Lindsey P

University of Tennessee Health Science Center

EM Publications

h-index

(2,193 citations, 111 total works)

Research Topics

Ion channel regulation and function (26) Ion Transport and Channel Regulation (20) Mitochondrial Function and Pathology (14) Pain Mechanisms and Treatments (9) Cardiac electrophysiology and arrhythmias (8)

Erythromelalgia Publications

Yield of peripheral sodium channels gene screening in pure small fibre neuropathy.

Eijkenboom I, Sopacua M, Hoeijmakers JGJ, de Greef BTA, Lindsey P , et al.

Journal of neurology, neurosurgery, and psychiatry • 2019-Mar-01

Neuropathic pain is common in peripheral neuropathy. Recent genetic studies have linked pathogenic voltage-gated sodium channel (VGSC) variants to human pain disorders. Our aims are to determine the frequency of , and variants in patients with pure small fibre neuropathy (SFN), analyse their clinical features and provide a rationale for genetic screening. Between September 2009 and January 2017, 1139 patients diagnosed with pure SFN at our reference centre were screened for , and variants. Pathogenicity of variants was classified according to established guidelines of the Association for Clinical Genetic Science and frequencies were determined. Patients with SFN were grouped according to the VGSC variants detected, and clinical features were compared. Among 1139 patients with SFN, 132 (11.6%) patients harboured 73 different (potentially) pathogenic VGSC variants, of which 50 were novel and 22 were found in ≥ 1 patient. The frequency of (potentially) pathogenic variants was 5.1% (n=58/1139) for 3.7% (n=42/1139) for and 2.9% (n=33/1139) for . Only erythromelalgia-like symptoms and warmth-induced pain were significantly more common in patients harbouring VGSC variants. (Potentially) pathogenic VGSC variants are present in 11.6% of patients with pure SFN. Therefore, genetic screening of and should be considered in patients with pure SFN, independently of clinical features or underlying conditions.

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Network topology of NaV1.7 mutations in sodium channel-related painful disorders.

Kapetis D, Sassone J, Yang Y, Galbardi B, Xenakis MN , et al.

BMC systems biology • 2017-Feb-24

Gain-of-function mutations in SCN9A gene that encodes the voltage-gated sodium channel NaV1.7 have been associated with a wide spectrum of painful syndromes in humans including inherited erythromelalgia, paroxysmal extreme pain disorder and small fibre neuropathy. These mutations change the biophysical properties of NaV1.7 channels leading to hyperexcitability of dorsal root ganglion nociceptors and pain symptoms. There is a need for better understanding of how gain-of-function mutations alter the atomic structure of Nav1.7. We used homology modeling to build an atomic model of NaV1.7 and a network-based theoretical approach, which can predict interatomic interactions and connectivity arrangements, to investigate how pain-related NaV1.7 mutations may alter specific interatomic bonds and cause connectivity rearrangement, compared to benign variants and polymorphisms. For each amino acid substitution, we calculated the topological parameters betweenness centrality (B ), degree (D), clustering coefficient (CC ), closeness (C ), and eccentricity (E ), and calculated their variation (Δ = mutant -WT ). Pathogenic NaV1.7 mutations showed significantly higher variation of |ΔB | compared to benign variants and polymorphisms. Using the cut-off value ±0.26 calculated by receiver operating curve analysis, we found that ΔB correctly differentiated pathogenic NaV1.7 mutations from variants not causing biophysical abnormalities (nABN) and homologous SNPs (hSNPs) with 76% sensitivity and 83% specificity. Our in-silico analyses predict that pain-related pathogenic NaV1.7 mutations may affect the network topological properties of the protein and suggest |ΔB | value as a potential in-silico marker.

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