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

Dimos Kapetis; Jenny Sassone; Yang Yang; Barbara Galbardi; Markos N. Xenakis; Ronald L. Westra; Radek Szklarczyk; Patrick Lindsey; Catharina G. Faber; Monique Gerrits; Ingemar S. J. Merkies; Sulayman D. Dib-Hajj; Massimo Mantegazza; Stephen G. Waxman; PROPANE Study Grp; Hubertus J.M. Smeets; Giuseppe Lauria

doi:10.1186/s12918-016-0382-0

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

Dimos Kapetis^*, Jenny Sassone, Yang Yang, Barbara Galbardi, Markos N. Xenakis, Ronald L. Westra, Radek Szklarczyk, Patrick Lindsey, Catharina G. Faber, Monique Gerrits, Ingemar S. J. Merkies, Sulayman D. Dib-Hajj, Massimo Mantegazza, Stephen G. Waxman, PROPANE Study Grp, Hubertus J.M. Smeets, Giuseppe Lauria

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Background: 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.

Results: 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-ct), degree (D), clustering coefficient (CCct), closeness (C-ct), and eccentricity (E-ct), and calculated their variation (Delta(value) = mutant (value)-WT (value)). Pathogenic NaV1.7 mutations showed significantly higher variation of |Delta B-ct| compared to benign variants and polymorphisms. Using the cut-off value +/- 0.26 calculated by receiver operating curve analysis, we found that Delta B-ct correctly differentiated pathogenic NaV1.7 mutations from variants not causing biophysical abnormalities (nABN) and homologous SNPs (hSNPs) with 76% sensitivity and 83% specificity.

Conclusions: Our in-silico analyses predict that pain-related pathogenic NaV1.7 mutations may affect the network topological properties of the protein and suggest |Delta B-ct| value as a potential in-silico marker.

Original language	English
Article number	28
Number of pages	16
Journal	BMC Systems Biology
Volume	11
DOIs	https://doi.org/10.1186/s12918-016-0382-0
Publication status	Published - 24 Feb 2017

Keywords

Sodium channel
Neuropathic pain
Structural modeling
Network analysis
TRANSFER-RNA SYNTHETASE
MOLECULAR-DYNAMICS SIMULATIONS
OF-FUNCTION MUTATIONS
NA(V)1.7 MUTATION
PRIMARY ERYTHERMALGIA
ELECTROPHYSIOLOGICAL PROPERTIES
RESPONSIVE ERYTHROMELALGIA
NEURON HYPEREXCITABILITY
STRUCTURE PREDICTION
SLOW-INACTIVATION

Access to Document

10.1186/s12918-016-0382-0Licence: CC BY

Cite this

Kapetis, D., Sassone, J., Yang, Y., Galbardi, B., Xenakis, M. N., Westra, R. L., Szklarczyk, R., Lindsey, P., Faber, C. G., Gerrits, M., Merkies, I. S. J., Dib-Hajj, S. D., Mantegazza, M., Waxman, S. G., PROPANE Study Grp, J.M. Smeets, H., & Lauria, G. (2017). Network topology of NaV1.7 mutations in sodium channel-related painful disorders. BMC Systems Biology, 11, Article 28. https://doi.org/10.1186/s12918-016-0382-0

@article{fe2c6894f235471abdcc0fcc4906ecac,

title = "Network topology of NaV1.7 mutations in sodium channel-related painful disorders",

abstract = "Background: 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.Results: 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-ct), degree (D), clustering coefficient (CCct), closeness (C-ct), and eccentricity (E-ct), and calculated their variation (Delta(value) = mutant (value)-WT (value)). Pathogenic NaV1.7 mutations showed significantly higher variation of |Delta B-ct| compared to benign variants and polymorphisms. Using the cut-off value +/- 0.26 calculated by receiver operating curve analysis, we found that Delta B-ct correctly differentiated pathogenic NaV1.7 mutations from variants not causing biophysical abnormalities (nABN) and homologous SNPs (hSNPs) with 76% sensitivity and 83% specificity.Conclusions: Our in-silico analyses predict that pain-related pathogenic NaV1.7 mutations may affect the network topological properties of the protein and suggest |Delta B-ct| value as a potential in-silico marker.",

keywords = "Sodium channel, Neuropathic pain, Structural modeling, Network analysis, TRANSFER-RNA SYNTHETASE, MOLECULAR-DYNAMICS SIMULATIONS, OF-FUNCTION MUTATIONS, NA(V)1.7 MUTATION, PRIMARY ERYTHERMALGIA, ELECTROPHYSIOLOGICAL PROPERTIES, RESPONSIVE ERYTHROMELALGIA, NEURON HYPEREXCITABILITY, STRUCTURE PREDICTION, SLOW-INACTIVATION",

