Abstract
Background
Some variables have been proposed as predictors of efficacy of OnabotulinumtoxinA in chronic migraine patients, but data available are inconclusive. We aimed to analyse the influence of single nucleotide polymorphisms in the response to OnabotulinumtoxinA.
Methods
We included 156 female patients treated with OnabotulinumtoxinA accordingly to PREEMPT paradigm in three headache units. OnabotulinumtoxinA was offered to patients that had not responded to topiramate and at least one other preventative. Age at first procedure was 43.7 ± 11.8 years (16–74). Patients with a reduction of at least 50% in the number of migraine days after two OnabotulinumtoxinA procedures were considered as responders. We analysed 25 polymorphisms selected for their relevance regarding migraine pathophysiology and their association with migraine according to previously published genome-wide association studies. Genotyping was performed using KASP probes and a LightCycler-480 (Roche-Diagnostics). Allelic, genotypic frequencies and dominance/recesivity hypothesis of the allelic variants were compared between responders and non-responders by Fisher’s exact test.
Results
Response to treatment with OnabotulinumtoxinA was achieved in 120 patients (76,9%). Two polymorphisms showed differences: CALCA rs3781719, where allele C represents 26.9% in responders and 40.9% in non-responders (p = 0.007, OR = 3.11 (1.33–7.26)); and TRPV1 rs222749, where allele A represents 4.17% in responders and 12.5% in non-responders (p = 0.013, OR = 3.29 (1.28–8.43)). No significant differences in rest of polymorphisms or clinical or demographic variables were found.
Conclusions
Polymorphic variations of CALCA and TRPV1 genes might play a role as prognostic markers of efficacy of OnabotulinumtoxinA in chronic migraine female patients in our population.
Keywords: CALCA gene, Chronic migraine, OnabotulinumtoxinA, Single nucleotide polymorphisms, TRPV1 gene
Background
Chronic migraine (CM) is a debilitating neurological disorder which affects approximately 2–3% of adults and is five times more frequent among female. The pathophysiology of migraine attacks is based on the activation of the trigeminovascular system and the liberation of vasoactive neuropeptides which cause meningeal inflammation and produce pain, such as the calcitonin gene related peptide (CGRP) [1].
OnabotulinumtoxinA (OnabotA) is considered a safe and effective therapy to manage CM, as was shown in the PREEMPT clinical program [2–5]. Also in a real-life clinical practice OnabotA pericranial injections effectively reduced headache and migraine days [5–11].
Molecular mechanism of action of OnabotA consists on cleaving SNAP-25 and, so, impairing intracellular vesicular fusion and down regulating release of pain related neuropeptides, such as glutamate, substance P or CGRP [12, 13]. In addition, OnabotA blocks the translocation of membrane receptors to the surface of sensory neurons, such as the Transient Receptor Potential Vanilloid 1 (TRPV1) [14]. Decreasing peripheral sensitization by all these mechanisms, OnabotA would finally indirectly inhibit central sensitization [15].
Genetics is considered a key factor for migraine susceptibility. Some genes have been postulated as responsible for the appearance of migraine. These are related to ion channel and neurotransmitter pathways (glutamate, GABA, dopamine, serotonin) [16], vascular functions (CGRP, MTHFR) [16, 17], hormonal mechanisms [16] and nociceptive system (like receptors of the transient receptor potential family or TRP) [18].
Up to date, many predictors of response to OnabotA in CM patients have been proposed. They have been mainly related with the mechanism of action of OnabotA (as plasma levels of CGRP) [19] and with parameters that might imply a loss of possibility of dechronification of migraine as age, time from onset of migraine or chronic migraine [20], or structural or functional changes in pain related brain structures [21]. Data regarding a possible influence of migraine characteristics (strictly unilateral location, implosive pain, the presence of cutaneous allodynia or pericranial tenderness) have shown inconclusive [22].
We aimed to analyse single nucleotide polymorphisms (SNPs) previously related with a possible susceptibility to migraine, and to determine their value as prognostic markers of efficacy, in a population of CM patients treated with OnabotA.
