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. 2018 Apr 14;22(7):3377–3387. doi: 10.1111/jcmm.13612

Common genetic variants in GAL, GAP43 and NRSN1 and interaction networks confer susceptibility to Hirschsprung disease

Yang Wang 1,2,3, Weihui Yan 1,2,3, Jun Wang 1,2,3, Ying Zhou 1,2,3, Jie Chen 1,2,3, Beilin Gu 1,2,3, Wei Cai 1,2,3,
PMCID: PMC6010875  PMID: 29654647

Abstract

Hirschsprung disease (HSCR) is a severe multifactorial genetic disorder. Microarray studies indicated GAL,GAP43 and NRSN1 might contribute to the altered risk in HSCR. Thus, we focused on genetic variations in GAL,GAP43 and NRSN1, and the gene‐gene interactions involved in HSCR susceptibility. We recruited a strategy combining case‐control study and MassArray system with interaction network analysis. For GAL,GAP43 and NRSN1, a total of 18 polymorphisms were assessed in 104 subjects with sporadic HSCR and 151 controls of Han Chinese origin. We found statistically significant differences between HSCR and control groups at 5 genetic variants. For each gene, the haplotypes combining all polymorphisms were the most significant. Based on SNPsyn, MDR and GeneMANIA analyses, we observed significant gene‐gene interactions among GAL,GAP43,NRSN1 and our previous identified RELN,GABRG2 and PTCH1. Our study for the first time indicates that genetic variants within GAL,GAP43 and NRSN1 and related gene‐gene interaction networks might be involved in the altered susceptibility to HSCR in the Han Chinese population, which might shed more light on HSCR pathogenesis.

Keywords: GAL, GAP43, Han Chinese, Hirschsprung disease, interaction networks, MassArray, NRSN1

1. INTRODUCTION

Hirschsprung disease (HSCR) is a complex genetic disorder caused by congenital defect of the enteric nervous system (ENS) which is derived from neural crest cells (NCCs). HSCR affects approximately 1/5000 live births worldwide, and the highest incidence was observed in Asian population (2.8/10 000 live births).1 Based on the extent of aganglionosis, the HSCR cases can be anatomically categorized into three subtypes: short segment HSCR (S‐HSCR, 80% of cases) in which the aganglionic segment does not extend beyond the upper sigmoid, long segment HSCR (L‐HSCR, 15% of cases) and total colonic aganglionosis (TCA, 5% of cases).2 Importantly, HSCR shows a dramatic sex bias with at least 4 times more males affected than females in S‐HSCR (male:female ≈ 1:1 in L‐HSCR) for causes that remain unclear.3

Genetic factors or multiple gene interactions are crucial to the development of Hirschsprung disease as HSCR is a non‐Mendelian disorder in nature with low sex‐dependent penetrance and interfamilial variation.4 It has been suggested that there are variations in penetrance and severity of aganglionosis between family members bearing mutations in HSCR genes.5 Obviously, only a single homozygous null mutation of HSCR‐related genes is insufficient to cause serious aganglionosis phenotype in HSCR.3 Genetic variants of at least 15 genes so far have been implicated in HSCR aetiology, including RET (receptor tyrosine kinase), one of the major HSCR susceptibility genes,6, 7 whereas only ~ 0.1% of the heritability in HSCR can be attributed to the mutations in these genes that account for about 50% of familial and 7%‐35% of sporadic HSCR cases,8 indicating more genes that might be involved in HSCR development.

