Zonisamide regulates basal ganglia transmission via astroglial kynurenine pathway.

To clarify the anti-parkinsonian mechanisms of action of zonisamide (ZNS), we determined the effects of ZNS on tripartite synaptic transmission associated with kynurenine (KYN) pathway (KP) in cultured astrocytes, and transmission in both direct and indirect pathways of basal ganglia using microdialysis. Interactions between cytokines [interferon-γ (IFNγ) and tumor-necrosis factor-α (TNFα)] and ZNS on astroglial releases of KP metabolites, KYN, kynurenic-acid (KYNA), xanthurenic-acid (XTRA), cinnabarinic-acid (CNBA) and quinolinic-acid (QUNA), were determined by extreme liquid-chromatography with mass-spectrometry. Interaction among metabotropic glutamate-receptor (mGluR), KP metabolites and ZNS on striato-nigral, striato-pallidal GABAergic and subthalamo-nigral glutamatergic transmission was examined by microdialysis with extreme liquid-chromatography fluorescence resonance-energy transfer detection. Acute and chronic ZNS administration increased astroglial release of KYN, KYNA, XTRA and CNBA, but not QUNA. Chronic IFNγ administration increased the release of KYN, KYNA, CNBA and QUNA, but had minimal inhibitory effect on XTRA release. Chronic TNFα administration increased CNBA and QUNA, but not KYN, KYNA or XTRA. ZNS inhibited IFNγ-induced elevation of KYN, KYNA and QUNA, but enhanced IFNγ-induced that of CNBA. TNFα-induced rises in CNBA and QUNA were inhibited by ZNS. ZNS inhibited striato-nigral GABAergic, striato-pallidal GABAergic and subthalamo-nigral glutamatergic transmission via activation of groups II and III mGluRs. ZNS enhanced astroglial release of endogenous agonists of group II mGluR, XTRA and group III mGluR, CNBA. Activated endogenous mGluR agonists inhibited transmission in direct and indirect pathways of basal ganglia. These mechanisms contribute to effectiveness and well tolerability of ZNS as an adjunct treatment for Parkinson's disease during l-DOPA monotherapy. This article is part of the Special Issue entitled 'The Synaptic Basis of Neurodegenerative Disorders'.

Expression, subunit composition, and function of AMPA-type glutamate receptors are changed in activated microglia; possible contribution of GluA2 (GluR-B)-deficiency under pathological conditions.

Microglia express AMPA (α-amino-hydroxy-5-methyl-isoxazole-4-propionate)-type of glutamate (Glu) receptors (AMPAR), which are highly Ca(2+) impermeable due to the expression of GluA2. However, the functional importance of AMPAR in microglia remains to be investigated, especially under pathological conditions. As low expression of GluA2 was reported in some neurodegenerative diseases, GluA2(-/-) mice were used to show the functional change of microglial AMPARs in response to Glu or kainate (KA). Here we found that Glu-induced currents in the presence of 100 µM cyclothiazide, an inhibitor of AMPAR desensitization, showed time-dependent decrease after activation of microglia with lipopolysaccharide (LPS) in GluA2(+/+) microglia, but not in GluA2(-/-) microglia. Upon activation of microglia, expression level of GluA2 subunits significantly increased, while expression of GluA1, A3 and A4 subunits on membrane surface significantly decreased. These results suggest that nearly homomeric GluA2 subunits were the main reason for low conductance of AMPAR in activated microglia. Increased expression of GluA2 in microglia was also detected partially in brain slices from LPS-injected mice. Cultured microglia from GluA2(-/-) mice showed higher Ca(2+) -permeability, consequently inducing significant increase in the release of proinflammatory cytokine, such as TNF-α. The conditioning medium from KA-treated GluA2(-/-) microglia had more neurotoxic effect on wild type cultured neurons than that from KA-treated GluA2(+/+) microglia. These results suggest that membrane translocation of GluA2-containing AMPARs in activated microglia has functional importance and thus, dysfunction or decreased expression of GluA2 may accelerate Glu neurotoxicity via excess release of proinflammatory cytokines from microglia.

Relevance of astrocytic activation to reductions of astrocytic GABAA receptors.

Although astrocytes express gamma-aminobutyric acid subtype-A (GABAA) receptors in the mature brain, GABAA receptor expression in a cultivation state remains controversial. In this study, we investigated the alteration of astrocytic GABAA receptor expression in in vitro and in vivo studies to elucidate the relevance of astrocytic activation to reductions of astrocytic GABAA receptors. The GABA-evoked Cl- current (GABAA response) in cultured astrocytes was determined by recording in the whole-cell mode using a conventional patch-clamp technique under voltage-clamp conditions. The respective amplitudes of GABAA responses on days in vitro 1, 3-5, 7-10, and 12-15 were 1019+/-97, 512+/-76, 84+/-21, and 22+/-9 pA, respectively, suggesting that the GABAA response subsequently diminished with in vitro aging. In immunohistochemical and biochemical analyses, the expression of GABAA receptor beta-subunit decreased, whereas expressions of glial fibrillary acidic protein (GFAP) and S100B, hallmarks of astrocytic activation, increased dramatically in the cultured astrocytes with in vitro aging. With the use of [3H]SR95531, a GABAA-specific ligand, at 24 h after transient focal ischemia, binding was significantly reduced in the astrocytic fractions without affecting the synaptosomal fractions, and decreases in the mRNA expression level of GABAA receptor beta-subunits were concurrently observed. Interestingly, the loss of GABAA response in cultured astrocytes was mitigated by co-culturing with neurons or treatments with monoclonal S100B antibodies. These results indicate that astrocytic GABAA receptors are reduced with in vitro aging and cerebral ischemia, presumably through the overproduction of S100B in activated astrocytes.

[S100B: astrocyte specific protein].

The S100B is a Ca2+ binding proteins of EF-hand type and is produced primarily by astrocytes in the central nervous system. This protein has been implicated in the Ca2+-dependent regulation of a variety of intracellular functions such as protein phosphorylation, enzyme activities, cell proliferation and differentiation, dynamics of cytoskeleton constituents, structural organization of membranes, intracellular Ca2+ homeostasis, inflammation, and protection from oxidative cell damage. Recent studies suggest that released S100B exerts paracrine and autocrine effects on neurons and glia. On the other hand, elevations of S100B levels in blood or cerebrospinal fluid have been observed in patients with Alzheimer's disease, Down's syndrome, amyotrophic lateral sclerosis, multiple sclerosis, schizophrenia, depression, cerebral stroke and traumatic brain injury, and the levels have reached micromol/L-order at focal regions. It has been documented that the excessive S100B promotes the expression of inducible nitric oxide synthase or pro-inflammatory cytokines and exhibits detrimental effects on neurons. On studies using some animal models of the cerebral stroke or Alzheimer's disease, it is suggested that the excessive S100B produced by activated astrocytes precedes neurodegenerations. Authors discussed the relationship between neurological disorders and the S100B.