Methods
Patients and study design
A prospective, observational, multicentre study was conducted in which demographic and clinical data, along with biological samples, were collected from 156 female patients affected by CM between January 2014 and December 2015.
20 male patients were firstly included in the cohort but not analysed as we found this number too low for comparison.
The patients were recruited in the Headache Units of three Tertiary Hospitals: Hospital Clínico Universitario de Valladolid, Hospital Central de Asturias and Hospital Universitario de La Princesa. All of them were of Caucasian ethnicity and Spanish origin, and no siblings were included.
Written informed consent was obtained from all the patients to perform genetic analysis.
Scientific as well as ethical approvals were obtained from the Clinical Research Ethics Committee (CEIC) of East Valladolid Area (Hospital Clínico Universitario de Valladolid) as well as CEIC of Hospital La Princesa, according to the Declaration of Helsinki (1975). Patient anonymity and adherence to Data Protection Laws were maintained at all times.
CM was diagnosed accordingly to International Classification of Headache Disorders, III edition, beta version [23]. All patients included were eligible for treatment with OnabotA in accordance with the PREEMPT protocol. Exclusion criteria for the use of OnabotA were pregnancy, breastfeeding, and drug or alcohol abuse. We did not exclude medication overuse and our patients were allowed to continue with previous preventatives with no dose increasing.
License of OnabotA in Spain indicates its use “for patients who have not adequately responded or are intolerant to prophylactic drugs for migraine”. Inclusion criteria in our study considered patients previously treated with topiramate (or another neuromodulator in case of intolerance) and at least one other preventative (among beta-blockers or calcium antagonists) with no efficacy. Lack of response was evaluated after the administration of these drugs at adequate doses during at least 3 months, unless intolerance.
OnabotA was injected accordingly to PREEMPT protocol. The patients used a diary in order to record migraine and headache days and the days in which symptomatic medications were used. We also gathered time (years) from onset of migraines and time (months) from onset of chronic migraine. Response to treatment with OnabotA was evaluated 3 months after the second procedure and was defined as a reduction of at least 50% in the number of monthly migraine days.
We analysed 25 SNPs from each patient; they were selected for their relevance regarding migraine pathophysiology and their association with migraine according to previously published genome-wide association studies (GWAS). So, some polymorphisms were directly related to an increasing in the occurrence of migraine (MEF2D, MTHFR, MTDH, TRPV1 GABRQ, GABRE and GABRA3, this latter only in the case of female population), and others with processes that might be part of it: SLC1A2 were linked to the tendency to excessive use of symptomatic medication in migraine patients, GRIK3 with schizophrenia, which shares with migraine processes related to the glutamatergic system, and SCN9A, P2RX7 and KCNS1 with increased pain chronification [24–31].
Genes and SNPs studied as well as the change in DNA sequence (NM or NC), changes caused to proteins (NP), its OMIM reference number and the position of each gene in each chromosome are shown in Table 1.
Table 1.
GEN | SNP | NM | NP | OMIM | POSITION |
---|---|---|---|---|---|
Genes related to glutamate homeostasis | |||||
MEF2D | rs1050316 | NM_001271629.1:c.*2734C>A | – | 608320 | 15q26.3 |
LRP1 | rs11172113 | NM_002332.2:c.67+4469T>C | – | 190182 | 3p24.1 |
