The impact of reduced neuronal p75NTR expression on sensory neuron phenotype and associated glia

2011 October 1900

The common neurotrophin receptor, p75NTR, has been implicated in diverse responses of sensory neurons including a role in nociception following nerve injury, suggesting that it may serve a similar role in intact sensory neurons and their satellite glial cells (SGCs). To examine the impact of suppressing neuronal p75NTR expression on known molecular modulators/regulators of the nociceptive state namely, the sodium channels NaV1.8 and NaV1.9, the nerve growth factor receptor TrkA, the potassium channel Kir4.1, glial fibrillary acidic protein (GFAP), SGC p75NTR, connexin 43, we intrathecally infused p75NTR anti-sense oligonucleotides (AS OGN), previously shown by Obata et al. (2006) to effectively suppress p75NTR expression in intact neurons. Male, Wistar rats were divided into three groups, receiving either no treatment (non-infused), seven day intrathecal infusion of p75NTR AS OGN or sense control (SC OGN) via an osmotic pump. Serial L4 and L5 DRG sections were processed for immunohistochemistry to detect alterations in NaV1.8, NaV1.9, TrkA, Kir4.1, p75NTR, GFAP and connexin-43 protein expression. Sciatic nerve sections were also processed for immunohistochemistry to detect NaV1.8, NaV1.9, TrkA and GFAP protein expression. Infusion of p75NTR AS OGNs resulted in a significant decrease in neuronal p75NTR expression, however no significant change was observed in neuronal NaV1.8, NaV1.9 or TrkA expression relative to SC OGN treated or non-infused controls. On the contrary, SGC expression of phenotypic markers normally associated with the reactive state that is induced in these cells in response to peripheral nerve axotomy was dramatically altered. More specifically, in response to p75NTR AS OGN infusion, there was a significant increase in SGC protein expression of the cytoskeletal protein GFAP and p75NTR, along with a significant decrease in expression of the inward rectifying potassium channel Kir4.1. Preliminary data also revealed this induced reactive state in SGCs to be associated with an increase in the number of SGCs surrounding individual neurons as well as increased SGC expression of the gap junction protein, connexin 43. In conclusion, reductions in neuronal p75NTR expression and potentially reduced neurotrophin signaling lead to alterations in neuron/glial or axon/glial communication that results in induction of a reactive phenotype in the associated SGCs. With our ever increasing understanding of the role of SGCs modulating pain states, elucidation of the pathways leading to adoption of pathological phenotypes can help in the identification of novel therapeutic targets.

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

Effects of Peripheral Nerve Injury on the Cells of the Dorsal Root Ganglion: a Role for Primary Cilia

Smith, Sarah K.

12 1900

Primary cilia are ubiquitous sensory organelles found on most cell types including cells of the dorsal root ganglia (DRG). The DRG are groups of peripheral neurons that relay sensory information from the periphery to the CNS. Other cell types in the DRG include a type of glial cell, the satellite glial cells (SGCs). The SGCs surround the DRG neurons and, with the neurons, form functional sensory units. Currently are no reports describing the numbers of DRG cells that have cilia. We found that 26% of the SGCs had primary cilia. The incidence of cilia on neurons varied with neuron size, a property that roughly correlates with physiological characteristics. We found that 29% of the small, 16% of the medium and 5% of the large neurons had primary cilia. Primary cilia have been shown to have a role in cell proliferation in a variety of cell types. In some of the cells the cilia mediate the proliferative effects of Sonic hedgehog (Shh). In the CNS, Shh signaling through primary cilia affects proliferation during development as well as following injury, but no studies have looked at this function in the PNS. The SGCs and neurons of the DRG undergo complex changes following peripheral nerve injury such as axotomy. One marked change seen after axotomy is SGC proliferation and at later stages, neuronal death. We found that following axotomy there is a significant increase in the percentage of SGCs with primary cilia. We also found a significant increase in the percentage of medium-sized neurons with primary cilia. In other experiments we tested the idea that Shh plays a role in SGC proliferation. When Shh signaling was blocked following axotomy we found decreased proliferation of SGCs. This is the first report of a change in the percentage of cells with cilia following injury in the PNS, and the first report of a role for Shh in SGC proliferation following axotomy.