On the other hand, recent genomewide association studies have revealed dozens of novel HSCR genes, which may facilitate the description of a complete landscape of genetic networks in HSCR. Taking advantage of whole exome sequencing, several genes, including DENND3, FAT3 and AGL, were linked to HSCR pathogenesis.9, 10, 11 NRG3 has recently been proved to be a new HSCR risk gene based on exome sequencing and genomewide copy number analysis,2, 12 which was further confirmed by our previous work.13 In addition, genomewide association studies on HSCR trios and sporadic cases have uncovered the class 3 semaphorin gene cluster and certain large‐scale chromosomal aberrations regarding HSCR aetiology.14, 15 Recent genomewide microarray analysis has reported the levels of GAL (galanin), GAP43 (growth‐associated protein 43) and NRSN1 (neurensin 1) were significantly down‐regulated in HSCR cases when compared to controls, indicating the possibility that all 3 genes might be associated with HSCR risk.16

More importantly, joint gene‐gene effects, such as RET and PHOX2B genes, might have a crucial impact on the development of HSCR.17 Our previous study has proved the interactions among GABRG2, RELN and PTCH1 may contribute to altered susceptibility to HSCR.13 Additionally, galanin‐expressing GABA neurons in the lateral hypothalamus may have important implications for treatment strategies of psychiatric disorders.18 In Ptch1 (+/−) mice that causes aberrant hedgehog signalling, reduced Gap43 expression leads to the Nos2‐mediated medulloblastoma development.19 Recently, it has been demonstrated that reelin blockade results in decreased levels of phospho‐GAP43 in the superior colliculus, suggesting the interaction of reelin signalling and phospho‐GAP43 might be involved in the development of neural circuits.20 With all these lines of evidence and results, we aimed to explore whether genetic variants within GAL, GAP43 and NRSN1 might contribute to the altered susceptibility to HSCR, and based on the 18 polymorphisms involved in this study (Figure 1A), we further assessed the interaction relationship among GAL, GAP43, NRSN1 and our previous identified GABRG2, RELN and PTCH1 genes.

Figure 1.

Figure 1

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Distribution and representative mass spectra of the genetic variants in the present study. A‐C, The 18 genetic variants distributed in GAL, GAP43 and NRSN1. Red lines indicate the studied SNPs; blue lines and arrows represent the exons located in theGAL, GAP43 and NRSN1; D, Representative mass spectra of the 8 polymorphisms in GAP43. Blue dotted lines indicate the presence of the studied alleles; red dotted lines represent no allele detected; grey dotted lines denote the unrelated peaks

2. MATERIALS AND METHODS

2.1. Subjects

The subject group involved in this study consisted of 104 cases with HSCR (84 male and 20 female) and 151 normal controls (86 male and 65 female). The mean ages of HSCR group and control group were 1.14 ± 1.83 years and 1.66 ± 1.05 years. The characteristics of the study subjects can be found in our previous study.21 All the participants in the study were of Han Chinese origin and were recruited from the residents who were biologically unrelated. Diagnosis of HSCR was confirmed by the histological examination of either surgical resection material or biopsy for the absence of ganglion cells. The HSCR group included 86 subjects of S‐HSCR (short segment HSCR), 15 subjects of L‐HSCR (long segment HSCR) and 3 subjects of TCA (total colonic aganglionosis). Controls were randomly enrolled from the subjects with no history of chronic constipation. The protocol of our study was reviewed and approved by the ethics committee of Xin Hua Hospital. Informed consent was obtained from parents of all participants after the procedure had been fully explained. All experiments were conducted in accordance with the tenets of the Declaration of Helsinki. DNA extraction was performed according to standard procedures with QIAamp DNA blood midi kit (Qiagen, Valencia, CA).

2.2. SNP selection

The tagSNP selection was conducted using the Haploview software (Version 4.2) with MAF (minor allele frequency) ≥ 0.1 and r ≥ 0.8 according to the Han Chinese in Beijing (HCB) population's SNP data from the HapMap database. In regard to HCB population, we have very few choices for cSNPs (coding SNPs) and UTR SNPs because of the unavailability of allele frequency data for many polymorphisms. In our present study, we enrolled 18 tagSNPs including 4 UTR SNPs (GAL: rs1042577; GAP43: rs14360; NRSN1: rs3829810 and rs3178) and 14 intronic SNPs (GAL: rs1546309, rs3136540 and rs3136541; GAP43: rs2028248, rs2118604, rs12632276, rs1370808, rs283369, rs2918079 and rs283367; NRSN1: rs4449613, rs6935378, rs4285310 and rs10946675) (Figure 1A).

