorylated NR1 subunits.     

Functional maturation of excitatory synapses in layer 3 pyramidal neurons during postnatal development of the primate prefrontal cortex

In the primate dorsolateral prefrontal cortex (DLPFC), the density of excitatory synapses decreases by 40-50% during adolescence. Although such substantial circuit refinement might underlie the adolescence-related maturation of working memory performance, its functional significance remains poorly understood. The consequences of synaptic pruning may depend on the properties of the eliminated synapses. Are the synapses eliminated during adolescence functionally immature, as is the case during early brain development? Or do maturation-independent features tag synapses for pruning? We examined excitatory synaptic function in monkey DLPFC during postnatal development by studying properties that reflect synapse maturation in rat cortex. In 3-month-old (early postnatal) monkeys, excitatory inputs to layer 3 pyramidal neurons had immature properties, including higher release probability, lower alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA)/N-methyl-D-aspartate (NMDA) ratio, and longer duration of NMDA-mediated synaptic currents, associated with greater sensitivity to the NMDA receptor subunit B (NR2B) subunit-selective antagonist ifenprodil. In contrast, excitatory synaptic inputs in neurons from preadolescent (15 months old) and adult (42 or 84 months old) monkeys had similar functional properties. We therefore conclude that the contribution of functionally immature synapses decreases significantly before adolescence begins. Thus, remodeling of excitatory connectivity in the DLPFC during adolescence may occur in the absence of widespread maturational changes in synaptic strength.     

MK-801 upregulates NR2A protein levels and induces functional recovery of the ipsilateral hemidiaphragm following acute C2 hemisection in adult rats

BACKGROUND: C2 hemisection results in paralysis of the ipsilateral hemidiaphragm. Recent data indicate that an upregulation of the N-methyl-D-aspartate (NMDA) receptor 2A subunit following chronic C2 hemisection is associated with spontaneous hemidiaphragmatic recovery following injury. MK-801, an antagonist of the NMDA receptor, upregulates the NR2A subunit in neonatal rats. HYPOTHESIS: We hypothesized that administration of MK-801 to adult, acute C2-hemisected rats would result in an increase of NR2A in the spinal cord. Furthermore, we hypothesized that upregulation of NR2A would be associated with recovery of the ipsilateral hemidiaphragm as in the chronic studies. DESIGN: To develop a dose-response curve, adult rats were treated with varying doses of MK-801 and their spinal cords harvested and assessed for NR2A as well as AMPA GluR1 and GluR2 subunit protein levels. In the second part of this study, C2-hemisected animals received MK-801. Following treatment, the animals were assessed for recovery of the hemidiaphragm through electromyographic recordings and their spinal cords assessed for NR2A, GluR1, and GluR2. RESULTS: Treatment with MK-801 leads to an increase of the NR2A subunit in the spinal cords of adult noninjured rats. There were no changes in the expression of GluR1 and GluR2 in these animals. Administration of MK-801 to C2-hemisected rats resulted in recovery of the ipsilateral hemidiaphragm, an increase of NR2A, and a decrease of GluR2. CONCLUSION: Our findings strengthen the evidence that the NR2A subunit plays a substantial role in mediating recovery of the paralyzed hemidiaphragm following C2 spinal cord hemisection.     

The effect of three inhaled anesthetics in mice harboring mutations in the GluR6 (kainate) receptor gene

Combinations of GluR5-GluR7, KA1, and KA2 subunits form kainate receptors, a subtype of excitatory ionotropic glutamate receptors. Isoflurane enhances the action of kainate receptors comprising GluR6 subunits expressed in oocytes. To test whether alterations of the GluR6 subunit gene affect the actions of inhaled anesthetics in vivo, we measured the minimum alveolar concentration of desflurane, isoflurane, and halothane in mice lacking the kainate receptor subunit GluR6 (GluR6 knockout mice) and mice with a dominant negative glutamine/arginine (Q/R) editing mutation in membrane domain 2 of the GluR6 receptor (GluR6 editing mutants), which increases the calcium permeability of kainate receptors containing GluR6Q. We also measured the capacity of isoflurane to interfere with Pavlovian fear conditioning to a tone and to context. Absence of the GluR6 subunit did not change the minimum alveolar concentration of isoflurane, desflurane, or halothane. Possibly, kainate receptors assembled from the remaining kainate receptor subunits compensate for the absent subunits and thereby produce a normal minimum alveolar concentration. A Q/R mutation that dominantly affects kainate receptors containing the GluR6 subunit in mice increased isoflurane minimum alveolar concentration (by 12%; P < 0.01), decreased desflurane minimum alveolar concentration (by 18%; P < 0.001), and did not change halothane minimum alveolar concentration (P = 0.25). These data may indicate that kainate receptors containing GluR6Q subunits differently modulate, directly or indirectly, the mechanism by which inhaled anesthetics cause immobility. The mutations of GluR6 that were studied did not affect the capacity of isoflurane to interfere with fear conditioning.