MTDH | rs1835740 | NC_000008.10:g.98166913 T > C | – | 610323 | 8q22.1 |
EAAT2 | rs4354668 | NM_001195728.2:c.-130+507A>C | – | 600300 | 11p13 |
GRIK3 | rs6691840 | NM_000831.3:c.928T>C | NP_000822.2:p.Ser310Ala | 138243 | 1p34.3 |
Gene which encodes for CGRP | |||||
CALCA | rs3781719 | NC_000021.8:g.22052312C>T | – | 114130 | 11p15.2 |
rs145837941 | NM_001033952.2:c.197 T > C | NP_001029124.1:p.Leu66Pro | |||
Genes of the GABA system | |||||
GABRE | rs1139916 | NM_004961.3:c.304T>G | NP_004952.2:p.Ser102Ala | 300093 | Xq28 |
GABRQ | rs3810651 | NM_018558.3:c.1432A | NP_061028.3:p.Ile478Phe | 300349 | |
GABRA3 | rs6627221 | NM_000808.3:c.551+8376A>G | – | 305660 | |
rs2201169 | NM_000808.3:c.262+23738T>C | – | |||
Genes which encode voltage dependant channels | |||||
SCN9A | rs6746030 | NM_002977.2:c.3448C | NP_002968.1:p.Arg1150, | 603415 | 2q24.3 |
KCNS1 | rs734784 | NM_002251.3:c.1465A>G | NP_002242.2:p.Ile489Val | 602905 | 20q13.12 |
P2RX7 | rs2230912 | NM_002562.5:c.1379A>G | NP_002553.3:p.Gln460Arg | 602566 | 12q24.31 |
rs1718119 | NM_002562.5:c.1042G>A | NP_002553.3:p.Ala348Thr | |||
Gene which encodes the D2 dopamine receptor | |||||
DRD2(ANKK1) | rs1800497 | NM_178510.1:c.2137G>A | NP_848605.1:p.Glu713Lys | 608,774 | 11q23.2 |
Gene of the 5-HT2C serotonin receptor | |||||
HTR2C | rs3813929 | NM_000868.2:c.-759C>T | – | 312861 | Xq23 |
Genes of the TRP family | |||||
TRPV1 | rs222749 | NM_018727.5:c.271C>T | NP_061197.4:p.Pro91Ser | 602076 | 17p13.2 |
rs222747 | NM_018727.5:c.945G>C | NP_061197.4:p.Met315Ile | |||
rs222741 | NM_080704.3:c.-34+2841C>T | – | |||
TRPV3 | rs7217270 | NM_001258205.1:c.2085+395T>C | – | 607066 | 17p13.2 |
TRPM8 | rs10166942 | NM_024080.4:c.-990T>C | – | 606678 | 2q37.1 |
Other genes studied | |||||
WFS1 | rs734312 | NM_001145853.1:c.1832G>A | NP_001139325.1:p.Arg611His | 606201 | 4p16.1 |
TGFBR2 | rs7640543 | NC_000003.11:g.30462403G > A | – | 190182 | 3p24.1 |
MTHFR | rs121434294 | NM_005957.4:c.547C > T | NP_005948.3:p.Arg183Ter | 607,093 | 1p36.3 |
Considering that this was the first study addressing the relationship between the variants and genes and OnabotA response, we estimated the sample size using the most similar study from a similar population [28]. We evaluated the highest possible variance (0.164) and the smallest possible difference in the proportions (0.15), with a type 1 error of 5% and a statistical power of 90%, with a possible attrition rate of 15%, with a minimum estimated sample size of 147 patients.
Sample collection and genotyping
Three mL of peripheral blood anticoagulated in EDTA-K3 were collected from each patient and from this was extracted the genomic DNA using the commercial kit “Ultra Clean® Blood DNA Isolation”, following the manufacturer’s protocol. The DNA obtained was quantified using the spectrophotometer NanoDrop ND1000 (Thermo Fisher Scientific, Inc.®) and genotyping was then carried out with KASP probes (Kompetitive Allele Specific PCR, KBioscience®) which are based on polymerase chain reaction (PCR) with the simultaneous use of two specific forward primers, each one of which differs in only one nucleotide so as to be able to recognise the two possibilities of alleles which exist in a point mutation or SNP.
The fluorescent emissions of the PCR product were measured at 37 °C in a LightCycler 480® (Roche Diagnostics). The absorbance measure determined the alleles (in homo or heterozygosis) according to the fluorescence emitted by the fluorophores FAM and/or HEX. The homozygotes emitted the signal of only one fluorophore and the heterozygotes of both.
Statistical analysis
Using the Fisher’s exact test, an assessment was made to see if the genotypic frequencies of each variant fulfilled the Hardy-Weinberg equilibrium.