2.3. Genotyping and quality control

Genotyping was carried out using the MassARRAY iPLEX Gold technology (Sequenom, San Diego, CA). Briefly, PCR and iPLEX single‐base extension primers (SBE) were designed taking advantage of the Assay Design Suite of Sequenom. The whole process consisted of the PCR amplification, the shrimp alkaline phosphatase (SAP) and the primer extension reactions using iPLEX Gold assay (Sequenom) that discriminates sequence differences at the single nucleotide level. Mass signals for the different alleles were captured by MALDI‐TOF‐based system with high accuracy. Raw data from the assays were processed with Typer Version 4.0 (Sequenom).

We recruited the following criteria as a measure of acceptable genotyping: (1) 30 sample duplicates and 4 blank wells were involved in each 384‐well plate; (2) concordance rate for the duplicates ≥ 99.5%; (3) call rate for the blank wells <5% in each 384‐well plate; (4) call rate > 95% for each 384‐well plate; and (5) overall call rate by individual or by marker > 95%. The data for any marker or individual failing the criteria were excluded from further analyses.

2.4. SNP‐SNP interaction analysis

In this study, SNPsyn (http://snpsyn.biolab.si)22 was employed to interrogate the SNP‐SNP interaction networks regarding HSCR. The genotyping data of the studied genetic variants were processed with the SNPsyn software tool, using which we uncovered the SNP‐SNP interaction networks and carried out the SNP pair selection that was mainly based on information gain (I), synergy (Syn) and false discovery rate (FDR).22, 23 Moreover, the multifactor dimensionality reduction (MDR) analysis was included to explore the gene‐gene interactions. We used the MDR software version 3.0.2 to perform the MDR analysis and identified all risk factors in the best model maximizing testing accuracy and cross‐validation consistency (CVC).24 We further recruited the GeneMANIA database, including co‐expression, co‐localization and genetic interaction datasets, to assess the gene‐gene interaction networks and to conduct a function prediction.25

2.5. Statistical analysis

We used SHEsis (http://analysis.bio-x.cn/myAnalysis.php) to calculate Hardy‐Weinberg equilibrium, allelic and genotypic association, odds ratio (OR) and 95% confidence interval (CI) and to estimate allelic distribution and linkage disequilibrium (LD).26D” was included as the standardized measure for all possible pairs of SNP loci. All the P values in this study were two‐tailed, and the significance level was set at = .05. Bonferroni correction was performed to correct the P values of genetic analysis, and Plink was enrolled to conduct the association analyses with dominant model and recessive model, and perform the adjustment for gender factor in the association analysis.27 Additionally, haplotype distribution was estimated using the program UNPHASED,28 and power calculations were conducted using the G*Power 3 program.29