author = "Dimos Kapetis and Jenny Sassone and Yang Yang and Barbara Galbardi and Xenakis, {Markos N.} and Westra, {Ronald L.} and Radek Szklarczyk and Patrick Lindsey and Faber, {Catharina G.} and Monique Gerrits and Merkies, {Ingemar S. J.} and Dib-Hajj, {Sulayman D.} and Massimo Mantegazza and Waxman, {Stephen G.} and {PROPANE Study Grp} and {J.M. Smeets}, Hubertus and Giuseppe Lauria",

year = "2017",

month = feb,

day = "24",

doi = "10.1186/s12918-016-0382-0",

language = "English",

volume = "11",

journal = "BMC Systems Biology",

issn = "1752-0509",

publisher = "BioMed Central Ltd",

}

Kapetis, D, Sassone, J, Yang, Y, Galbardi, B, Xenakis, MN, Westra, RL , Szklarczyk, R , Lindsey, P , Faber, CG , Gerrits, M, Merkies, ISJ, Dib-Hajj, SD, Mantegazza, M, Waxman, SG, PROPANE Study Grp, J.M. Smeets, H & Lauria, G 2017, 'Network topology of NaV1.7 mutations in sodium channel-related painful disorders', BMC Systems Biology, vol. 11, 28. https://doi.org/10.1186/s12918-016-0382-0

TY - JOUR

T1 - Network topology of NaV1.7 mutations in sodium channel-related painful disorders

AU - Kapetis, Dimos

AU - Sassone, Jenny

AU - Yang, Yang

AU - Galbardi, Barbara

AU - Xenakis, Markos N.

AU - Westra, Ronald L.

AU - Szklarczyk, Radek

AU - Lindsey, Patrick

AU - Faber, Catharina G.

AU - Gerrits, Monique

AU - Merkies, Ingemar S. J.

AU - Dib-Hajj, Sulayman D.

AU - Mantegazza, Massimo

AU - Waxman, Stephen G.

AU - PROPANE Study Grp

AU - J.M. Smeets, Hubertus

AU - Lauria, Giuseppe

PY - 2017/2/24

Y1 - 2017/2/24

N2 - Background: 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.Results: 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-ct), degree (D), clustering coefficient (CCct), closeness (C-ct), and eccentricity (E-ct), and calculated their variation (Delta(value) = mutant (value)-WT (value)). Pathogenic NaV1.7 mutations showed significantly higher variation of |Delta B-ct| compared to benign variants and polymorphisms. Using the cut-off value +/- 0.26 calculated by receiver operating curve analysis, we found that Delta B-ct correctly differentiated pathogenic NaV1.7 mutations from variants not causing biophysical abnormalities (nABN) and homologous SNPs (hSNPs) with 76% sensitivity and 83% specificity.Conclusions: Our in-silico analyses predict that pain-related pathogenic NaV1.7 mutations may affect the network topological properties of the protein and suggest |Delta B-ct| value as a potential in-silico marker.

AB - Background: 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.Results: 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-ct), degree (D), clustering coefficient (CCct), closeness (C-ct), and eccentricity (E-ct), and calculated their variation (Delta(value) = mutant (value)-WT (value)). Pathogenic NaV1.7 mutations showed significantly higher variation of |Delta B-ct| compared to benign variants and polymorphisms. Using the cut-off value +/- 0.26 calculated by receiver operating curve analysis, we found that Delta B-ct correctly differentiated pathogenic NaV1.7 mutations from variants not causing biophysical abnormalities (nABN) and homologous SNPs (hSNPs) with 76% sensitivity and 83% specificity.Conclusions: Our in-silico analyses predict that pain-related pathogenic NaV1.7 mutations may affect the network topological properties of the protein and suggest |Delta B-ct| value as a potential in-silico marker.

KW - Sodium channel

KW - Neuropathic pain

KW - Structural modeling

KW - Network analysis

KW - TRANSFER-RNA SYNTHETASE

KW - MOLECULAR-DYNAMICS SIMULATIONS

KW - OF-FUNCTION MUTATIONS

KW - NA(V)1.7 MUTATION

KW - PRIMARY ERYTHERMALGIA

KW - ELECTROPHYSIOLOGICAL PROPERTIES

KW - RESPONSIVE ERYTHROMELALGIA

KW - NEURON HYPEREXCITABILITY

KW - STRUCTURE PREDICTION

KW - SLOW-INACTIVATION

U2 - 10.1186/s12918-016-0382-0

DO - 10.1186/s12918-016-0382-0

M3 - Article

C2 - 28235406

SN - 1752-0509

VL - 11

JO - BMC Systems Biology

JF - BMC Systems Biology

M1 - 28

ER -