Glutamate Neurotransmission in Rodent Models of Traumatic Brain Injury

Dorsett, Christopher R.; McGuire, Jennifer L.; DePasquale, Erica A. K.; Gardner, Amanda E.; Floyd, Candace L.; McCullumsmith, Robert E.

doi:10.1089/neu.2015.4373

Cited by 111 publications

(84 citation statements)

References 126 publications

(170 reference statements)

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“…The recycled glutamate serves as the principle source of synaptically released glutamate for neurotransmission. In addition to providing a mechanism of efficiently recycling extracellular glutamate, the 'astrocytic cradle' creates an anatomical and functional barrier that blocks the 'spillover' of glutamate into the extrasynaptic space (Dorsett et al, 2016;McCullumsmith and Sanacora, 2015). Although glutamate binds to EAATs with high affinity, not all the bound glutamate is immediately transported across the plasma membrane of astrocytes (Dorsett et al, 2016).…”

Section: Astrocytesmentioning

confidence: 99%

“…In addition to providing a mechanism of efficiently recycling extracellular glutamate, the 'astrocytic cradle' creates an anatomical and functional barrier that blocks the 'spillover' of glutamate into the extrasynaptic space (Dorsett et al, 2016;McCullumsmith and Sanacora, 2015). Although glutamate binds to EAATs with high affinity, not all the bound glutamate is immediately transported across the plasma membrane of astrocytes (Dorsett et al, 2016). EAAT-bound glutamate may become 'unbound', released, and rebound to neighboring glutamate transporters, thus bouncing from one transporter to the other until it is eventually transported across the plasma membrane (Tzingounis and Wadiche, 2007).…”

Section: Astrocytesmentioning

confidence: 99%

“…EAAT-bound glutamate may become 'unbound', released, and rebound to neighboring glutamate transporters, thus bouncing from one transporter to the other until it is eventually transported across the plasma membrane (Tzingounis and Wadiche, 2007). This process of the temporary holding of glutamate before transport is referred to as 'buffering' and it helps limit its spillover outside the cradle (Dorsett et al, 2016). Finally, through their podocytic endfeet, astrocytes come in close proximity to blood vessels and vascular pericytes, leaving an empty space-a 'no man's land' of extracellular space that forms an integral part of the blood-brain barrier (BBB) and brain lymphatic systems (Iliff and Nedergaard, 2013;Louveau et al, 2015).…”

Section: Astrocytesmentioning

confidence: 99%

“…The extent and effects of glutamate diffusion will depend upon the spatial arrangement of extrasynaptic glutamate receptors, glutamate synapses, and their glutamate transporter buffering zones (Dorsett et al, 2016;McCullumsmith and Sanacora, 2015;Tzingounis and Wadiche, 2007). In physiological conditions, the buffering and release of glutamate is tightly regulated by EAATs and glutamate is not allowed to diffuse beyond 0.5 μm from its point of origin, thus restricting access to extrasynaptic glutamate receptors (Tzingounis and Wadiche, 2007).…”

Section: Conceptual Convergence: a Working Modelmentioning

confidence: 99%

“…Extracellular diffusion of glutamate can lead to the loss of synaptic fidelity, decreased specificity of neurotransmission, and lead to 'noisy', non-specific, and disruptive neural activity experienced by patients as cognitive and affective symptoms (Dorsett et al, 2016). Although precise data are lacking, we speculate that inflammatory activation in mood disorders might lead to increased AMPA activity during early phases followed by desensitization and decreased AMPA activity in later stages resulting in synaptic depression, decreased transmission efficiency, and impaired synaptic plasticity (Choquet and Triller, 2013;Popoli et al, 2012;Pribiag and Stellwagen, 2014;Pribiag and Stellwagen, 2013).…”

Section: Conceptual Convergence: a Working Modelmentioning

confidence: 99%

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Inflammation, Glutamate, and Glia: A Trio of Trouble in Mood Disorders

Haroon

Miller

Sanacora

2016

Neuropsychopharmacol

360

294

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Increasing data indicate that inflammation and alterations in glutamate neurotransmission are two novel pathways to pathophysiology in mood disorders. The primary goal of this review is to illustrate how these two pathways may converge at the level of the glia to contribute to neuropsychiatric disease. We propose that a combination of failed clearance and exaggerated release of glutamate by glial cells during immune activation leads to glutamate increases and promotes aberrant extrasynaptic signaling through ionotropic and metabotropic glutamate receptors, ultimately resulting in synaptic dysfunction and loss. Furthermore, glutamate diffusion outside the synapse can lead to the loss of synaptic fidelity and specificity of neurotransmission, contributing to circuit dysfunction and behavioral pathology. This review examines the fundamental role of glia in the regulation of glutamate, followed by a description of the impact of inflammation on glial glutamate regulation at the cellular, molecular, and metabolic level. In addition, the role of these effects of inflammation on glia and glutamate in mood disorders will be discussed along with their translational implications.

