1,721,049 research outputs found
Tweaking neural organoids to model human reactive astrocytes
No full textThe study of human reactive astrocytes has been limited by resource availability. In this issue, Cvetkovic et al. (2022. J. Cell Biol.https://doi.org/10.1083/jcb.202107135) develop multicellular organoid systems containing mature astrocytes to study the dynamics of human astrocytes reactivity and its downstream effects on neuronal activity
The active role of astrocytes in synaptic transmission
No full textIn the central nervous system, astrocytes form an intimately connected network with neurons, and their processes closely enwrap synapses. The critical role of these cells in metabolic and trophic support to neurons, ion buffering and clearance of neurotransmitters is well established. However, recent accumulating evidence suggests that astrocytes are active partners of neurons in additional and more complex functions. In particular, astrocytes express a repertoire of neurotransmitter receptors mirroring that of neighbouring synapses. Such receptors are stimulated during synaptic activity and start calcium signalling into the astrocyte network. Intracellular oscillations and intercellular calcium waves represent the astrocyte's own form of excitability, as they trigger release of transmitter (i.e. glutamate) via a novel process sensitive to blockers of exocytosis and involving cyclooxygenase eicosanoids. Astrocyte-released glutamate activates receptors on the surrounding neurons and modifies their electrical and intracellular calcium ([Ca2+]i) state. These exciting new findings reveal an active participation of astrocytes in synaptic transmission and the involvement of neuronastrocyte circuits in the processing of information in the brain
CXCR4-mediated glutamate exocytosis from astrocytes
No full textThe role of astrocytes as structural and metabolic support for neurons is known since the beginning of the last century. Because of their strategic localization between neurons and capillaries they can monitor and control the level of synaptic activity by providing energetic metabolites to neurons and remove excess of neurotransmitters. During the last two decades number of papers further established that the astrocytic plasma-membrane G-protein coupled receptors (GPCR) can sense external inputs (such as the spillover of neurotransmitters) and transduce them as intracellular calcium elevations and release of chemical transmitters such as glutamate. The chemokine CXCR4 receptor is a GPCR widely expressed on glial cells (especially astrocytes and microglia). Activation of the astrocytic CXCR4 by its natural ligand CXCL12 (or SDF1 alpha) results in a long chain of intracellular and extracellular events (including the release of the pro-inflammatory cytokine TNF alpha and prostanglandins) leading to glutamate release. The emerging role of CXCR4-CXCL12 signalling axis in brain physiology came from the recent observation that glutamate in astrocytes is released via a regulated exocytosis process and occurs with a relatively fast time-scale, in the order of few hundred milliseconds. Taking into account that astrocytes are electrically non-excitable and thus exocytosis rely only on a signalling pathway that involves the release Ca2+ from the internal stores, these results suggested a close relationship between sites of Ca2+ release and those of fusion events. Indeed, a recent observation describes structural sub-membrane microdomains where fast ER-dependent calcium elevations occur in spatial and temporal correlation with fusion events. (C) 2010 Elsevier B.V. All rights reserved
SDF 1-alpha (CXCL12) triggers glutamate exocytosis from astrocytes on a millisecond time scale: imaging analysis at the single-vesicle level with TIRF microscopy
No full textChemokines are small chemotactic molecules widely expressed throughout the central nervous system. A number of papers, during the past few years, have suggested that they have physiological functions in addition to their roles in neuroinflammatory diseases. In this context, the best evidence concerns the CXC-chemokine stromal cell-derived factor (SDF-1alpha or CXCL12) and its receptor CXCR4, whose signalling cascade is also implicated in the glutamate release process from astrocytes. Recently, astrocytic synaptic like microvesicles (SLMVs) that express vesicular glutamate transporters (VGLUTs) and are able to release glutamate by Ca2+-dependent regulated exocytosis, have been described both in tissue and in cultured astrocytes. Here, in order to elucidate whether SDF-1alpha/CXCR4 system can participate to the brain fast communication systems, we investigated whether the activation of CXCR4 receptor triggers glutamate exocytosis in astrocytes. By using total internal reflection (TIRF) microscopy and the membrane-fluorescent styryl dye FM4-64, we adapted an imaging methodology recently developed to measure exocytosis and recycling in synaptic terminals, and monitored the CXCR4-mediated exocytosis of SLMVs in astrocytes. We analyzed the co-localization of VGLUT with the FM dye at single-vesicle level, and observed the kinetics of the FM dye release during single fusion events. We found that the activation of CXCR4 receptors triggered a burst of exocytosis on a millisecond time scale that involved the release of Ca2+ from internal stores. These results support the idea that astrocytes can respond to external stimuli and communicate with the neighboring cells via fast release of glutamate
Spatio-temporal overview of neuroinflammation in an experimental mouse stroke model