Peripheral nervous system

primary cilia

satellite glial cells

proliferation

The Response of Satellite Glial Cells to P2X7 Receptor Activation

Kursewicz, Christina D

01 January 2017

Satellite glial cells (SGCs) surround the cell bodies of neurons of the peripheral nervous system, including those of the sensory ganglia. Their close apposition to the neuronal soma allows for bi-directional communication between neurons and SGCs, which are thought to regulate neuronal activity. After nerve injury, SGCs in the dorsal root ganglia contribute to neuropathic pain. Although the mechanisms are not fully understood, SGCs show increased coupling via gap junctions, and communicate with the neuron via bi-directional purinergic signaling after nerve injury. The increased coupling between SGCs and neurons may have implications for chronic pain following peripheral nerve injury. In vivo studies suggest that injury through the administration of capsaicin to the sensory nerve endings causes SGCs to be activated and proliferate. We have shown that capsaicin treatment in an in vitro co-culture of sensory neurons and SGCs increased the expression of the proliferation marker, Ki-67 in the glia. Here, we examine whether purinergic signaling plays a role in the promotion of SGC proliferation.

satellite glial cells

purinergic signaling

P2X7

proliferation

BzATP

Cell Biology

Avaliação estrutural e quantitativa dos efeitos do envelhecimento sobre o gânglio trigeminal de ratos Wistar / Structural and quantitative evaluation of aging process on trigeminal ganglion of Wistar rats

Silva, Ricardo Eustáquio da

23 February 2010

O envelhecimento é uma falha progressiva nos processos fisiológicos celulares, produzindo alterações morfológicas nas células e nos tecidos. No sistema nervoso, produz uma redução no número de neurônios, nas fibras nervosas, principalmente nas arborizações dendríticas e nas espinhas sinápticas, e nas células da glia que, de acordo com sua localização e tipo celular, podem diminuir, permanecer constantes ou mesmo aumentar numericamente. Na presente pesquisa, avaliou-se os efeitos do envelhecimento sobre o gânglio trigeminal (GT) de ratos Wistar em animais jovens (2 meses de vida), adultos (12 meses de vida) e idosos (24 meses de vida). Os GT foram submetidos às técnicas histológicas da hematoxilina e eosina e Picro-sírius, onde avaliou-se, respectivamente, a densidade das células satélites glias (CGS) e o componente colágeno ganglionar. Através da técnica histoquímica da NADH-d, avaliou-se a área do perfil do GT, a área do perfil dos corpos celulares dos neurônios ganglionares e a densidade neuronal. Uma avaliação qualitativa foi também realizada relativamente à imunorreatividade dos neurônios ganglionares à substância P (SP) e ao peptídeo intestinal vasoativo (VIP). A densidade das CGS foi maior nos animais jovens do que nos animais adultos e idosos. Verificou-se, qualitativamente, que à medida que o animal envelhece há uma diminuição das fibras colágenas do tipo III, passando a predominar, nos animais idosos, as fibras do tipo I. A área do perfil celular dos corpos neuronais foi maior nos animais adultos sendo que em todos os grupos predominaram neurônios de tamanho médio, com a área do perfil celular entre 490 e 1100 μm2. A densidade neuronal apresentou-se maior nos animais jovens, e sem variações estatísticas entre os animais adultos e idosos. Em todos os grupos estudados, os neurônios pequenos foram os que apresentaram maior imunorreatividade à SP e ao VIP. / Aging is a progressive failure in cellular physiological processes. It determines morphological changes in cells of different tissues. In the nervous system, a reduction in neuron number and in neuron fibers, mainly in dendritic tree and synaptic, are described. With aging the glial cells may increase or decrease in number or also remain constant. In the present work the effects of aging were evaluated on the trigeminal ganglion (TG) comparing young (2 months age), adult (12 months age) and old rats (24 months age). Histological sections of TG were stained with hematoxilin-eosin technique to determine the density of satellite glial cells and Picro-sirius under polarized light to evaluate the Types I and III of collagen fibers. The NADH-diaphorase technique allowed determining the perycarion area. The immunoreactivity of ganglionar neurons to Substance P (SP) and vasoactive intestinal peptide (VIP) were also qualitatively evaluated. The glial cells density was higher in young and adult animals than in old animals. The type I collagen fibers predominates in ganglia of old animals whereas in the young animals is characteristic the presence of the type III collagen fibers. Although the perycarion area was higher in adult animals the medium-sized neurons predominated in all groups. Their areas ranged from 490 to 1100 μm2. It was also observed that the neuron density was higher in young animals. In the adult and old animals the neuron density was similar. In all groups the immunoreactivity both to SP an VIP was detected mainly in neurons of small perycarion.