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Section: Astrocytesmentioning

confidence: 99%

Section: Astrocytesmentioning

confidence: 99%

Section: Astrocytesmentioning

confidence: 99%

Section: Conceptual Convergence: a Working Modelmentioning

confidence: 99%

Section: Conceptual Convergence: a Working Modelmentioning

confidence: 99%

See 3 more Smart Citations

Inflammation, Glutamate, and Glia: A Trio of Trouble in Mood Disorders

Haroon

Miller

Sanacora

2016

Neuropsychopharmacol

360

294

View full text Add to dashboard Cite

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Cell and Tissue Instructive Materials for Central Nervous System Repair

Rocha

Silva

Barata‐Antunes

et al. 2020

Adv Funct Materials

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Neurodegenerative disorders and traumatic events affecting the central nervous system (CNS) represent one of the main health problems nowadays. The level of disability and impairment of these patients is very high, both at physiological and psychological level, drastically altering a person's lifestyle. The fact that CNS tissue has a limited capacity of regeneration has hampered the development of possible therapies to these conditions. The specificity of each disease also increases the complexity of creating strategies capable of inducing significant recovery. Therefore, the search for a solution for these problems most likely demands a combinatorial approach that integrates knowledge from different fields. Tissue engineering and regenerative medicine (TERM) concepts merge areas such as biology, chemistry, physics, or biomaterials science, and it is a strong candidate for CNS applications. In particular, the development of cell and tissue instructive materials (CTIMs) can bring new opportunities for the treatment of these conditions. In this review, the authors summarize and discuss the most recent advances in the development of CTIMs for CNS applications, focusing on traumatic conditions such as spinal cord injuy, traumatic brain injuy, but also stroke, and other neurodegenerative diseases such as Alzheimer's and Parkinson's disease as well as multiple sclerosis.

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TREM2 alleviates white matter injury after traumatic brain injury in mice might be mediated by regulation of DHCR24/LXR pathway in microglia

Li,

Yu,

et al. 2024

Clinical & Translational Med

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BackgroundWhite matter injury (WMI) is an important pathological process after traumatic brain injury (TBI). The correlation between white matter functions and the myeloid cells expressing triggering receptor‐2 (TREM2) has been convincingly demonstrated. Moreover, a recent study revealed that microglial sterol metabolism is crucial for early remyelination after demyelinating diseases. However, the potential roles of TREM2 expression and microglial sterol metabolism in WMI after TBI have not yet been explored.MethodsControlled cortical injury was induced in both wild‐type (WT) and TREM2 depletion (TREM2 KO) mice to simulate clinical TBI. COG1410 was used to upregulate TREM2, while PLX5622 and GSK2033 were used to deplete microglia and inhibit the liver X receptor (LXR), respectively. Immunofluorescence, Luxol fast blue staining, magnetic resonance imaging, transmission electron microscopy, and oil red O staining were employed to assess WMI after TBI. Neurological behaviour tests and electrophysiological recordings were utilized to evaluate cognitive functions following TBI. Microglial cell sorting and transcriptomic sequencing were utilized to identify alterations in microglial sterol metabolism‐related genes, while western blot was conducted to validate the findings.ResultsTREM2 expressed highest at 3 days post‐TBI and was predominantly localized to microglial cells within the white matter. Depletion of TREM2 worsened aberrant neurological behaviours, and this phenomenon was mediated by the exacerbation of WMI, reduced renewal of oligodendrocytes, and impaired phagocytosis ability of microglia after TBI. Subsequently, the upregulation of TREM2 alleviated WMI, promoted oligodendrocyte regeneration, and ultimately facilitated the recovery of neurological behaviours after TBI. Finally, the expression of DHCR24 increased in TREM2 KO mice after TBI. Interestingly, TREM2 inhibited DHCR24 and upregulated members of the LXR pathway. Moreover, LXR inhibition could partially reverse the effects of TREM2 upregulation on electrophysiological activities.ConclusionsWe demonstrate that TREM2 has the potential to alleviate WMI following TBI, possibly through the DHCR24/LXR pathway in microglia.

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Glutamate Neurotransmission in Rodent Models of Traumatic Brain Injury

Cited by 111 publications

References 126 publications

Inflammation, Glutamate, and Glia: A Trio of Trouble in Mood Disorders

Inflammation, Glutamate, and Glia: A Trio of Trouble in Mood Disorders

Cell and Tissue Instructive Materials for Central Nervous System Repair

TREM2 alleviates white matter injury after traumatic brain injury in mice might be mediated by regulation of DHCR24/LXR pathway in microglia

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