Development of a glial network in the olfactory nerve: role of calcium and neuronal activity

Koussa, Mounir A.; Tolbert, Leslie P.; Oland, Lynne A.

doi:10.1017/s1740925x11000081

Cited by 5 publications

(4 citation statements)

References 92 publications

(87 reference statements)

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“…A significant role for P2Y 1 in the development of radial glial cells and neurons could be shown in the subventricular zone, where proliferation of glial cells and migration of neuronal progenitors depends on ATPmediated calcium signals (Weissman et al, 2004;Liu et al, 2008). In addition, neuronal activity evokes calcium signaling in glial cells in the insect olfactory nerve and the olfactory lobe (homologous to the vertebrate olfactory bulb) (Hartl et al, 2007;Heil et al, 2007), and this calcium signaling is required for glial cell migration in these structures (Lohr et al, 2005;Koussa et al, 2011). A similar function of mGluR 1 and P2Y 1 receptor-mediated calcium signaling for migration of OECs from the olfactory placode to the telencephalon, a key step in early development of the olfactory system in mammals (Ekberg et al, 2012), could be speculated, but needs further investigation.…”

Section: Oecs In Olfactory Bulb Development: a Role For Calcium Signamentioning

confidence: 99%

Spatial and developmental heterogeneity of calcium signaling in olfactory ensheathing cells

Thyssen

Stavermann

Buddrus

et al. 2012

Glia

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Olfactory ensheathing cells (OECs) are specialized glial cells in the mammalian olfactory system supporting growth of axons from the olfactory epithelium into the olfactory bulb. OECs in the olfactory bulb can be subdivided into OECs of the outer nerve layer and the inner nerve layer according to the expression of marker proteins and their location in the nerve layer. In the present study, we have used confocal calcium imaging of OECs in acute mouse brain slices and olfactory bulbs in toto to investigate physiological differences between OEC subpopulations. OECs in the outer nerve layer, but not the inner nerve layer, responded to glutamate, ATP, serotonin, dopamine, carbachol, and phenylephrine with increases in the cytosolic calcium concentration. The calcium responses consisted of a transient and a tonic component, the latter being mediated by store-operated calcium entry. Calcium measurements in OECs during the first three postnatal weeks revealed a downregulation of mGluR(1) and P2Y(1) receptor-mediated calcium signaling within the first 2 weeks, suggesting that the expression of these receptors is developmentally controlled. In addition, electrical stimulation of sensory axons evoked calcium signaling via mGluR(1) and P2Y(1) only in outer nerve layer OECs. Downregulation of the receptor-mediated calcium responses in postnatal animals is reflected by a decrease in amplitude of stimulation-evoked calcium transients in OECs from postnatal days 3 to 21. In summary, the results presented reveal striking differences in receptor responses during development and in axon-OEC communication between the two subpopulations of OECs in the olfactory bulb.

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Section: Oecs In Olfactory Bulb Development: a Role For Calcium Signamentioning

confidence: 99%

Spatial and developmental heterogeneity of calcium signaling in olfactory ensheathing cells

Thyssen

Stavermann

Buddrus

et al. 2012

Glia

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“…No dye coupling to other neighboring cells occurred in the presence of nheptanol. Arrow indicates ventral according to the neuraxis, and the scale bar represents 65 μm throughout Swales and Lane 1985;Carlson and Saint Marie 1990;Carlson et al 2000;Pereanu et al 2005;Banerjee and Bhat 2007), in phagocytic functions (Doherty et al 2009), and in modulating synaptic transmission, for example, via K + and Ca 2+ signaling (Schmidt and Deitmar 1996;Edwards and Meinertzhagen 2010;Koussa et al 2010). Glial/neuronal interactions are also an integral component of insect nervous system development.…”

Section: Discussionmentioning

confidence: 99%

“…Migration of glia in the central and peripheral nervous system of insects has been shown to depend on both neuron/glia and glia/glia interactions (Rangarajaran et al 1999;Silies et al 2007;Klämbt 2009;Silies and Klämbt 2011). Among the factors playing a role in such glial interactions in the nervous systems of both insects (Koussa et al 2010) and vertebrates (Parys et al 2010) is Ca 2+ signaling via gap junctions, and one indicator of gap junctional communication is the presence of dye coupling as revealed by fluorescent dyes (Hossain et al 1995;Ball et al 2007;Lanosa et al 2008;Koussa et al 2010).…”