Subgroups were established within the cohort of patients: responders and non-responders. We firstly analysed if clinical and demographic variables related with the response to OnabotA. We also searched for any differences between the groups in relation to any of the 25 SNPs for allelic, genotypic frequencies and dominance/recesivity hypothesis of the allelic variants. For this purpose, 3 × 2 contingency tables were used to analyse genotypic distribution and 2 × 2 contingency tables for the analysis of allele distribution and of allele dominance/recesivity, using the Fisher’s exact test.
The statistical analysis was carried out using version 20.0 of the IBM-SPSS programme for Windows. Values for p of less than 0.05 were considered to be statistically significant, taking into account the Bonferroni correction.
In all cases where a significant association was found, a binary logistic regression was performed, adjusting for age, in order to determine the possible influence of this variable in the signification found.
To estimate the risk derived from the significant differences, the Odds Ratio (OR) statistical measure was calculated with a 95% confidence interval. Thus, several comparisons were made for those which obtained a value of the odds ratio: for the allele of greater risk versus the allele of less risk and for risk according to three genetic models: dominant, codominant and recessive, using Bonferroni adjustment for multiplicity correction.
Results
Among the 156 patients included in the study, 91 (58.3%) were included in Valladolid, 10 (6.4%) in Madrid and 55 (35.3%) in Asturias. Age at inclusion was 43.7 ± 11.8 years.
Response to treatment with OnabotA was achieved in 120 patients (76.9%).
None of the demographic variables considered predict significantly response to OnabotA.
All of the variants analysed were found to be in Hardy-Weinberg Equilibrium except one. This exception was SNP rs222749, located on the gene TRPV1 (p = 0.00006).
Results regarding relationship between SNPs and response to OnabotA are shown in Appendices 1, 2.
Among the variables studied, after correction for multiple comparisons, there were two which showed significant differences between the groups of responders and non-responders.
Significant differences in SNP rs3781719 of the gene CALCA were found. Allele C represented 40.9% of non-responders and only 26.9% of responders (Table 2). For this SNP, the results of genotype determination in 7 samples were inconclusive, so the cohort consisted of 149 patients instead of 156.
Table 2.
P value | Odds ratio (95% CI) | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
POPULATION | RESPONSE | GENOTYPES | MINOR ALLELE FREQUENCY (%) | GENOTYPIC FREQUENCY | ALLELE FREQUENCY | ALLELE C RECESIVITY HYPOTHESIS | ALLELE C DOMINANCE HYPOTHESIS | Dominant model | Codominant model | Recessive model | ||
TT | TC | CC | ||||||||||
n = 150 | Responders (n = 117) | 63 | 45 | 9 | 26,9 | 0.023 | 0.029 | 0.794 | 0.007 | 3,11 (1,33-7,26) | 1,6 (0,85-3,0) | 1,2 (0,31-4,71) |
Non-responders (n = 33) | 9 | 21 | 3 | 40,9 |
Regarding the strength of association, the following values of Odds Ratio were obtained with confidence intervals of 95%: allele C related with a greater risk of non-response than allele T: [OR = 1.88 (1.06–3.32)] and, in relation to genetic models, the dominant model had a value of OR = 3.11 (1.33–7.26); the codominant model had a value of OR = 1.6 (0.85–3.00) and the recessive model had a value of OR = 1.2 (0.31–4.71).
The SNP rs222749 located on the gene TRPV1 also showed significant differences between the two groups. Allele A represented 12.5% in non-responders and 4.17% in the group of responders (Table 3).
Table 3.
P value | Odds ratio (95% CI) | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
POPULATION | RESPONSE | GENOTYPES | MINOR ALLELE FREQUENCY (%) | GENOTYPIC FREQUENCY | ALLELE FREQUENCY | ALLELE A RECESIVITY HYPOTHESIS | ALLELE A DOMINANCE HYPOTHESIS | Dominant model | Codominant model | Recessive model | ||
GG | GA | AA | ||||||||||
n = 156 | Responders (n = 120) | 111 | 8 | 1 | 4,2 | 0,040 | 0,021 | 0,013 | 0,102 | 2,47 (0,81-7,48) | 2,40 (0,80-7,24) | 10,82 (1,09-107,45) |
Non-responders (n = 36) | 30 | 3 | 3 | 12,5 |
Regarding the strength of association, the following values of Odds Ratio were obtained with confidence intervals of 95%: allele A related with a greater risk of non-response than allele G [OR = 3.29 (1.28–8.43)] and, in relation to genetic models, the dominant model had a value of OR = 2.47 (0.81–7.48); the codominant model had a value of OR = 2.40 (0.80–7.24) and the recessive model had a value of OR = 10.82 (1.09–107.45).