3. RESULTS

In regard to the studied genetic variants, Hardy‐Weinberg equilibrium tests were conducted in HSCR group and control group, respectively. Allele and genotype frequencies of the 18 markers are listed in Tables 1, 2, 3. Genotype distributions were in Hardy‐Weinberg equilibrium for all 18 polymorphisms in either HSCR group or control group (> .05). Power calculations were conducted in regard to all 3 genes: (1) GAL, the power of rs1546309, rs3136540, rs3136541 and rs1042577 was of 0.749, 0.741, 0.765 and 0.775 (OR 1.5, 95% CI); (2) GAP43, the power of rs2028248, rs2118604, rs12632276, rs1370808, rs283369, rs2918079, rs283367 and rs14368 was of 0.804, 0.779, 0.785, 0.8, 0.802, 0.786, 0.799 and 0.787 (OR 1.5, 95% CI); (3) NRSN1, the power of rs4449613, rs6935378, rs4285310, rs10946675, rs3829810 and rs3178 was of 0.804, 0.805, 0.768, 0.788, 0.791 and 0.791 (OR 1.5, 95% CI). There were significant associations between HSCR and 5 genetic polymorphisms, including 1 GAL SNP (rs1042577), 2 GAP43 SNPs (rs283367 and rs14360) and 2 NRSN1 SNPs (rs10946675 and rs3829810). We also found the significance in allele distributions of the 5 positive SNPs and in genotype distributions of the 1 GAL SNP and 2 GAP43 SNPs remained after the Bonferroni correction. Moreover, all 5 positive SNPs were involved in the further analyses with dominant model (Dom) and recessive model (Rec), giving P values as following: (1) GAL_rs1042577, Dom = .001, Rec = .04; (2) GAP43_rs283367, Dom = .064, Rec = .001; (3) GAP43_rs14360, Dom = .001, RecP = 0.184; (4) NRSN1_rs10946675, Dom = .002, Rec = .237; and (5) NRSN1_rs3829810, Dom = .013, Rec = .049. PLINK was recruited in the adjustment for gender factor, and the findings in the 5 positive SNPs remained significant after correction. Figure 1B presents representative mass spectra of the original MassARRAY reactions in GAP43. Additionally, the frequencies of certain alleles and genotypes regarding the 5 positive markers were significantly higher in HSCR group compared to normal control group, such as the A allele and AA genotype of GAL rs1042577, the T allele and TT genotype of GAP43 rs283367, the G allele and GG genotype of GAP43 rs14360, the G allele and GG genotype of NRSN1 rs10946675, and the C allele and CC genotype of NRSN1 rs3829810.

Table 1.

Allele and genotype distributions of GAL among patients with HSCR and normal controls

SNP ID Chr (Pos) Genotype frequency (%) HWE check P valuea P valuea Bonferroni correction Allele frequency (%) X 2 P valuea Bonferroni correction Odds ratio (95% CI)
rs1546309 CC CT TT C T
Case 11 (68687214) 3 (3.0) 32 (32.0) 65 (65.0) .692 .158 >0.05 38 (19.0) 162 (81.0) 3.432 .064 >0.05 1.58 (0.97‐2.58)
Control 3 (2.0) 33 (21.9) 115 (76.2) .727 39 (12.9) 263 (87.1)
rs3136540 CC CT TT C T
Case 11 (68688942) 68 (67.3) 29 (28.7) 4 (4.0) .684 .242 >0.05 165 (81.7) 37 (18.3) 2.405 .121 >0.05 0.68 (0.42‐1.11)
Control 116 (76.8) 30 (19.9) 5 (3.3) .096 262 (86.8) 40 (13.2)
rs3136541 CC CT TT C T
Case 11 (68690475) 5 (4.9) 39 (37.9) 59 (57.3) .653 .173 >0.05 49 (23.8) 157 (76.2) 3.409 .065 >0.05 1.51 (0.97‐2.35)
Control 4 (2.7) 43 (28.9) 102 (68.5) .833 51 (17.1) 247 (82.9)
rs1042577 AA AG GG A G
Case 11 (68691002) 12 (11.9) 39 (38.6) 50 (49.5) .313 .003 0.014 63 (31.2) 139 (68.8) 12.666 3.75 × 10 −4 0.002 2.14 (1.40‐3.27)
Control 7 (4.8) 37 (25.3) 102 (69.9) .144 51 (17.5) 241 (82.5)
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SNP, single nucleotide polymorphism; Chr, chromosome; Pos, position; CI, confidence interval; HSCR, Hirschsprung disease; HWE, Hardy‐Weinberg equilibrium.

a

Pearson's P value; the significance level was set at P = .05.

Table 2.