Full text linkAfter ischemic stroke, in the lesion core as well as in the ischemic penumbra, evolution of tissue damage and repair is strongly affected by neuroinflammatory events that involve activation of local specialized glial cells, release of inflammatory mediators, recruiting of systemic cells and vascular remodelling. To take advantage of this intricate response in the quest to devise new protective therapeutic strategies we need a better understanding of the territorial and temporal interplay between stroke-triggered inflammatory and cell death-inducing processes in both parenchymal and vascular brain cells. Our goal is to describe structural rearrangements and functional modifications occurring in glial and vascular cells early after an acute ischemic stroke. Low and high scale mapping of the glial activation on brain sections of mice subjected to 30 minutes middle cerebral artery occlusion (MCAO) was correlated with that of the neuronal cell death, with markers for microvascular changes and with markers for pro-inflammatory (IL-1β) and reparative (TGFβ1) cytokines. Our results illustrate a time-course of the neuroinflammatory response starting at early time-points (1 h) and up to one week after MCAO injury in mice, with an accurate spatial distribution of the observed phenomena
Synaptic Transmission with the Glia
No full textGlia are the most numerous cells in the central nervous system, with well-established roles in providing structural,
metabolic, and trophic support to neurons. However, the classic view that glial cells are subservient to neurons has been
challenged by recent findings indicating that perisynaptic glial cells (such as astrocytes and oligodendrocytes in the central
nervous system and Schwann cells in the peripheral nervous system) can be recruited for neurotransmission and exert a
modulatory action on synaptic function. This new vision of “tripartite synapses,” composed of perisynaptic glia in addition to
pre- and postsynaptic terminals (1, 5), certainly makes this one of the most exciting discoveries in current neurobiology. This
review will focus mainly on the rapid reciprocal communication between neurons and glia involving glutamate as the signaling molecule. However, this form of communication does not appear to be restricted to glutamatergic districts and may imply the release of transmitters other than glutamate from
either the neurons or the glia (11)
Regulated exocytosis from astrocytes physiological and pathological related aspects
No full textAstrocytes have traditionally been considered ancillary, satellite cells of the nervous system. However, it is a very recent acquisition that glial cells generate signaling loops which are integral to the brain circuitry and participate, interactively with neuronal networks, in the processing of information. Such a conceptual breakthrough makes this field of investigation one of the hottest in neuroscience, as it calls for a revision of past theories of brain function as well as for new strategies of experimental exploration of brain function. Glial cells are electrically not excitable, and it was only the use of optical recording techniques together with calcium sensitive dyes, that allowed the chemical excitability of glial cells to become apparent. Studies using these new techniques have shown for the first time that glial cells are activated by surrounding synaptic activity and translate neuronal signals into their own calcium code. Intracellular calcium concentration([Ca2+]i) elevations in glial cells have then shown to underlie spatial transfer of information in the glial network, accompanied by release of chemical transmitters (gliotransmitters) such as glutamate and back‐signaling to neurons. As a consequence, optical imaging techniques applied to cell cultures or intact tissue have become a state‐of‐the‐art technology for studying glial cell signaling. The molecular mechanisms leading to release of “gliotransmitters,” especially glutamate, from glia are under debate. Accumulating evidence clearly indicates that astrocytes secrete numerous transmitters by Ca2+‐dependent exocytosis. This review will discuss the mechanisms underlying the release of chemical transmitters from astrocytes with a particular emphasis to the regulated exocytosis processes
"Astrocytes and microglia and their potential link with autism spectrum disorders"
Full text linkThe cellular mechanism(s) underlying autism spectrum disorders (ASDs) are not fully understood although it has been shown that various genetic and environmental factors contribute to their etiology. As increasing evidence indicates that astrocytes and microglial cells play a major role in synapse maturation and function, and there is evidence of deficits in glial cell functions in ASDs, one current hypothesis is that glial dysfunctions directly contribute to their pathophysiology. The aim of this review is to summarise microglia and astrocyte functions in synapse development and their contributions to ASDs
[Ca2+] modulates the ratio between cycloxygenase and lipoxygenase metabolism of arachidonic acid in homogenates of hippocampal astroglial cultures
No full textWhile studying the enzymatic processing of arachidonic acid (AA) to eicosanoids in homogenates of hippocampal astrocytes, we observed that all the HPLC peaks corresponding to AA metabolites displayed significantly different levels depending on the presence or not of free Ca2+ in the incubation medium. A specific pattern was noticed, i.e. lipoxygenase (LOX) derivatives, in particular 12-hydroxyeicosatetraenoic acid (12-HETE), showed higher levels in medium containing 1 mM Ca2+, while cycloxygenase (COX) products including prostaglandins (PG) F2 alpha, E2 and D2 and 12-hydroxyhepatadecatrienoic acid (12-HHT), were higher in Ca(2+)-free medium. COX metabolism exceeded LOX metabolism by threefold in Ca(2+)-free medium, while it was only 60% of it in 1 mM Ca2+. The total amount of AA processed under the two conditions was identical. These data suggest that free [Ca2+] influences the pattern of AA metabolites formed in hippocampal astrocytes, with possible important implications in view of the distinct roles played by COX and LOX eicosanoids in synaptic transmission and neurotoxicity in this area
Astrocytes as active participants of glutamatergic function and regulators of its homeostasis
No full text- …