All the results were confirmed by age-adjusted logistic regression.
None of the clinical and demographic variables considered in our population predicted OnabotA response.
Discussion
Efficacy of OnabotA in CM patients in our series is comparable to recent “real-life” data [10].
There are lots of SNPs that have been associated with migraine in GWAS [24–31], and have been validated with other independent studies. These SNPs are located in genes related to migraine pathophysiology. So occurs with glutamate, the main excitatory neurotransmitter in the central nervous system (CNS) whose levels have been shown increased in the cerebrospinal fluid and serum of migraineurs. Another example is Gamma-Amino Butyric acid (GABA), the main inhibitory neurotransmitter in the CNS. Also with CGRP, a powerful vasodilator neuropeptide and mediator of neurogenic inflammation. Or with the methylene-tetrahydrofolate reductase (MTHFR) system and the angiotensin converting enzyme, both related to vascular disorders. Others genes considered are related with voltage dependent channels involved in nociceptive signalling, with neurotransmitters such as dopamine or serotonin and with receptors of the transient receptor potential family (TRP) which are expressed in the nociceptive neurons of the trigeminal nerve and whose activation leads to the release of CGRP [16, 18, 32, 33].
There are no many studies considering pharmacogenetics of migraine. Most of them have explored predictors of response of migraine attacks to triptans. So, polymorphisms related to triptan metabolizing enzymes (monoamine oxidase A, CYP3A4, CYP1A2 [34], COMT [35]) to serotonin (5-HT1B) and dopamine (DRD2) receptors [36] and to the serotonin transporter gene SLC6A4 [37] have been explored as possible predictors or response to triptans in episodic migraine patients.
Considering preventive therapies, certain mitochondrial DNA haplogroups showed influence in response to riboflavin in migraine patients [38]. Nevertheless, to the best of our knowledge, no previous study has addressed the relationship between the variants and genes included in this study and response to OnabotA.
The relationship between an SNP and a particular phenotype is more consistent when sample size is large, when the gene is located in a related area of genetic linkage (for example in the case of migraine in an area related to pain response) or if the relationship has been demonstrated in animal models [39]. Given the scarcity of individuals suffering from CM who are resistant to preventive oral treatment or OnabotA injection, and especially the low frequency of some haplotypes, the sample size used in this study might be considered as small. Hence, the significant results should be considered with caution even though the same level of significance might be found in other similar groups involved in other independent studies that might validate the findings. It is also important that the subjects being compared here belong to the same ethnic group. In our study, all the patients were of Caucasian ethnicity and of Spanish origin.
Furthermore, the SNPs variant should modify the regulation of the gene (SNP promoter) or its primary structure (SNP exon). Although certain genes can, by themselves, be related to patients having a greater susceptibility to suffer migraine, it sometimes occurs that they are reflecting what is happening in a neighbouring gene, since many alleles segregate themselves in bloc forming haplotypes within which are found several genes. The protein related to such a gene must be implicated in the pathogenesis of the illness. The genes being studied must be selected according to the evidence that there is a probability of association with the illness, on the basis of previous studies which support the relationship between those genes and the pathogenesis of the illness (studies in animal models, in illnesses where there is a familial tendency, etc.) [40]. That was we have tried to do in our design.
The definition of the phenotype of the illness and of its development should be sufficiently homogeneous or serious in patients to make comparison possible. In this case, patients included were diagnosed of CM accordingly to the ICHD-III beta [23] and resistance to previous oral preventatives was clearly defined.
As far as the handling of samples is concerned, it must be meticulous, since a percentage of error in this type of study on the scale of 1–3% has been described, leading to the drawing of false conclusions [41]. To avoid errors from the contamination of samples, sterility measures should be maximised. Also, in the process of genotyping, white control wells and empty control wells were used; repeating the genetic analysis was considered when the degree of allele discrimination was not clear, or not including the results where they were inconclusive as it happened with 7 samples regarding CALCA gen in our study.