Aging

Células satélites gliais

Collagen fibers

Envelhecimento

Fibras colágenas

Gânglio trigeminal

Immunohistochemistry

Imunohistoquímica

Satellite glial cells

Trigeminal ganglion

Avaliação estrutural e quantitativa dos efeitos do envelhecimento sobre o gânglio trigeminal de ratos Wistar / Structural and quantitative evaluation of aging process on trigeminal ganglion of Wistar rats

Ricardo Eustáquio da Silva

23 February 2010

O envelhecimento é uma falha progressiva nos processos fisiológicos celulares, produzindo alterações morfológicas nas células e nos tecidos. No sistema nervoso, produz uma redução no número de neurônios, nas fibras nervosas, principalmente nas arborizações dendríticas e nas espinhas sinápticas, e nas células da glia que, de acordo com sua localização e tipo celular, podem diminuir, permanecer constantes ou mesmo aumentar numericamente. Na presente pesquisa, avaliou-se os efeitos do envelhecimento sobre o gânglio trigeminal (GT) de ratos Wistar em animais jovens (2 meses de vida), adultos (12 meses de vida) e idosos (24 meses de vida). Os GT foram submetidos às técnicas histológicas da hematoxilina e eosina e Picro-sírius, onde avaliou-se, respectivamente, a densidade das células satélites glias (CGS) e o componente colágeno ganglionar. Através da técnica histoquímica da NADH-d, avaliou-se a área do perfil do GT, a área do perfil dos corpos celulares dos neurônios ganglionares e a densidade neuronal. Uma avaliação qualitativa foi também realizada relativamente à imunorreatividade dos neurônios ganglionares à substância P (SP) e ao peptídeo intestinal vasoativo (VIP). A densidade das CGS foi maior nos animais jovens do que nos animais adultos e idosos. Verificou-se, qualitativamente, que à medida que o animal envelhece há uma diminuição das fibras colágenas do tipo III, passando a predominar, nos animais idosos, as fibras do tipo I. A área do perfil celular dos corpos neuronais foi maior nos animais adultos sendo que em todos os grupos predominaram neurônios de tamanho médio, com a área do perfil celular entre 490 e 1100 μm2. A densidade neuronal apresentou-se maior nos animais jovens, e sem variações estatísticas entre os animais adultos e idosos. Em todos os grupos estudados, os neurônios pequenos foram os que apresentaram maior imunorreatividade à SP e ao VIP. / Aging is a progressive failure in cellular physiological processes. It determines morphological changes in cells of different tissues. In the nervous system, a reduction in neuron number and in neuron fibers, mainly in dendritic tree and synaptic, are described. With aging the glial cells may increase or decrease in number or also remain constant. In the present work the effects of aging were evaluated on the trigeminal ganglion (TG) comparing young (2 months age), adult (12 months age) and old rats (24 months age). Histological sections of TG were stained with hematoxilin-eosin technique to determine the density of satellite glial cells and Picro-sirius under polarized light to evaluate the Types I and III of collagen fibers. The NADH-diaphorase technique allowed determining the perycarion area. The immunoreactivity of ganglionar neurons to Substance P (SP) and vasoactive intestinal peptide (VIP) were also qualitatively evaluated. The glial cells density was higher in young and adult animals than in old animals. The type I collagen fibers predominates in ganglia of old animals whereas in the young animals is characteristic the presence of the type III collagen fibers. Although the perycarion area was higher in adult animals the medium-sized neurons predominated in all groups. Their areas ranged from 490 to 1100 μm2. It was also observed that the neuron density was higher in young animals. In the adult and old animals the neuron density was similar. In all groups the immunoreactivity both to SP an VIP was detected mainly in neurons of small perycarion.

Células satélites gliais

Envelhecimento

Fibras colágenas

Gânglio trigeminal

Imunohistoquímica

Aging

Collagen fibers

Immunohistochemistry

Satellite glial cells

Trigeminal ganglion