Section: Dye Coupling and Gap Junctionsmentioning

confidence: 99%

A cellular network of dye-coupled glia associated with the embryonic central complex in the grasshopper Schistocerca gregaria

2012

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The central complex of the grasshopper (Schistocerca gregaria) brain comprises a modular set of neuropils, which develops after mid-embryogenesis and is functional on hatching. Early in embryogenesis, Repo-positive glia cells are found intermingled among the commissures of the midbrain, but then redistribute as central complex modules become established and, by the end of embryogenesis, envelop all midbrain neuropils. The predominant glia associated with the central body during embryogenesis are glutamine synthetase-/Repo-positive astrocyte-like glia, which direct extensive processes (gliopodia) into and around midbrain neuropils. We used intracellular dye injection in brain slices to ascertain whether such glia are dye-coupled into a communicating cellular network during embryogenesis. Intracellular staining of individual cells located at any one of four sites around the central body revealed a population of dye-coupled cells whose number and spatial distribution were stereotypic for each site and comparable at both 70 and 100% of embryogenesis. Subsequent immunolabeling confirmed these dye-coupled cells to be astrocyte-like glia. The addition of n-heptanol to the bathing saline prevented all dye coupling, consistent with gap junctions linking the glia surrounding the central body. Since dye coupling also occurred in the absence of direct intersomal contacts, it might additionally involve the extensive array of gliopodia, which develop after glia are arrayed around the central body. Collating the data from all injection sites suggests that the developing central body is surrounded by a network of dye-coupled glia, which we speculate may function as a positioning system for the developing neuropils of the central complex.

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“…Tumor glial cells move through the nerve tissue, leading to formation of glioma, the most aggressive form of cancer in the nervous system (Cayre et al, 2009). In addition, glia of the peripheral nervous system (PNS), such as vertebrate perineurium and Schwann cells (Klämbt, 2009), as well as embryonic and pupal Drosophila and Manduca glia, move as collectives to reach their final destination (Cafferty and Auld, 2007;Klämbt, 2009;Koussa et al, 2010;Silies and Klambt, 2010a;von Hilchen et al, 2008;von Hilchen et al, 2013). This makes glia a valuable tool to analyze the role of cadherins in cell migration in the nervous system.…”

Section: N-cadherin and Glial Migrationmentioning

confidence: 99%

N-cadherin negatively regulates collective Drosophila glial migration via actin cytoskeleton remodeling

Kumar

Gupta

Berzsenyi

et al. 2015

Journal of Cell Science

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Cell migration is an essential and highly regulated process. During development, glia cells and neurons migrate over long distancesin most cases collectively -to reach their final destination and build the sophisticated architecture of the nervous system, the most complex tissue of the body. Collective migration is highly stereotyped and efficient, defects in the process leading to severe human diseases that include mental retardation. This dynamic process entails extensive cell communication and coordination, hence, the real challenge is to analyze it in the entire organism and at cellular resolution. We here investigate the impact of the Ncadherin adhesion molecule on collective glial migration, by using the Drosophila developing wing and cell-type specific manipulation of gene expression. We show that N-cadherin timely accumulates in glial cells and that its levels affect migration efficiency. N-cadherin works as a molecular brake in a dosage-dependent manner, by negatively controlling actin nucleation and cytoskeleton remodeling through a/b catenins. This is the first in vivo evidence for N-cadherin negatively and cell autonomously controlling collective migration.

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Development of a glial network in the olfactory nerve: role of calcium and neuronal activity

Cited by 5 publications

References 92 publications

Spatial and developmental heterogeneity of calcium signaling in olfactory ensheathing cells

Spatial and developmental heterogeneity of calcium signaling in olfactory ensheathing cells

A cellular network of dye-coupled glia associated with the embryonic central complex in the grasshopper Schistocerca gregaria

N-cadherin negatively regulates collective Drosophila glial migration via actin cytoskeleton remodeling

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