Migraine, as other pain disorders, is more prevalent in females. Multiple phenotype differences between male and female migraine have been described. Symptoms as allodynia, response to triptans or preventatives, psychiatric comorbidities, and even brain structures or functional connectivity showed sex differences in migraine [42]. This heterogeneity provides us the opportunity to sub-classify our population and develop a genetic analysis considering only the female sub-population as we have done in this study.
All the variables considered were in Hardy-Weinberg equilibrium except one which deviated from it with a significance of p = 0.00006. The SNP in question was rs222749, located on the TRPV1 gene. The lack of equilibrium in the hardy-Weinberg law can be explained either by the small sample size, in which there are very infrequent haplotypes, or by the existence of selection bias. The latter situation is produced when there is a close relationship between the selection criterion, in our case CM, and the SNP. The results relating to whether this variant is a cause of CM are not completely conclusive and so it may be argued that the disequilibrium is due to a very low frequency of one of the alleles (only 4 homozygous patients in our population). However, although there is no literature about the implication of TRPV1 in chronic migraine, this gene has been widely studied like an important molecular player in chronic pain states, like chronic migraine [43].
The SNP rs3781719 c.-767 T > C of the CALCA gene showed significant differences between the group of responders and the group of non-responders to OnabotA. All of the analyses were statistically significant, particularly the hypothesis of dominance of the allele C (p = 0.007), whose presence, not only as homozygous but also as heterozygous, impedes the response to OnabotA. The CALCA gene encodes for the peptide CGRP, whose involvement in migraine has been studied widely [44]. CGRP levels have been proposed as a marker of migraine, mainly of chronic migraine [45, 46]. When OnabotA is used in CM patients, a decreasing of interictal levels of CGRP have been shown [47]. Finally, the increased levels of CGRP have been proposed as predictors of efficacy of OnabotA therapy in these patients [19, 48].
Results of our study support the role of CGRP in the therapeutic response of CM and its usefulness as a biomarker or therapeutic target, especially taking into account that the position c.-767 T > C of SNP rs3781719, located in the promoter region 5-UTR, could alter the expression of the gene. Our data suggest a possible regulatory role of the response to OnabotA mediated by the CALCA gene.
The SNP rs222749 located on the gene TRPV1 also showed significant differences between the two groups. Allele A represents 4.17% of the responders, while in the group of non-responders it is 12.5%. This would support the hypothesis that OnabotA interferes with the response mediated by the TRPV1 receptor [14], encoded by that gene, and as a result impedes the release of neuropeptides implicated in pain, such as CGRP or substance P. The reduction of sensitivity to TRPV1 channels could be of interest to explain the effect of OnabotA as migraine preventative [49]. Thus, the patients with allele A in homozygous state would be more susceptible to the release of those neuropeptides.
In our study clinical and demographical variables considered did not correlate with response to OnabotA in CM patients. The series which showed correlation of time from onset of migraine and chronic migraine with good outcome included a quite larger number of patients than our study [20].
We did not consider if the presence of sympathetic or parasympathetic symptoms correlated with the genotype or if other parameters influenced the response. Future studies should explore this possible association in detail.
Conclusions
In conclusion, in this study, and for the first time, two genetic polymorphisms have been associated with the response to therapy with OnabotA in Chronic Migraine patients. These polymorphisms are situated on the CALCA and TRPV1 genes. However, the role of the SNPs identified has to be considered with caution and the results have to be validated by other independent studies.
Acknowledgements
Not applicable.
Funding
This study was supported by Allergan Inc. via an independent and unrestricted research grant. All authors met the ICMJE authorship criteria.
Availability of data and materials
The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.
Abbreviations
- CGRP
Calcitonine gene related peptide
- CM
Chronic migraine
- DNA
Deoxyribonucleic acid
- EDTA
Ethylenediaminetetraacetic acid
- GABA
Gamma-aminobutyric acid
- GWAS
Genome wide association studies
- MTHFR
Methylenetetrahydrofolatereductase
- OnabotA
Onabotulinumtoxin A
- SNPs
Single nucleotide polymorphisms
- TRP
Transient receptor potential action channel
Appendix
Table 4.