Allele and genotype distributions of GAP43 among patients with HSCR and normal controls

SNP ID Chr (Pos) Genotype frequency (%) HWE check P valuea P valuea Bonferroni correction Allele frequency (%) X 2 P valuea Bonferroni correction Odds ratio (95% CI)
rs2028248 CC CT TT C T
Case 3 (115648119) 14 (14.0) 52 (52.0) 34 (34.0) .405 .632 >0.05 80 (40.0) 120 (60.0) 0.297 .586 >0.05 0.90 (0.63‐1.30)
Control 27 (18.5) 70 (47.9) 49 (33.6) .820 124 (42.5) 168 (57.5)
rs2118604 CC CG GG C G
Case 3 (115654882) 5 (4.8) 34 (32.7) 65 (62.5) .839 .275 >0.05 44 (21.2) 164 (78.8) 2.639 .104 >0.05 0.71 (0.47‐1.08)
Control 12 (7.9) 59 (39.1) 80 (53.0) .808 83 (27.5) 219 (72.5)
rs12632276 AA AG GG A G
Case 3 (115668013) 12 (11.9) 39 (38.6) 50 (49.5) .313 .317 >0.05 63 (31.2) 139 (68.8) 2.445 .118 >0.05 1.37 (0.92‐2.04)
Control 11 (7.4) 52 (34.9) 86 (57.7) .426 74 (24.8) 224 (75.2)
rs1370808 AA AG GG A G
Case 3 (115678938) 41 (40.6) 46 (45.5) 14 (13.9) .849 .221 >0.05 128 (63.4) 74 (36.6) 1.357 .102 >0.05 1.36 (0.94‐1.96)
Control 45 (30.2) 77 (51.7) 27 (18.1) .551 167 (56.0) 131 (44.0)
rs283369 CC CT TT C T
Case 3 (115685746) 33 (32.0) 51 (49.5) 19 (18.4) .928 .939 >0.05 117 (56.8) 89 (43.2) 0.020 .887 >0.05 0.97 (0.68‐1.40)
Control 47 (31.8) 76 (51.4) 25 (16.9) .541 170 (57.4) 126 (42.6)
rs2918079 AA AG GG A G
Case 3 (115700948) 51 (49.5) 42 (40.8) 10 (9.7) .754 .697 >0.05 144 (69.9) 62 (30.1) 0.099 .753 >0.05 1.06 (0.72‐1.57)
Control 74 (50.0) 55 (37.2) 19 (12.8) .094 203 (68.6) 93 (31.4)
rs283367 CC CT TT C T
Case 3 (115712360) 33 (32.0) 43 (41.7) 27 (26.2) .100 .004 0.035 109 (52.9) 97 (47.1) 9.365 .002 0.018 0.57 (0.39‐0.82)
Control 65 (43.6) 68 (45.6) 16 (10.7) .775 198 (66.4) 100 (33.6)
rs14360 GG GT TT G T
Case 3 (115721160) 10 (10.1) 51 (51.5) 38 (38.4) .233 .004 0.035 71 (35.9) 127 (64.1) 9.708 .002 0.015 1.88 (1.26‐2.80)
Control 8 (5.6) 50 (34.7) 86 (59.7) .836 66 (22.9) 222 (77.1)
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SNP, single nucleotide polymorphism; Chr, chromosome; Pos, position; CI, confidence interval; HSCR, Hirschsprung disease; HWE, Hardy‐Weinberg equilibrium.

a

Pearson's P value; the significance level was set at P = .05.

Table 3.

