Neuronal-Glial Communication and the Biology of Major Depression

Ordway, Gregory A.

01 August 2009

No description available.

depression

neuronal-glial

communication

Biomedical Sciences

Neuronal-Glial Interactions Germane to the Biology of Depression

Ordway, Gregory A.

03 June 2010

No description available.

depression

neuronal-glial

interactions

germane

Biomedical Sciences

Neuronal-Glial Communication and the Biology of Major Depression

Ordway, Gregory A.

01 November 2010

No description available.

depression

neuronal-glial

communication

Biomedical Sciences

GLIAL CELL REMODELING DURING TERMINAL NERVE TRUNK FORMATION IN DROSOPHILA MELANOGASTER

Siefert, Matthew Emerson

09 December 2013

No description available.

Zoology

Glial Cells

Nervous System Remodeling

Drosophila

The role of potassium buffering and apoptosis of trigeminal satellite glial cells in the induction and maintenance of orofacial neuropathic pain in rats

Bustamante Diaz, Hedie A.

28 June 2011

Satellite glial cells (SGC) are laminar cells that wrap completely around the sensory neuron and are responsible for buffering extracellular K+ after neuronal excitation. A decrease in the potassium buffering capacity of SGC has been associated with neuropathic pain (NP) behavior and apoptosis. This dissertation investigated the role of the potassium buffering capacity and apoptosis of trigeminal satellite glial cells (SGC) in the maintenance and development of orofacial NP in rats using in vivo and in vitro methodologies. In vivo endpoints were evaluated after performing chronic constriction injury (CCI) of the infraorbital nerve (IoN). NP signs and behavior were evaluated at 5, 10, 20 40 and 80 hours after injury. We evaluated the potassium buffering capacity of SGC by measuring the intracellular potassium concentration and protein levels and gene expression of the Kir4.1 and the SK3 potassium channels and gap junction protein connexin 43 (Cx43). We evaluated apoptosis endpoints including protein levels and gene expression of apoptotic related proteins bcl-2, caspase 9, caspase 3 and p53. Results indicate that NP signs developed as early as 5 hours after injury. After PNI, SGC responded by increasing their intracellular potassium concentration and by increasing protein levels of Kir4.1, SK3 and Cx43. Nonetheless, this increase in protein levels was not accompanied by an increase in gene expression. Apoptosis results revealed that SGC decreased protein levels and gene expression of anti-apoptotic protein Bcl-2. Using in vitro methodologies, we developed primary trigeminal SGC cultures and evaluated how a decrease in the intracellular potassium concentration modulates apoptosis induced by the mitochondrial and death receptor pathways. SGC depleted of potassium after hypoosmotic shock showed a significant increase in early apoptosis after incubation with mitochondrial pathway apoptotic inducer staurosporine when compared to SGC with normal intracellular concentration. This research has revealed that SGC respond early to PNI by increasing their potassium buffering capacity. We also determined that the mitochondrial apoptotic pathway might be involved in the trigeminal SGC response to PNI. From our in vitro experiments we have revealed that potassium is an important modulator of apoptosis induced by the mitochondrial pathway in cultured trigeminal SGC. / Ph. D.

neuropathic pain

Satellite glial cells

potassium

Apoptosis

Impaired Behavioral and Pathological Outcomes Following Blast Neurotrauma

Sajja, Venkata Siva Sai Sujith

30 August 2013

Blast-induced neurotrauma (BINT) is a major societal concern due to the complex expression of neuropathological disorders after exposure to blast. Disruptions in neuronal function, proximal in time to the blast exposure, may eventually contribute to the late emergence of the clinical deficits. Besides complications with differential clinical diagnosis, the biomolecular mechanism underlying BINT that gives rise to cognitive deficits is poorly understood. Some pre-clinical studies have demonstrated cognitive deficits at an acute stage following blast overpressure (BOP) exposure. However, the behavioral deficit type (e.g., short term memory) and the mechanism underlying injury prognosis that onsets the cognitive deficits remains to be further investigated. An established rodent model of blast neurotrauma was used in order to study impaired behavioral and neuropathological outcomes following blast. Anesthetized rats were exposed to a calibrated BOP using a blast simulator while control animals were not exposed to BOP. Behavioral changes in short term memory and anxiety were assessed with standard behavioral techniques (novel objected recognition paradigm and light and dark box test) at acute and chronic stages (range: 3 hours -- 3 months). In addition, brains were assayed for neurochemical changes using proton magnetic resonance spectroscopy (MRS) and neuropathology with immunohistochemistry in cognitive regions of brain (hippocampus, amygdala, frontal cortex and nucleus accumbens) Early metabolic changes and oxidative stress were observed along with a compromise in energy metabolism associated with sub-acute (7 days following BOP exposure) active neurodegeneration and glial scarring. Data suggested GABA shunting pathway was activated and phospholipase A2 regulated arachadonic acid pathway may be involved in cellular death cascades. In addition, increased myo-inositol levels in medial pre-frontal cortex (PFC) further supported the glial scarring and were associated with impaired working memory at a sub-acute stage (7 days) following BOP exposure. Chronic working memory issues and anxiety associated behavior could be related to chronic activation of microglia in hippocampus and astrocytes in amygdala respectively. Furthermore, these results from MRS could be directly translated into clinical studies to provide a valuable insight into diagnosis of BINT, and it is speculated that gliosis associated markers (myo-inositol) may be a potential biomarker for blast-induced memory impairment. / Ph. D.