No (n) | Yes (n) | |
---|---|---|
rs145837941 (CALCA) | ||
AA | 18 | 63 |
AG | 0 | 0 |
GG | 0 | 0 |
rs1800497 (DRD2) | ||
AA | 1 | 2 |
AG | 7 | 25 |
GG | 15 | 38 |
rs2201169 (GABRA3) | ||
TT | 28 | 80 |
TC | 8 | 38 |
CC | 0 | 2 |
rs1139916 (GABRE) | ||
AA | 6 | 10 |
CA | 14 | 57 |
CC | 16 | 53 |
rs6691840 (GRIK3) | ||
AA | 23 | 66 |
AC | 13 | 43 |
CC | 0 | 9 |
rs734784 (KCNS1) | ||
GG | 8 | 29 |
GA | 14 | 56 |
AA | 13 | 34 |
rs1050316 (MEF2D) | ||
TT | 16 | 51 |
TG | 17 | 56 |
GG | 3 | 13 |
rs121434294 (MTHFR) | ||
CC | 19 | 68 |
CT | 0 | 0 |
TT | 0 | 0 |
rs2230912 (P2RX7) | ||
AA | 27 | 85 |
AG | 8 | 28 |
GG | 1 | 3 |
rs7640543 (TGFBR2) | ||
AA | 4 | 11 |
AG | 17 | 60 |
GG | 15 | 49 |
rs222741 (TRPV1) | ||
TT | 18 | 64 |
TC | 15 | 51 |
CC | 2 | 5 |
rs222749 (TRPV1) | ||
AA | 3 | 1 |
GA | 3 | 8 |
GG | 30 | 111 |
rs734312 (WFS1) | ||
AA | 12 | 34 |
AG | 14 | 55 |
GG | 9 | 31 |
rs3781719 (CALCA) | ||
TT | 9 | 63 |
TC | 21 | 45 |
CC | 3 | 9 |
rs4354668 (EAAT2) | ||
GG | 3 | 22 |
GT | 16 | 54 |
TT | 17 | 43 |
rs6627221 (GABRA3) | ||
CC | 1 | 3 |
CT | 8 | 44 |
TT | 27 | 73 |
rs3810651 (GABRQ) | ||
TT | 7 | 19 |
TA | 17 | 55 |
AA | 11 | 42 |
rs3813929_1732 (HTR2C) | ||
TT | 1 | 2 |
CT | 15 | 35 |
CC | 20 | 82 |
rs11172113 (LRP1) | ||
CC | 4 | 13 |
CT | 18 | 49 |
TT | 14 | 58 |
rs1835740 (MTDH) | ||
GG | 24 | 73 |
GA | 10 | 43 |
AA | 2 | 4 |
rs1718119 (P2RX7) | ||
TT | 3 | 17 |
TC | 16 | 47 |
CC | 17 | 55 |
rs6746030 (SCN9A) | ||
GG | 29 | 88 |
AG | 6 | 30 |
AA | 1 | 1 |
rs10166942 (TRPM8) | ||
TT | 25 | 85 |
TC | 9 | 32 |
CC | 2 | 3 |
rs222747 (TRPV1) | ||
GG | 21 | 70 |
GC | 12 | 43 |
CC | 3 | 6 |
rs7217270 (TRPV3) | ||
AA | 9 | 21 |
AG | 16 | 54 |
GG | 11 | 45 |
Table 5.
