Mechanisms of GABA release from human astrocytes

Lee, Moon-Hee; McGeer, Edith G.; McGeer, Patrick L.

doi:10.1002/glia.21202

Cited by 101 publications

(73 citation statements)

References 35 publications

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“…Various transmitters, such as L-glutamate, D-serine, GABA and kynurenic acid, are released from astrocytes (Hamilton and Attwell, 2010;Parpura and Zorec, 2010;Potter et al, 2010;Lee et al, 2011). Our previous study demonstrated that basal and 100 mM AMPA-evoked releases of L-glutamate and D-serine from astrocytes were inhibited by the glial toxin, FLC and the synaptobrevin inhibitor, TeNT, but such release was insensitive to the voltage-gated sodium channel inhibitor, TTX (Tanahashi et al, 2012), similar to the present results.…”

Section: Mechanisms Of Gliotransmitter Release In Cultured Astrocytessupporting

confidence: 90%

ONO‐2506 inhibits spike–wave discharges in a genetic animal model without affecting traditional convulsive tests via gliotransmission regulation

Yamamura

Hoshikawa

Kato

et al. 2013

British J Pharmacology

102

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BACKGROUND AND PURPOSEAnticonvulsants have been developed according to the traditional neurotransmission imbalance hypothesis. However, the anticonvulsive pharmacotherapy currently available remains unsatisfactory. To develop new antiepileptic drugs with novel antiepileptic mechanisms, we have tested the antiepileptic actions of ONO-2506, a glial modulating agent, and its effects on tripartite synaptic transmission. EXPERIMENTAL APPROACHDose-dependent effects of ONO-2506 on maximal-electroshock seizure (MES), pentylenetetrazol-induced seizure (PTZ) and epileptic discharge were determined in a genetic model of absence epilepsy in mice (Cacna1a tm2Nobs/tm2Nobs strain). Antiepileptic mechanisms of ONO-2506 were analysed by examining the interaction between ONO-2506 and transmission-modulating toxins (tetanus toxin, fluorocitrate, tetrodotoxin) on release of L-glutamate, D-serine, GABA and kynurenic acid in the medial-prefrontal cortex (mPFC) of freely moving rats using microdialysis and primary cultured rat astrocytes. KEY RESULTS ONO-2506 inhibited spontaneous epileptic discharges in Cacna1atm2Nobs/tm2Nobs mice without affecting MES or PTZ. Given systemically, ONO-2506 increased basal release of GABA and kynurenic acid in the mPFC through activation of both neuronal and glial exocytosis, but inhibited depolarization-induced releases of all transmitters. ONO-2506 increased basal glial release of kynurenic acid without affecting those of L-glutamate, D-serine or GABA. However, ONO-2506 inhibited AMPA-induced releases of L-glutamate, D-serine, GABA and kynurenic acid. CONCLUSIONS AND IMPLICATIONSONO-2506 did not affect traditional convulsive tests but markedly inhibited epileptic phenomena in the genetic epilepsy mouse model. ONO-2506 enhanced release of inhibitory neuro-and gliotransmitters during the resting stage and inhibited tripartite transmission during the hyperactive stage. The results suggest that ONO-2506 is a novel potential glial-targeting antiepileptic drug. LINKED ARTICLEThis article is commented on by Onat, pp. 1086-1087 of this issue. To view this commentary visit http://dx

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Section: Mechanisms Of Gliotransmitter Release In Cultured Astrocytessupporting

confidence: 90%

ONO‐2506 inhibits spike–wave discharges in a genetic animal model without affecting traditional convulsive tests via gliotransmission regulation

Yamamura

Hoshikawa

Kato

et al. 2013

British J Pharmacology

102

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“…Because of the abundant expression of GABA receptors and GABA in the brain microenvironment (27), we investigated whether BBM cells had any GABAergic properties by comparing the expression of their genes and proteins to the highly passaged primary breast cancer cell lines, SkBr3 and MDA-MB-231. All GABA receptor mRNA isoforms were highly up-regulated in HER2…”

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confidence: 99%

Human breast cancer metastases to the brain display GABAergic properties in the neural niche