Allele and genotype distributions of NRSN1 among patients with HSCR and normal controls

SNP ID Chr (Pos) Genotype frequency (%) HWE check P valuea P valuea Bonferroni correction Allele frequency (%) X 2 P valuea Bonferroni correction Odds ratio (95% CI)
rs4449613 AA AG GG A G
Case 6 (24130593) 31 (30.7) 49 (48.5) 21 (20.8) .840 .795 >0.05 111 (55.0) 91 (45.0) 0.067 .795 >0.05 1.05 (0.73‐1.50)
Control 40 (27.4) 77 (52.7) 29 (19.9) .462 157 (53.8) 135 (46.2)
rs6935378 CC CG GG C G
Case 6 (24131987) 18 (18.9) 46 (48.4) 31 (32.6) .898 .762 >0.05 82 (43.2) 108 (56.8) 0.525 .469 >0.05 0.87 (0.60‐1.26)
Control 31 (21.5) 72 (50.0) 41 (28.5) .954 134 (46.5) 154 (53.5)
rs4285310 AA AC CC A C
Case 6 (24137874) 4 (4.0) 34 (34.0) 62 (62.0) .805 .846 >0.05 42 (21.0) 158 (79.0) 0.015 .903 >0.05 1.03 (0.66‐1.60)
Control 4 (2.7) 52 (35.6) 90 (61.6) .273 60 (20.5) 232 (79.5)
rs10946675 AA AG GG A G
Case 6 (24141692) 7 (7.1) 29 (29.3) 63 (63.6) .168 .010 0.058 43 (21.7) 155 (78.3) 8.515 .004 0.021 0.54 (0.36‐0.82)
Control 17 (11.6) 65 (44.5) 64 (43.8) .936 99 (33.9) 193 (66.1)
rs3829810 CC CT TT C T
Case 6 (24146444) 56 (54.4) 40 (38.8) 7 (6.8) .968 .022 0.130 152 (73.8) 54 (26.2) 7.829 .005 0.031 1.74 (1.18‐2.56)
Control 57 (38.5) 69 (46.6) 22 (14.9) .881 183 (61.8) 113 (38.2)
rs3178 CC CT TT C T
Case 6 (24147344) 41 (39.8) 52 (50.5) 10 (9.7) .263 .794 >0.05 134 (65.0) 72 (35.0) 0.411 .522 >0.05 0.88 (0.61‐1.29)
Control 65 (43.6) 72 (48.3) 12 (8.1) .194 202 (67.8) 96 (32.2)
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SNP, single nucleotide polymorphism; Chr, chromosome; Pos, position; CI, confidence interval; HSCR, Hirschsprung disease; HWE, Hardy‐Weinberg equilibrium.

a

Pearson's P value; the significance level was set at P = .05.

We then performed LD and haplotype analyses of genetic variants in the 3 genes as haplotypes constructed from polymorphisms with strong LD will increase the statistical power for association with the disease. Figure S1 shows LD for each pair of SNPs in HSCR group and control group. Strong LD was observed in the following marker groups: (1) GAL, rs1546309‐s1042577; (2) GAP43, rs2118604‐rs12632276; and (3) NRSN1, rs4449613‐rs6935378, rs4449613‐rs3178 and rs6935378‐rs3178. We thus interrogated the haplotype distributions for these markers in the later analysis.

We selected haplotypes with strong LD for presentation (Table S1). As there were significant frequency discrepancies between HSCR and control groups, several haplotypes were observed to be strongly associated with HSCR. Additionally, haplotype analysis of these 18 polymorphisms revealed some significant global P values (Table S2). For each gene, the haplotypes that combined all markers were the most significant (GAL,= 6.78 × 10−8; GAP43,= 4.16 × 10−12; NRSN1,= .0095). We further included G*Power 3 program in the power calculations and found our sample size had >80% power to detect a significant association (< .05) for alleles, genotypes and haplotypes when an effect size index of 0.24 (corresponding to a “weak” gene effect) was adopted. We further compared the SNP frequency of normal controls in our present study with the SNP frequency of CHB (Han Chinese in Beijing, China) in 1000 Genomes Project Phase3 database (http://asia.ensembl.org), and no significant difference was observed between these 2 datasets (Table S3).

