AMPA glutamate receptor-mediated calcium signaling is transiently enhanced during development of oligodendrocytes

Itoh, Takayuki; Beesley, Jacqueline; Itoh, Aki; Cohen, Akiva S.; Kavanaugh, Bryan; Coulter, Douglas A.; Grinspan, Judith B.; Pleasure, David E

doi:10.1046/j.1471-4159.2002.00866.x

Cited by 141 publications

(160 citation statements)

References 53 publications

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“…Expression of AMPA/kainate receptors is particularly marked in immature cells of the oligodendrocyte lineage (Itoh et al, 2002), which in the neonatal optic nerve are in the process of forming an exquisitely close morphological arrangement with neighbouring axons (Butt and Ransom, 1993). We and others have recently demonstrated the presence of functional NMDA-type glutamate receptors in oligodendrocyte processes (Salter and Fern, 2005;Káradóttir et al, 2005;Micu et al, 2006)).…”

Section: Discussionmentioning

confidence: 97%

Functional glutamate transport in rodent optic nerve axons and glia

Arranz

Hussein

Alix

et al. 2008

Glia

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Glutamate uptake and potential release via Na + -dependent glutamate transporters is crucial to CNS function and to various forms of injury. Evidence for glutamatemediated damage of oligodendroglia somata and processes in white matter suggests that glutamate regulation in white matter is of particular clinical importance. The expression of glutamate transporters was examined in developing mouse and mature mouse and rat white matter using immuno-histochemistry and immuno-electron microscopy. EAAC1 was the major glutamate transporter detected in oligodendroglia cell membranes in both neonatal and mature optic nerve while GLT1 was the most heavily expressed transporter in the membranes of astrocytes. Both EAAC1 and GLAST were also seen in adult astrocytes but there was little membrane expression of either in the neonate. GLAST, EAAC1 and GLT1 were expressed in neonatal axons with significant amount of GLT1 present in the axolemma, while in mature axons EAAC1 was abundant at the node of Ranvier. Functional glutamate transport was probed in developing mouse optic nerve revealing Na + -dependent, TBOA-blockable uptake of D-aspartate in astrocytes, axons and oligodendrocytes. The data show that in addition to oligodendroglia and astrocytes, axons represent a significant potential sink and source for extracellular glutamate in white matter.

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Section: Discussionmentioning

confidence: 97%

Functional glutamate transport in rodent optic nerve axons and glia

Arranz

Hussein

Alix

et al. 2008

Glia

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“…Here, exposure to hypoxia that induces strong elevations in the concentration of extracellular glutamate is associated with a significant increase in GluA4 immunoreactivity within immature oligodendroglia. The expression of Gria4 is regulated developmentally (Itoh et al, 2002; Hossain et al, 2014), thus the direction of excitotoxicity‐induced regulation of Gria4 in oligodendroglia may depend on maturational status. Indeed, Oli‐neu cells cultured under the conditions used in the present study exhibit low levels of immunoreactivity to anti‐O4 (Toutouna et al, 2016), suggesting that this cell line holds a more immature position in the lineage than pOPC, which typically exhibit strong anti‐04 staining.…”

Section: Discussionmentioning

confidence: 99%

“…These observations suggest that a substantial number of OPC AMPAR lack GluA2 subunits since inclusion of this subunit limits the permeability of AMPAR to Ca 2+ (Geiger et al, 1995; Hollmann, Hartley, & Heinemann, 1991). In support of this, cultured OPC express high levels of GluA3 and 4 (Hossain et al, 2014; Itoh et al, 2002) which may assemble to form Ca 2+ permeable AMPAR, and GluA4 is the predominant subunit expressed by OPC in the developing white matter of rodents and humans (Talos, Fishman, et al, 2006; Talos, Follett, et al, 2006). Importantly, the timing of GluA4 expression in these systems corresponds with an established window of vulnerability during which OPC are selectively injured by hypoxic‐ischemic conditions (Back et al, 2002; Back et al, 2001; reviewed in Fern, Matute, & Stys, 2014), and GluA4 is highly expressed in neural cells vulnerable to excitotoxic cell death (Page & Everitt, 1995).…”

Section: Introductionmentioning

confidence: 97%

“…OPC express all four subunits, although GluA1 represents a minor contributor compared with GluA2–4 in vitro (Hossain, Liu, Fragoso, & Almazan, 2014; Itoh et al, 2002), and appears to be entirely absent from OPC in vivo (Kougioumtzidou et al, 2017). Activation of OPC AMPAR provokes an influx of Ca 2+ (Ge et al, 2006; Haberlandt et al, 2011; Hamilton, Vayro, Wigley, & Butt, 2010; Itoh et al, 2002) that can mediate excitotoxic injury in vitro (Alberdi, Sanchez‐Gomez, Marino, & Matute, 2002; Deng, Rosenberg, Volpe, & Jensen, 2003; Li & Stys, 2000; Sanchez‐Gomez & Matute, 1999). These observations suggest that a substantial number of OPC AMPAR lack GluA2 subunits since inclusion of this subunit limits the permeability of AMPAR to Ca 2+ (Geiger et al, 1995; Hollmann, Hartley, & Heinemann, 1991).…”

Section: Introductionmentioning

confidence: 99%

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NF‐Y‐dependent regulation of glutamate receptor 4 expression and cell survival in cells of the oligodendrocyte lineage

Begum

Otsu

Ahmed

et al. 2018

Glia

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Glutamate receptor subunit 4 (GluA4) is highly expressed by neural cells sensitive to excitotoxicity, and is the predominant subunit expressed by oligodendrocyte precursor cells (OPC) during a key period of vulnerability to hypoxic‐ischemic injury. Therefore, transcriptional networks downstream of excitotoxic GluA4 activation represent a promising area for therapeutic intervention. In this work, we identify the CCAAT binding transcription factor NF‐Yb as a novel transcriptional regulator of Gria4 (GluA4 gene), and a controller of excitotoxic death in the oligodendroglial lineage. We describe a novel regulatory region within Gria4 containing CCAAT sequences whose binding by NF‐Yb is regulated by excitotoxicity. Excitotoxicity‐induced alterations in NF‐Yb binding are associated with changes in Gria4 transcription, while knockdown of NF‐Yb alters the transcription of reporter constructs containing this regulatory region. Data from immortalized and primary OPC reveal that RNAi and pharmacological disruption of NF‐Yb alter Gria4 transcription, with the latter inducing apoptosis and influencing a set of apoptotic genes similarly regulated during excitotoxicity. These data provide the first definition of a trans‐acting mechanism regulating Gria4, and identify the NF‐Y network as a potential source of pharmacological targets for promoting OPC survival.

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“…Glutamate is produced by the developing oligodendrocytes and axons (Rossi, Oshima et al 2000;Desilva, Kinney et al 2007) and is highly toxic in vitro (Choi 1992). Moreover, it renders even more vulnerable the premyelinating oligodendrocytes, though not the mature cells (Itoh, Beesley et al 2002).…”

Section: Glutamate-induced Brain Injurymentioning

confidence: 99%