Neman¹,

Termini²,

Wilczynski³

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

259

218

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Dispersion of tumors throughout the body is a neoplastic process responsible for the vast majority of deaths from cancer. Despite disseminating to distant organs as malignant scouts, most tumor cells fail to remain viable after their arrival. The physiologic microenvironment of the brain must become a tumor-favorable microenvironment for successful metastatic colonization by circulating breast cancer cells. Bidirectional interplay of breast cancer cells and native brain cells in metastasis is poorly understood and rarely studied. We had the rare opportunity to investigate uncommonly available specimens of matched fresh breast-to-brain metastases tissue and derived cells from patients undergoing neurosurgical resection. We hypothesized that, to metastasize, breast cancers may escape their normative genetic constraints by accommodating and coinhabiting the neural niche. This acquisition or expression of brainlike properties by breast cancer cells could be a malignant adaptation required for brain colonization. Indeed, we found breast-to-brain metastatic tissue and cells displayed a GABAergic phenotype similar to that of neuronal cells. The GABA A receptor, GABA transporter, GABA transaminase, parvalbumin, and reelin were all highly expressed in breast cancer metastases to the brain. Proliferative advantage was conferred by the ability of breast-to-brain metastases to take up and catabolize GABA into succinate with the resultant formation of NADH as a biosynthetic source through the GABA shunt. The results suggest that breast cancers exhibit neural characteristics when occupying the brain microenvironment and co-opt GABA as an oncometabolite.brain metastasis | tumor microenvironment M etastases are responsible for 90% of all cancer deaths, and patients diagnosed with brain metastases have a dismal 20% probability of 1-y survival (1-3). The brain is increasingly the first site of recurrence after treatment of stage IV advanced breast cancer, even when disease in other sites is in remission. This emerging clinical problem significantly limits the survival gains made from recent advances in systemic therapy for breast cancer (4). Breast cancer metastasizes to the brain in ∼40% of patients who have a tumor that is HER2 + (>30% of tumor cells have complete membrane staining for the tyrosine kinase receptor erbB2) or triple negative (TN) (negative for the estrogen and progesterone receptors and have reduced expression of HER2 + ) (5). Ninety percent of patients with these breast cancer subtypes will die of metastasis to the brain (1). Currently, treatment options beyond radiotherapy and neurological surgery are limited, underscoring the need for research into the biology of these clinically recalcitrant tumors (6).Breast cancer patients typically develop brain metastases months to several years after their initial diagnosis (6). This unique clinical latency occurs despite the early presence of circulating tumor cells, often detectable at the time of primary diagnosis (7-9). These observations suggest that the final step ...

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“…The GABA transporter GAT-3 is exclusively expressed in astrocytes (Minelli et al 1996); GAT-1 and -2 are found in astrocytic processes and other neuronal-and nonneuronal elements (Conti et al 1998(Conti et al , 1999. As a result of the concerted action of these enzymes and transporters, cultured human astrocytes maintain an intracellular GABA level of 2.32 mM (Lee et al 2011b). On the same line, cultured human microglia express the mRNA and protein for GABA-T, in Fig.…”

Section: Discussionmentioning

confidence: 99%

Localization of SUCLA2 and SUCLG2 subunits of succinyl CoA ligase within the cerebral cortex suggests the absence of matrix substrate-level phosphorylation in glial cells of the human brain

Dobolyi

Bagó

Gál

et al. 2014

J Bioenerg Biomembr

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We have recently shown that the ATP-forming SUCLA2 subunit of succinyl-CoA ligase, an enzyme of the citric acid cycle, is exclusively expressed in neurons of the human cerebral cortex; GFAP-and S100-positive astroglial cells did not exhibit immunohistoreactivity or in situ hybridization reactivity for either SUCLA2 or the GTP-forming SUCLG2. However, Western blotting of post mortem samples revealed a minor SUCLG2 immunoreactivity. In the present work we sought to identify the cell type(s) harboring SUCLG2 in paraformaldehyde-fixed, free-floating surgical human cortical tissue samples. Specificity of SUCLG2 antiserum was supported by co-localization with mitotracker orange staining of paraformaldehyde-fixed human fibroblast cultures, delineating the mitochondrial network. In human cortical tissue samples, microglia and oligodendroglia were identified by antibodies directed against Iba1 and myelin basic protein, respectively. Double immunofluorescence for SUCLG2 and Iba1 or myelin basic protein exhibited no costaining; instead, SUCLG2 appeared to outline the cerebral microvasculature. In accordance to our previous work there was no co-localization of SUCLA2 immunoreactivity with either Iba1 or myelin basic protein. We conclude that SUCLG2 exist only in cells forming the vasculature or its contents in the human brain. The absence of SUCLA2 and SUCLG2 in human glia is in compliance with the presence of alternative pathways occurring in these cells, namely the GABA shunt and ketone body metabolism which do not require succinyl CoA ligase activity, and glutamate dehydrogenase 1, an enzyme exhibiting exquisite sensitivity to inhibition by GTP.

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Mechanisms of GABA release from human astrocytes

Cited by 101 publications

References 35 publications

ONO‐2506 inhibits spike–wave discharges in a genetic animal model without affecting traditional convulsive tests via gliotransmission regulation

ONO‐2506 inhibits spike–wave discharges in a genetic animal model without affecting traditional convulsive tests via gliotransmission regulation

Human breast cancer metastases to the brain display GABAergic properties in the neural niche

Localization of SUCLA2 and SUCLG2 subunits of succinyl CoA ligase within the cerebral cortex suggests the absence of matrix substrate-level phosphorylation in glial cells of the human brain

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