Immunohistochemical detection by immersion fixation with Carnoy solution of particular non-N-methyl-D-aspartate receptor subunits in murine hippocampus

Repeated exposure to microcystin-leucine-arginine potentiates excitotoxicity induced by a low dose of kainate

Microcystin-leucine-arginine (MLCR) is a cyanobacterial toxin, and has been demonstrated to cause neurotoxicity. In addition, MCLR has been identified as an inhibitor of protein phosphatase (PP)1 and PP2A, which are known to regulate the phosphorylation of various molecules related to synaptic excitability. Thus, in the present study, we examined whether MCLR exposure affects seizures induced by a low dose of kainic acid (KA; 0.05 μg, i.c.v.) administration. KA-induced seizure occurrence and seizure score significantly increased after repeated exposure to MCLR (2.5 or 5.0 μg/kg, i.p., once a day for 10 days), but not after acute MCLR exposure (2.5 or 5.0 μg/kg, i.p., 2 h and 30 min prior to KA administration), and hippocampal neuronal loss was consistently facilitated by repeated exposure to MCLR. In addition, repeated MCLR significantly elevated the membrane expression of kainate receptor GluK2 subunits, p-pan-protein kinase C (PKC), and p-extracellular signal-related kinase (ERK) at 1 h after KA. However, KA-induced membrane expression of Ca²⁺/calmodulin-dependent kinase II (CaMKII) was significantly reduced by repeated MCLR exposure. Consistent with the enhanced seizures and neurodegeneration, MCLR exposure significantly potentiated KA-induced oxidative stress and microglial activation, which was accompanied by increased expression of p-ERK and p-PKCδ in the hippocampus. The combined results suggest that repeated MCLR exposure potentiates KA-induced excitotoxicity in the hippocampus by increasing membrane GluK2 expression and enhancing oxidative stress and neuroinflammation through the modulation of p-CaMKII, p-PKC, and p-ERK.

Shisa6 traps AMPA receptors at postsynaptic sites and prevents their desensitization during synaptic activity

Trafficking and biophysical properties of AMPA receptors (AMPARs) in the brain depend on interactions with associated proteins. We identify Shisa6, a single transmembrane protein, as a stable and directly interacting bona fide AMPAR auxiliary subunit. Shisa6 is enriched at hippocampal postsynaptic membranes and co-localizes with AMPARs. The Shisa6 C-terminus harbours a PDZ domain ligand that binds to PSD-95, constraining mobility of AMPARs in the plasma membrane and confining them to postsynaptic densities. Shisa6 expressed in HEK293 cells alters GluA1- and GluA2-mediated currents by prolonging decay times and decreasing the extent of AMPAR desensitization, while slowing the rate of recovery from desensitization. Using gene deletion, we show that Shisa6 increases rise and decay times of hippocampal CA1 miniature excitatory postsynaptic currents (mEPSCs). Shisa6-containing AMPARs show prominent sustained currents, indicating protection from full desensitization. Accordingly, Shisa6 prevents synaptically trapped AMPARs from depression at high-frequency synaptic transmission.

Auxiliary AMPA receptor subunits can affect gating and surface mobility. Here the authors show that Shisa6 traps AMPA receptors at postsynaptic sites via PSD-95, and keeps them in an activated state in the presence of glutamate, preventing full desensitization and consequently synaptic depression.

A-kinase anchoring protein 150 in the mouse brain is concentrated in areas involved in learning and memory

A-kinase anchoring proteins (AKAPs) form large macromolecular signaling complexes that specifically target cAMP-dependent protein kinase (PKA) to unique subcellular compartments and thus, provide high specificity to PKA signaling. For example, the AKAP79/150 family tethers PKA, PKC and PP2B to neuronal membranes and postsynaptic densities and plays an important role in synaptic function. Several studies suggested that AKAP79/150 anchored PKA contributes to mechanisms associated with synaptic plasticity and memory processes, but the precise role of AKAPs in these processes is still unknown. In this study we established the mouse brain distribution of AKAP150 using two well-characterized AKAP150 antibodies. Using Western blotting and immunohistochemistry we showed that AKAP150 is widely distributed throughout the mouse brain. The highest AKAP150 expression levels were observed in striatum, cerebral cortex and several other forebrain regions (e.g. olfactory tubercle), relatively high expression was found in hippocampus and olfactory bulb and low/no expression in cerebellum, hypothalamus, thalamus and brain stem. Although there were some minor differences in mouse AKAP150 brain distribution compared to the distribution in rat brain, our data suggested that rodents have a characteristic AKAP150 brain distribution pattern. In general we observed that AKAP150 is strongly expressed in mouse brain regions involved in learning and memory. These data support its suggested role in synaptic plasticity and memory processes.

Activation of GABA(A) receptors facilitates astroglial differentiation induced by ciliary neurotrophic factor in neural progenitors isolated from fetal rat brain

Immunocytochemical analysis confirmed the validity of isolation procedures of neural progenitors capable of self-replication and differentiation from discrete fetal rat brain structures. A reverse transcription-polymerase chain reaction analysis revealed the expression of particular GABA(A) receptor (GABA(A)R), GABA(B)R-1 and GABA(C)R, but not GABA(B)R-2, subunits in neocortical cells before commitment. Sustained exposure to the GABA(A)R agonist muscimol at 100 mumol/L led to significant increases in the mitochondrial activity and the total areas of neocortical neurospheres formed during the cultivation for 12 days in a manner sensitive to a GABA(A)R antagonist, with lactate dehydrogenase release being unchanged. Moreover, prior sustained exposure to muscimol significantly facilitated the subsequent expression of an astroglial marker protein in cells differentiated by ciliary neurotrophic factor (CNTF) toward an astroglial lineage, with a concomitant decrease in the neuronal marker protein expression, in an antagonist-sensitive manner on Western blotting analysis. However, muscimol failed to significantly affect the expression of both marker proteins in cells differentiated in either the presence or absence of all-trans-retinoic acid. These results suggest that prior activation of GABA(A)R may preferentially facilitate the commitment by CNTF of neural progenitor cells toward an astroglial lineage after simulation of the self-replication activity in the developing rat brain.

