Vagal sensory neurons drive mucous cell metaplasia

Summary: Airway sensory neuron-produced Substance P heightens allergy-induced goblet cell hyperplasia and hypersecretion of Muc5AC, electrically silencing these overreactive neurons reduced these components of lung type 2 allergic inflammatory response

Gluteal compartment syndrome: a case report

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Painful and painless mutations of SCN9A and SCN11A voltage-gated sodium channels

Chronic pain is a global problem affecting up to 20% of the world’s population and has a significant economic, social and personal cost to society. Sensory neurons of the dorsal root ganglia (DRG) detect noxious stimuli and transmit this sensory information to regions of the central nervous system (CNS) where activity is perceived as pain. DRG neurons express multiple voltage-gated sodium channels that underlie their excitability. Research over the last 20 years has provided valuable insights into the critical roles that two channels, NaV1.7 and NaV1.9, play in pain signalling in man. Gain of function mutations in NaV1.7 cause painful conditions while loss of function mutations cause complete insensitivity to pain. Only gain of function mutations have been reported for NaV1.9. However, while most NaV1.9 mutations lead to painful conditions, a few are reported to cause insensitivity to pain. The critical roles these channels play in pain along with their low expression in the CNS and heart muscle suggest they are valid targets for novel analgesic drugs

Bortezomib-induced neuropathy is in part mediated by the sensitization of TRPV1 channels

Abstract TRPV1 is an ion channel that transduces noxious heat and chemical stimuli and is expressed in small fiber primary sensory neurons that represent almost half of skin nerve terminals. Tissue injury and inflammation result in the sensitization of TRPV1 and sustained activation of TRPV1 can lead to cellular toxicity though calcium influx. To identify signals that trigger TRPV1 sensitization after a 24-h exposure, we developed a phenotypic assay in mouse primary sensory neurons and performed an unbiased screen with a compound library of 480 diverse bioactive compounds. Chemotherapeutic agents, calcium ion deregulators and protein synthesis inhibitors were long-acting TRPV1 sensitizers. Amongst the strongest TRPV1 sensitizers were proteasome inhibitors, a class that includes bortezomib, a chemotherapeutic agent that causes small fiber neuropathy in 30–50% of patients. Prolonged exposure of bortezomib produced a TRPV1 sensitization that lasted several days and neurite retraction in vitro and histological and behavioral changes in male mice in vivo. TRPV1 knockout mice were protected from epidermal nerve fiber loss and a loss of sensory discrimination after bortezomib treatment. We conclude that long-term TRPV1 sensitization contributes to the development of bortezomib-induced neuropathy and the consequent loss of sensation, major deficits experienced by patients under this chemotherapeutic agent

The δ Opioid Receptor Agonist SNC80 Selectively Activates Heteromeric μ–δ Opioid Receptors

Coexpressed and colocalized μ- and δ-opioid receptors have been established to exist as heteromers in cultured cells and <i>in vivo</i>. However the biological significance of opioid receptor heteromer activation is less clear. To explore this significance, the efficacy of selective activation of opioid receptors by SNC80 was assessed <i>in vitro</i> in cells singly and coexpressing opioid receptors using a chimeric G-protein-mediated calcium fluorescence assay, SNC80 produced a substantially more robust response in cells expressing μ–δ heteromers than in all other cell lines. Intrathecal SNC80 administration in μ- and δ-opioid receptor knockout mice produced diminished antinociceptive activity compared with wild type. The combined <i>in vivo</i> and <i>in vitro</i> results suggest that SNC80 selectively activates μ–δ heteromers to produce maximal antinociception. These data contrast with the current view that SNC80 selectively activates δ-opioid receptor homomers to produce antinociception. Thus, the data suggest that heteromeric μ–δ receptors should be considered as a target when SNC80 is employed as a pharmacological tool <i>in vivo</i>