Improvement of neuronal cell survival by astrocyte‐derived exosomes under hypoxic and ischemic conditions depends on prion protein

Guitart, Kathrin; Loers, Gabriele; Buck, Friedrich; Bork, Ute; Schachner, Melitta; Kleene, Ralf

doi:10.1002/glia.22963

Cited by 127 publications

(111 citation statements)

References 59 publications

(95 reference statements)

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“…One potential mechanism of astrocyte-mediated neuroprotection after IPC may involve limiting neuronal excitotoxicity by clearing glutamate [21], and in stroke astrocytes may protect neurons from oxidative stress [103]. Astrocytes are capable of engaging in spatial buffering, which allows them to transport and metabolize amino acids and glucose, as well as upregulate antioxidants and free radical scavengers in the ischemic region [103,107,[114][115][116]. Prion protein protects neurons against oxidative stress, hypoxia, ischemia, and hypoglycemia, and may be supplied to neurons by astrocytes under ischemic or hypoxic conditions [117].…”

Section: Astrocytesmentioning

confidence: 99%

Neuroimmune Response in Ischemic Preconditioning

McDonough

Weinstein

2016

Neurotherapeutics

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Ischemic preconditioning (IPC) is a robust neuroprotective phenomenon in which a brief period of cerebral ischemia confers transient tolerance to subsequent ischemic challenge. Research on IPC has implicated cellular, molecular, and systemic elements of the immune response in this phenomenon. Potent molecular mediators of IPC include innate immune signaling pathways such as Toll-like receptors and type 1 interferons. Brain ischemia results in release of proand anti-inflammatory cytokines and chemokines that orchestrate the neuroinflammtory response, resolution of inflammation, and transition to neurological recovery and regeneration. Cellular mediators of IPC include microglia, the resident central nervous system immune cells, astrocytes, and neurons. All of these cell types engage in cross-talk with each other using a multitude of signaling pathways that modulate activation/ suppression of each of the other cell types in response to ischemia. As the postischemic neuroimmune response evolves over time there is a shift in function toward provision of trophic support and neuroprotection. Peripheral immune cells infiltrate the central nervous system en masse after stroke and are largely detrimental, with a few subtypes having beneficial, protective effects, though the role of these immune cells in IPC is largely unknown. The role of neural progenitor cells in IPC-mediated neuroprotection is another active area of investigation as is the role of microglial proliferation in this setting. A mechanistic understanding of these molecular and cellular mediators of IPC may not only facilitate more effective direct application of IPC to specific clinical scenarios, but also, more broadly, reveal novel targets for therapeutic intervention in stroke.

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Section: Astrocytesmentioning

confidence: 99%

Neuroimmune Response in Ischemic Preconditioning

McDonough

Weinstein

2016

Neurotherapeutics

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“…EVs are constitutively released from most (if not all) cells, and EV shedding can be induced by a variety of stimuli. There is an increasing amount of evidence that EVs, particularly ADEVs, can regulate neurological function (Chaudhuri et al, ; Guitart et al, ; Hu et al, ; Xin et al, ), and recent findings suggest that ADEVs communicate to the peripheral immune system (Dickens et al, ). Although it has been suggested that EV cargo is modified by the stimulus used to induce release, we are only aware of one study (Drago et al, ) that has compared the cargo of EVs released in response to a stimulus (ATP) to constitutive release.…”

Section: Discussionmentioning

confidence: 99%

Stimulus‐dependent modifications in astrocyte‐derived extracellular vesicle cargo regulate neuronal excitability

Chaudhuri

Dasgheyb

DeVine

et al. 2019

Glia

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Extracellular vesicles have now emerged as key players in cell‐to‐cell communication. This is particularly important in the central nervous system, where glia–neuron cross‐talk helps maintain normal neuronal function. Astrocyte‐derived extracellular vesicles (ADEVs) secreted constitutively promote neurite outgrowth and neuronal survival. However, extracellular stimuli can alter the cargo and downstream functions of ADEVs. For example, ADEVs secreted in response to inflammation contain cargo microRNAs and proteins that reduce neurite outgrowth, neuronal firing, and promote neuronal apoptosis. We performed a comprehensive quantitative proteomic analysis to enumerate the proteomic cargo of ADEVs secreted in response to multiple stimuli. Rat primary astrocytes were stimulated with a trophic stimulus (adenosine triphosphate, ATP), an inflammatory stimulus (IL‐1β) or an anti‐inflammatory stimulus (IL10) and extracellular vesicles secreted within a 2 hr time frame were collected using sequential ultracentrifugation method. ADEVs secreted constitutively without exposure to any stimulus were used a control. A tandem mass tag‐based proteomic platform was used to identify and quantify proteins in the ADEVs. Ingenuity pathway analysis was performed to predict the downstream signaling events regulated by ADEVs. We found that in response to ATP or IL10, ADEVs contain a set of proteins that are involved in increasing neurite outgrowth, dendritic branching, regulation of synaptic transmission, and promoting neuronal survival. In contrast, ADEVs secreted in response to IL‐1β contain proteins that regulate peripheral immune response and immune cell trafficking to the central nervous system.

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“…In the injured CNS, EVs were recently found to cross the blood–brain barrier and promote neuroinflammation . Furthermore, certain types of EVs appear to support neuronal survival under conditions of ischemic stress . In neurodegenerative diseases, EVs contribute to the seeding and spreading of toxic protein aggregates, and influence the aggregation process and clearance of these aggregates …”

Section: Introductionmentioning

confidence: 99%

Fibroblast Growth Factor 2‐Mediated Regulation of Neuronal Exosome Release Depends on VAMP3/Cellubrevin in Hippocampal Neurons

et al. 2020

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Extracellular vesicles (EVs) are endogenous membrane‐derived vesicles that shuttle bioactive molecules between glia and neurons, thereby promoting neuronal survival and plasticity in the central nervous system (CNS) and contributing to neurodegenerative conditions. Although EVs hold great potential as CNS theranostic nanocarriers, the specific molecular factors that regulate neuronal EV uptake and release are currently unknown. A combination of patch‐clamp electrophysiology and pH‐sensitive dye imaging is used to examine stimulus‐evoked EV release in individual neurons in real time. Whereas spontaneous electrical activity and the application of a high‐frequency stimulus induce a slow and prolonged fusion of multivesicular bodies (MVBs) with the plasma membrane (PM) in a subset of cells, the neurotrophic factor basic fibroblast growth factor (bFGF) greatly increases the rate of stimulus‐evoked MVB‐PM fusion events and, consequently, the abundance of EVs in the culture medium. Proteomic analysis of neuronal EVs demonstrates bFGF increases the abundance of the v‐SNARE vesicle‐associated membrane protein 3 (VAMP3, cellubrevin) on EVs. Conversely, knocking‐down VAMP3 in cultured neurons attenuates the effect of bFGF on EV release. The results determine the temporal characteristics of MVB‐PM fusion in hippocampal neurons and reveal a new function for bFGF signaling in controlling neuronal EV release.

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Improvement of neuronal cell survival by astrocyte‐derived exosomes under hypoxic and ischemic conditions depends on prion protein

Cited by 127 publications

References 59 publications

Neuroimmune Response in Ischemic Preconditioning

Neuroimmune Response in Ischemic Preconditioning

Stimulus‐dependent modifications in astrocyte‐derived extracellular vesicle cargo regulate neuronal excitability

Fibroblast Growth Factor 2‐Mediated Regulation of Neuronal Exosome Release Depends on VAMP3/Cellubrevin in Hippocampal Neurons

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