Distinct subunits in heteromeric kainate receptors mediate ionotropic and metabotropic function at hippocampal mossy fiber synapses

Heteromeric kainate receptors (KARs) containing both glutamate receptor 6 (GluR6) and KA2 subunits are involved in KAR-mediated EPSCs at mossy fiber synapses in CA3 pyramidal cells. We report that endogenous glutamate, by activating KARs, reversibly inhibits the slow Ca2+-activated K+ current I(sAHP) and increases neuronal excitability through a G-protein-coupled mechanism. Using KAR knockout mice, we show that KA2 is essential for the inhibition of I(sAHP) in CA3 pyramidal cells by low nanomolar concentrations of kainate, in addition to GluR6. In GluR6(-/-) mice, both ionotropic synaptic transmission and inhibition of I(sAHP) by endogenous glutamate released from mossy fibers was lost. In contrast, inhibition of I(sAHP) was absent in KA2(-/-) mice despite the preservation of KAR-mediated EPSCs. These data indicate that the metabotropic action of KARs did not rely on the activation of a KAR-mediated inward current. Biochemical analysis of knock-out mice revealed that KA2 was required for the interaction of KARs with Galpha(q/11)-proteins known to be involved in I(sAHP) modulation. Finally, the ionotropic and metabotropic actions of KARs at mossy fiber synapses were differentially sensitive to the competitive glutamate receptor ligands kainate (5 nM) and kynurenate (1 mM). We propose a model in which KARs could operate in two modes at mossy fiber synapses: through a direct ionotropic action of GluR6, and through an indirect G-protein-coupled mechanism requiring the binding of glutamate to KA2.

The Fixation of Living Skin Equivalents

Histologic evaluations and immunohistochemical characterizations are important in studies of artificial organs such as skin equivalents. However, tissue compact organization is not easy to obtain when the artificial organ is constructed in vitro. Thus, appropriate fixation methods must be selected according to the compactness of the artificial organ and tissue engineering methodologies. The effects of several fixatives-Carnoy, Bouin's solution, formalin, paraformaldehyde, and paraformaldehyde-glutaraldehyde-were examined to select the best fixation method for preserving the structural and molecular markers of skin equivalents. Formalin-based fixatives ware found to be relatively free of the histologic problems (e.g., tissue shrinkage, poor structural preservation, weak stainability, and nonspecific immunolocalization) presented by the soft tissue fixatives (i.e., Carnoy or Bouin's solution). Unfortunately, the standard concentration of formalin induced detachment of epidermis from dermis, but this was prevented by reducing the concentration of the fixative. These findings suggest that fixation procedures should be selected for particular tissue and specific goals; in particular, they show that the paraformaldehyde-glutaraldehyde combination performed best in terms of preserving the histologic features of skin equivalents.

Testosterone's anti-anxiety and analgesic effects may be due in part to actions of its 5alpha-reduced metabolites in the hippocampus

Although testosterone (T) may have effects to enhance analgesia and reduce anxiety, its effects and mechanisms are not well understood. We hypothesized that if T's anti-anxiety and analgesic effects are due in part to actions of its 5alpha-reduced metabolite (dihydrotestosterone-DHT) and/or its 3alpha-hydroxysteroid dehydrogenase reduced metabolite (3alpha-androstanediol-3alpha-diol), in the hippocampus, then androgen regimens that increase levels of these metabolites in the hippocampus should produce anti-anxiety behavior, and analgesic effects, in gonadectomized (GDX) male rats. In Experiment 1, GDX rats were administered T, DHT, 3alpha-diol (1 mg/kg, SC), or vehicle. In Experiment 2, GDX rats had T, DHT, 3alpha-diol-containing inserts, or empty control inserts applied to the dorsal hippocampus immediately prior to behavioral testing. Androgen-administered rats (SC or intrahippocampal) showed significantly more exploratory behavior in the open field and elevated plus maze, less freezing in response to shock, and longer tailflick and pawlick latencies. These findings suggest that T's anti-anxiety effects may be due in part to actions of its 5alpha-reduced metabolites in the dorsal hippocampus.

Testosterone's Analgesic, Anxiolytic, and Cognitive-Enhancing Effects May Be Due in Part to Actions of Its 5α-Reduced Metabolites in the Hippocampus

Although testosterone (T) may decrease anxiety and enhance cognitive performance, its mechanisms are not well understood. The authors hypothesized that if T's effects are mediated in part through actions of its 5alpha-reduced, nonaromatizable metabolite dihydrotestosterone (DHT) and/or its 3alpha-hydroxysteroid dehydrogenase reduced metabolite 3alpha-androstanediol (3alpha-diol) in the hippocampus, then T, DHT, and 3alpha-diol administration should produce similar behavioral effects concomitant with elevating T metabolites in the hippocampus. Gonadectomized male rats administered T, DHT, or 3alpha-diol via Silastic capsules or intrahippocampal infusions had greater analgesia (tail flick, paw lick), less anxiety behavior (plus-maze, open field, defensive freezing), and better learning (inhibitory avoidance) compared with vehicle control rats. Only 3alpha-diol levels in the hippocampus were consistently elevated in conjunction with these behavioral effects.