FAMILY | GENE | SNP | p | ||||
---|---|---|---|---|---|---|---|
CHANGE | ANALYSIS BY PHENOTYPE |
ALLELE FREQUENCY |
ALLELE VARIANT RECESIVITY HYPOTHESIS | ALLELE VARIANT DOMINANCE HYPOTHESIS | |||
Genes related to glutamate homeostasis | MEF2D | rs1050316 | G > T | 0.907 | 0.729 | 0.836 | 0.665 |
LRP1 | rs11172113 | T > C | 0.583 | 0.439 | 0.963 | 0.319 | |
MTDH | rs1835740 | A > G | 0.596 | 0.740 | 0.527 | 0.543 | |
EAAT2 | rs4354668 | T > G | 0.266 | 0.105 | 0.147 | 0.231 | |
GRIK3 | rs6691840 | A > C | 0.218 | 0.176 | 0.088 | 0.397 | |
CGRP | CALCA | rs3781719 | T > C | 0.023 | 0.029 | 0.794 | 0.007 |
rs145837941 | A > G | – | – | – | – | ||
GABA Receptor system |
GABRE | rs1139916 | A > C | 0.312 | 0.522 | 0.977 | 0.148 |
GABRQ | rs3810651 | A > T | 0.824 | 0.532 | 0.619 | 0.604 | |
GABRA3 | rs6627221 | T > C | 0.271 | 0.190 | 0.977 | 0.074 | |
rs2201169 | T > C | 0.381 | 0.195 | 0.436 | 0.205 | ||
Voltage dependent channels | SCN9A | rs6746030 | G > A | 0.400 | 0.603 | 0.367 | 0.419 |
KCNS1 | rs734784 | A > G | 0.615 | 0.458 | 0.854 | 0.333 | |
P2RX7 | rs2230912 | A > G | 0.972 | 0.863 | 0.950 | 0.837 | |
rs1718119 | C > T | 0.628 | 0.584 | 0.351 | 0.916 | ||
Dopamine receptor | DRD2 | rs1800497 | C > T | 0.775 | 0.699 | 0.773 | 0.569 |
Serotoninergic receptor | HTR2C | rs3813929 | C > T | 0.332 | 0.163 | 0.675 | 0.139 |
TRPfamily | TRPV1 | rs222749 | G > A | 0.040 | 0.021 | 0.013 | 0.102 |
rs222747 | G > C | 0.749 | 0.740 | 0.459 | 0.958 | ||
rs222741 | C > T | 0.922 | 0.777 | 0.843 | 0.698 | ||
TRPV3 | rs7217270 | A > G | 0.553 | 0.275 | 0.446 | 0.317 | |
TRPM8 | rs10166942 | T > C | 0.656 | 0.655 | 0.361 | 0.873 | |
Others | WFS1 | rs734312 | G > A | 0.767 | 0.655 | 0.498 | 0.989 |
TGFBR2 | rs7640543 | G > A | 0.925 | 0.920 | 0.729 | 0.929 | |
MTHFR | rs121434294 | C > T | – | – | – | – |
Authors’ contributions
Conception and design: RMM, MR, JJT, ALG. Adquisition of data: MR, JP, MGS, IV, MS, ABGV, ALG. Analysis and interpretation of data: RMM, MR, IV, ECM, DGA, ALG. Drafting the manuscript: RMM, MR, ALG. Revising it for intelectual content: RMM, MR, JP, ABGV, DGA, ALG. Final approval of manuscript: All authors. Partially presented as an oral communication at the III Meeting of European Academy of Neurology, Amsterdam, June 2017. All authors read and approved the final manuscript.
Ethics approval and consent to participate
The study was approved by Clinical Research Ethics Committees (CEIC) of East Valladolid Area and Hospital Universitario de La Princesa.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
Publisher’s Note
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Contributor Information
R. Moreno-Mayordomo, Email: morenomayordomo@gmail.com
M. Ruiz, Email: ruizp.marina@gmail.com
J. Pascual, Email: juliopascualgomez@gmail.com
M. Gallego de la Sacristana, Email: merche_gs5@hotmail.com
I. Vidriales, Email: mividriales@saludcastillayleon.es
M. Sobrado, Email: sobrado.m@gmail.com
E. Cernuda-Morollon, Email: e.cernudamorollon@hotmail.es
A. B. Gago-Veiga, Email: dra.anagago@gmail.com
D. Garcia-Azorin, Email: davilink@hotmail.com
J. J. Telleria, Email: juanjose.telleria@uva.es
A. L. Guerrero, Email: gueneurol@gmail.com
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Data Availability Statement
The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.