Blast

neurotrauma

Memory

anxiety

glial scarring

Chemical Transmission between Dorsal Root Ganglion Somata via Intervening Satellite Glial Cell

Kim, Hyunhee

04 December 2012

The structure of afferent neurons is pseudounipolar. Studies suggest that they relay action potentials (APs) to both directions of the T-junctions to reach the cell body and the spinal cord. Moreover, the somata are electrically excitable and shown to be able to transmit the signals to associated satellite cells. Our study demonstrates that this transmission can go further and pass onto passive neighbouring somata, if they are in direct contact with same satellite cells. The neurons activate the satellite cells by releasing ATP. This triggers the satellite cells to exocytose acetylcholine to the neighbouring neurons. In addition, the ATP inhibits the nicotinic receptors of the neurons by activating P2Y receptors and initiating the G-protein-mediated pathway, thus reducing the signals that return to the neurons that initiated the signals. This “sandwich synapse” represents a unique pathway by the ectopic release between the somata and the satellite cells.

satellite glial cell

dorsal root ganglia

neuron-glial interaction

patch clamp technique

0317

0719

Chemical Transmission between Dorsal Root Ganglion Somata via Intervening Satellite Glial Cell

Kim, Hyunhee

04 December 2012

The structure of afferent neurons is pseudounipolar. Studies suggest that they relay action potentials (APs) to both directions of the T-junctions to reach the cell body and the spinal cord. Moreover, the somata are electrically excitable and shown to be able to transmit the signals to associated satellite cells. Our study demonstrates that this transmission can go further and pass onto passive neighbouring somata, if they are in direct contact with same satellite cells. The neurons activate the satellite cells by releasing ATP. This triggers the satellite cells to exocytose acetylcholine to the neighbouring neurons. In addition, the ATP inhibits the nicotinic receptors of the neurons by activating P2Y receptors and initiating the G-protein-mediated pathway, thus reducing the signals that return to the neurons that initiated the signals. This “sandwich synapse” represents a unique pathway by the ectopic release between the somata and the satellite cells.

satellite glial cell

dorsal root ganglia

neuron-glial interaction

patch clamp technique

0317

0719

Wirkung von Osteopontin auf die osmotische Volumenregulation von Müller- und Bipolarzellen der Rattennetzhaut

Wahl, Vincent

29 February 2016

Die Arbeit befasst sich mit dem Anschwellen von Neuronen und Gliazellen der Netzhaut, was einen wichtigen pathogenetischen Faktor des Netzhautödems darstellt. Osteopontin ist ein neuroprotektiver Faktor, der durch GDNF-Stimulation (glial cell line-derived neurotrophic factor) aus Müllerzellen ausgeschüttet wird. Die durch Osteopontin vermittelte Inhibition der osmotischen Zellschwellung von Müllerzellen der Ratte in Anwesenheit von Bariumionen oder H2O2 wird beschrieben und es wird dargestellt, dass Osteopontin keinen Einfluss auf die osmotische Zellschwellung der Bipolarzellen hat. Der für Müllerzellen beschriebene Effekt war dosisabhängig mit einer mittleren effektiven Konzentration von ca. 0,6 ng/ml. Durch den Einsatz pharmakologischer Rezeptor- oder Enzymblocker bzw. Antikörper werden die Schritte der Osteopontinwirkung identifiziert. Osteopontin induziert die Freisetzung von VEGF, Glutamat, ATP und Adenosin aus Müllerzellen. Die Osteopontinwirkung wurde verhindert durch die Blockade von spannungsabhängigen Natriumkanälen, T-Typ Calciumkanälen, Kalium- und Chloridkanälen. Der Effekt ist außerdem abhängig von einem intrazellulären Calciumsignal, der Aktivierung der Phospholipase C und der Proteinkinase C und der vesikulären Exozytose von Glutamat. Die Arbeit kommt zu dem Schluss, dass der neuroprotektive Effekt von Osteopontin teilweise durch das Verhindern eines Anschwellens der Müllerzellen und durch die Induktion einer Freisetzung von VEGF und Adenosin vermittelt wird.

Osteopontin

Müllerzelle

Glia

Retina

osteopontin

retinal glial cells

ddc:610

The role of astrocytes in murine models of toxic demyelination

Menken, Lena

22 June 2016

No description available.

610

astrocytes

glial fibrillary acidic protein

multiple sclerosis

Molekulare Medizin