University of Exeter

education 📍 Exeter, United Kingdom
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University of Exeter
2
EM Publications
2
EM Researchers

Associated Institutions

Royal Devon and Exeter Hospital
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Derriford Hospital
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Wellcome Centre of Cultures and Environments of Health
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MRC Centre for Medical Mycology
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GW4 Facility for High-Resolution Electron Cryo-Microscopy
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Erythromelalgia Researchers

Randall AD
2 EM publications • h-index: 65
Vollert J
1 EM publication • h-index: 34

Publications

Enhanced trafficking of an inherited erythromelalgia Na1.7 mutant channel at a physiological temperature.

Mis MA, Tyagi S, Akin EJ, Ghovanloo MR, Zhao P , et al.
Neurobiology of pain (Cambridge, Mass.)

Gain-of-function mutations which enhance activation of Na1.7, a widely expressed sodium channel in nociceptors, cause human pain disorders including inherited erythromelalgia (IEM). IEM is characterized by attacks of burning pain in distal extremities triggered by warmth, with cooling of affected limbs providing temporary relief. We investigated the behaviour of the IEM-linked L858F mutant Na1.7 channel at physiological normal skin temperature (NST, 33-35 °C) in IB4-negative DRG sensory neurons known to include thermosensors. Using voltage-clamp recordings at NST we found that the Na1.7-L858F mutant channel shows the characteristic hyperpolarizing shift in activation as has been previously found in recordings at room temperature, and that the current density of the L858F channels is significantly larger than that of WT channels. Using a live-cell optical pulse-chase imaging methodology at NST we observed that accelerated forward-trafficking significantly increases membrane insertion of mutant channels in IB4 neurons. Current-clamp recordings at NST show increased firing of IB4 neurons that express the L858F mutant channel, consistent with increased trafficking of the channel at this physiological temperature. Our findings identify enhanced trafficking and membrane insertion of the L858F mutant channels at normal skin temperature in IB4 neurons as an additional mechanism underlying IEM-related neuronal hyperexcitability.

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Pharmacological reversal of a pain phenotype in iPSC-derived sensory neurons and patients with inherited erythromelalgia.

Cao L, McDonnell A, Nitzsche A, Alexandrou A, Saintot PP , et al.
Science translational medicine

In common with other chronic pain conditions, there is an unmet clinical need in the treatment of inherited erythromelalgia (IEM). TheSCN9Agene encoding the sodium channel Nav1.7 expressed in the peripheral nervous system plays a critical role in IEM. A gain-of-function mutation in this sodium channel leads to aberrant sensory neuronal activity and extreme pain, particularly in response to heat. Five patients with IEM were treated with a new potent and selective compound that blocked the Nav1.7 sodium channel resulting in a decrease in heat-induced pain in most of the patients. We derived induced pluripotent stem cell (iPSC) lines from four of five subjects and produced sensory neurons that emulated the clinical phenotype of hyperexcitability and aberrant responses to heat stimuli. When we compared the severity of the clinical phenotype with the hyperexcitability of the iPSC-derived sensory neurons, we saw a trend toward a correlation for individual mutations. The in vitro IEM phenotype was sensitive to Nav1.7 blockers, including the clinical test agent. Given the importance of peripherally expressed sodium channels in many pain conditions, our approach may have broader utility for a wide range of pain and sensory conditions.

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