A gain-of-function sodium channel β2-subunit mutation in painful diabetic neuropathy.
Matthew AlsaloumMark EstacionRowida AlmomaniMonique M GerritsGidon J BönhofDan ZieglerRayaz MalikMaryam FerdousiGiuseppe LauriaIngemar Sj MerkiesCatharina G FaberSulayman Dib-HajjStephen G Waxmannull nullPublished in: Molecular pain (2020)
Diabetes mellitus is a global challenge with many diverse health sequelae, of which diabetic peripheral neuropathy is one of the most common. A substantial number of patients with diabetic peripheral neuropathy develop chronic pain, but the genetic and epigenetic factors that predispose diabetic peripheral neuropathy patients to develop neuropathic pain are poorly understood. Recent targeted genetic studies have identified mutations in α-subunits of voltage-gated sodium channels (Navs) in patients with painful diabetic peripheral neuropathy. Mutations in proteins that regulate trafficking or functional properties of Navs could expand the spectrum of patients with Nav-related peripheral neuropathies. The auxiliary sodium channel β-subunits (β1-4) have been reported to increase current density, alter inactivation kinetics, and modulate subcellular localization of Nav. Mutations in β-subunits have been associated with several diseases, including epilepsy, cancer, and diseases of the cardiac conducting system. However, mutations in β-subunits have never been shown previously to contribute to neuropathic pain. We report here a patient with painful diabetic peripheral neuropathy and negative genetic screening for mutations in SCN9A, SCN10A, and SCN11A-genes encoding sodium channel α-subunit that have been previously linked to the development of neuropathic pain. Genetic analysis revealed an aspartic acid to asparagine mutation, D109N, in the β2-subunit. Functional analysis using current-clamp revealed that the β2-D109N rendered dorsal root ganglion neurons hyperexcitable, especially in response to repetitive stimulation. Underlying the hyperexcitability induced by the β2-subunit mutation, as evidenced by voltage-clamp analysis, we found a depolarizing shift in the voltage dependence of Nav1.7 fast inactivation and reduced use-dependent inhibition of the Nav1.7 channel.
Keyphrases
- neuropathic pain
- spinal cord
- spinal cord injury
- type diabetes
- wound healing
- chronic pain
- genome wide
- healthcare
- public health
- mental health
- end stage renal disease
- ejection fraction
- dna methylation
- chronic kidney disease
- risk assessment
- gene expression
- protein kinase
- single cell
- heart failure
- papillary thyroid
- patient reported outcomes
- young adults
- pain management
- squamous cell carcinoma
- high frequency
- health information
- optical coherence tomography
- lymph node metastasis
- atrial fibrillation
- childhood cancer
- weight loss
- prognostic factors