Li Yen Mae Huang scite author profile

The roles of N-methyl-D-aspartate (NMDA) receptors and protein kinase C (PKC) are critical in generating and maintaining a variety of sustained neuronal responses. In the nociceptive (pain-sensing) system, tissue injury or repetitive stimulation of small-diameter afferent fibres triggers a dramatic increase in discharge (wind-up) or prolonged depolarization of spinal cord neurons. This central sensitization can neither be induced nor maintained when NMDA receptor channels are blocked. In the trigeminal subnucleus caudalis (a centre for processing nociceptive information from the orofacial areas), a mu-opioid receptor agonist causes a sustained increase in NMDA-activated currents by activating intracellular PKC. There is also evidence that PKC enhances NMDA-receptor-mediated glutamate responses and regulates long-term potentiation of synaptic transmission. Despite the importance of NMDA-receptors and PKC, the mechanism by which PKC alters the NMDA response has remained unclear. Here we examine the actions of intracellularly applied PKC on NMDA-activated currents in isolated trigeminal neurons. We find that PKC potentiates the NMDA response by increasing the probability of channel openings and by reducing the voltage-dependent Mg2+ block of NMDA-receptor channels.

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Neuronal somatic ATP release triggers neuron–satellite glial cell communication in dorsal root ganglia

Zhang

Chen

Wang

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

319

315

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It has been generally assumed that the cell body (soma) of a neuron, which contains the nucleus, is mainly responsible for synthesis of macromolecules and has a limited role in cell-to-cell communication. Using sniffer patch recordings, we show here that electrical stimulation of dorsal root ganglion (DRG) neurons elicits robust vesicular ATP release from their somata. The rate of release events increases with the frequency of nerve stimulation; external Ca 2؉ entry is required for the release. FM1-43 photoconversion analysis further reveals that small clear vesicles participate in exocytosis. In addition, the released ATP activates P2X7 receptors in satellite cells that enwrap each DRG neuron and triggers the communication between neuronal somata and glial cells. Blocking L-type Ca 2؉ channels completely eliminates the neuron-glia communication. We further show that activation of P2X7 receptors can lead to the release of tumor necrosis factor-␣ (TNF␣) from satellite cells. TNF␣ in turn potentiates the P2X3 receptor-mediated responses and increases the excitability of DRG neurons. This study provides strong evidence that somata of DRG neurons actively release transmitters and play a crucial role in bidirectional communication between neurons and surrounding satellite glial cells. These results also suggest that, contrary to the conventional view, neuronal somata have a significant role in cell-cell signaling.neuron-glia communication ͉ somatic release ͉ P2X3 ͉ P2X7 ͉ tumor necrosis factor ␣ N eurons use transmitters released from vesicles at presynaptic terminals to communicate with other cells (1). Recent reports suggest that transmitter release also takes place in extrasynaptic domains (ectopic release) (2). It has been assumed for a long time that the cell body (i.e., soma) of a neuron does not release transmitters in response to electrical stimulation. This assumption has been challenged by our and others' observations that neuronal somatic release indeed occurs (3-10). Using carbon fibers, several groups have shown that somatic release of catecholamine occurs through vesicular mechanisms (3, 5-7). Exocytosis in response to membrane depolarization has also been reported in the somata of dorsal root ganglion (DRG) neurons (4), a group of neurons responsible for transmitting touch, temperature and pain information from the periphery to the spinal cord (11). In most cases, soma release is triggered and enhanced by voltage-dependent Ca 2ϩ channels (4-7, 10). Despite these studies, it is not known whether vesicular release of fast-acting transmitters, e.g., ATP or glutamate, occurs in the somata. The function of somatic release is poorly understood.ATP has been shown to be released from nerve terminals and axons of DRG neurons (12, 13), and is involved in synaptic transmission at afferent-dorsal horn synapses (14) and neuron-glia signaling (15). Because ATP-activated P2X receptors become greatly sensitized after injury (16-19), ATP is a transmitter especially important for signaling injurious nociceptive informat...

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Communication between neuronal somata and satellite glial cells in sensory ganglia

Huang

Chen

2013

Glia

187

220

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Studies of the structural organization and functions of the cell body of a neuron (soma) and its surrounding satellite glial cells (SGCs) in sensory ganglia have led to the realization that SGCs actively participate in the information processing of sensory signals from afferent terminals to the spinal cord. SGCs use a variety ways to communicate with each other and with their enwrapped soma. Changes in this communication under injurious conditions often lead to abnormal pain conditions. “What are the mechanisms underlying the neuronal soma and SGC communication in sensory ganglia” and “how do tissue or nerve injuries affect the communication?” are the main questions addressed in this review.

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Ca2+-Dependent Exocytosis in the Somata of Dorsal Root Ganglion Neurons

Huang

Neher

1996

Neuron

266

204

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Using capacitance measurements and the single-cell immunoblot assay to study secretion in dorsal root ganglion neurons, we found that the somata underwent robust exocytosis upon depolarization and released substance P, in response to KCl stimulation. The parallel changes between capacitance responses and intracellular Ca2+ concentration ([Ca2+]i) at different membrane potentials and the inhibition of exocytosis by Ca2+ chelators suggest that soma release is Ca(2+)-dependent. We also assessed the level of Ca2+ required for exocytosis by raising the average [Ca2+]i with the Ca2+ ionophore, ionomycin. Capacitance changes were triggered by cytosolic Ca2+ > 0.6 microM; the [Ca2+]i at the release sites during depolarizations was estimated to be 3-10 microM. These Ca2+ levels are similar to those obtained from neuroendocrine cells, but are at least 10 times lower than those required for transmitter release from nerve terminals.

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Peripheral Inflammation Sensitizes P2X Receptor-Mediated Responses in Rat Dorsal Root Ganglion Neurons

2002

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ATP-gated P2X receptors in nociceptive sensory neurons participate in transmission of pain signals from the periphery to the spinal cord. To determine the role of P2X receptors under injurious conditions, we examined ATP-evoked responses in dorsal root ganglion (DRG) neurons isolated from rats with peripheral inflammation, induced by injections of complete Freund's adjuvant (CFA) into the hindpaw. Application of ATP induced both fast- and slow-inactivating currents in control and inflamed neurons. CFA treatment had no effect on the affinity of ATP for its receptors or receptor phenotypes. On the other hand, inflammation caused a twofold to threefold increase in both ATP-activated currents, altered the voltage dependence of P2X receptors, and enhanced the expression of P2X2 and P2X3 receptors. The increase in ATP responses gave rise to large depolarizations that exceeded the threshold of action potentials in inflamed DRG neurons. Thus, P2X receptor upregulation could account for neuronal hypersensitivity and contribute to abnormal pain responses associated with inflammatory injuries. These results suggest that P2X receptors are useful targets for inflammatory pain therapy.

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Li Yen Mae Huang

Protein kinase C reduces Mg2+ block of NMDA-receptor channels as a mechanism of modulation

Neuronal somatic ATP release triggers neuron–satellite glial cell communication in dorsal root ganglia

Communication between neuronal somata and satellite glial cells in sensory ganglia

Ca2+-Dependent Exocytosis in the Somata of Dorsal Root Ganglion Neurons

Peripheral Inflammation Sensitizes P2X Receptor-Mediated Responses in Rat Dorsal Root Ganglion Neurons

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