Moreover, SNPsyn software tool was enrolled to interrogate the SNP‐SNP interactions among GAL, GAP43, NRSN1 and our previous studied GABRG2, RELN and PTCH1 genes.13 We investigated the SNP‐SNP interaction networks based on both information gain (I) and synergy (Syn), and recruited only the SNP pairs with significant scores (I, Syn) in the network analysis (Figure 2).22 In our study, significant scores were found at several SNP pairs, corresponding to GAL‐GAP43, GAL‐NRSN1, PTCH1‐GABRG2‐GAP43 group, etc. (Figure 2). The positive SNPs associated with HSCR were also involved in the SNP‐SNP interactions, such as GAL_rs1042577, GAP43_rs283367, GAP43_rs14360, NRSN1_rs10946675, NRSN1_rs3829810, GABRG2_rs209350, GABRG2_rs169793, RELN_rs802788 and PTCH1_rs2236405. All significant results in regard to SNPsyn analysis survived the FDR correction.

Figure 2.

Figure 2

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Gene‐gene interaction networks among GAL, GAP43 NRSN1 and our previous identified RELN, GABRG2 and PTCH1 gene. A and B, Distribution of SNP pair synergy (Syn) and information gain (I). The scores for SNP pairs on true data are plotted in a I vs Syn scatter plot (blue dots) with the superimposed null distribution (red dots). The SNP pairs are selected only if they meet the criteria: synergy ratio (Syn/I) ≥ 0.5 and FDR ≤ 0.05,23 by which the region defined is highlighted in blue. Distributions of Syn and I are plotted in histograms on the sides of the scatter plot; C and D, The interaction networks. Genes and the corresponding SNPs in the networks are connected if the SNP pairs meet the selection criteria (synergy ratio (Syn/I) ≥ 0.5 and FDR≤ 0.05); A and C, The interactions among GAL, GAP43 and NRSN1; B and D, The interactions among GAL, GAP43, NRSN1, RELN, GABRG2 and PTCH1

We further employed the MDR strategy to explore the potential gene‐gene interactions among GAL, GAP43, NRSN1, GABRG2, RELN and PTCH1 corresponding to the best interaction model (Figure 3A‐C, Table 4). As for HSCR risk prediction, the best single factor model was GAP43 (rs14360) (testing accuracy = 0.5813; CVC = 10/10), which was significantly associated with HSCR. GAL (rs1042577)‐PTCH1 (rs28485160) constituted the best two‐factor model that was consistent with the results in the SNPsyn analysis. Certain genotype combinations as to GAL (rs1042577) and PTCH1 (rs28485160), such as AG (rs1042577)‐CC (rs28485160), contributed to high risk in HSCR (Figure 3C). The best four‐factor model, comprising GAP43 (rs14360), GAP43 (rs283367), NRSN1 (rs3829810) and PTCH1 (rs28701981), represented the most significant one (testing accuracy = 0.6167; CVC = 7/10; OR = 15.27) as the accuracy and OR of the best model were increased with the rising number of factors.

Figure 3.

Figure 3

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Gene‐gene interaction networks derived from MDR (multifactor dimensionality reduction) and GeneMANIA regarding HSCR risk. A and B, MDR interaction dendrogram. Shorter connections among nodes mean stronger synergistic (red and orange) or redundant (green and blue) interactions. GAL (rs1042577) and PTCH1 (rs28485160) have the strongest synergistic interaction; A, The interactions between GAL, GAP43 and NRSN1; B, The interactions between GAL, GAP43, NRSN1, GABRG2, RELN and PTCH1; C, Multilocus genotype combinations in the two‐factor best model are associated with the altered risks for HSCR. Each cell shows counts of HSCR cases on left and controls on right. Darker‐shaded cells show higher risk combinations when compared to lighter‐shaded cells; D, The gene network from GeneMANIA shows the relationships for GAL, GAP43, NRSN1, GABRG2, RELN and PTCH1 (nodes) connected (with edges) based on the functional association networks from the databases

Table 4.

Gene‐gene interaction models for SNPs in HSCR risk by MDR analysis

Number of factors Best modela Training accuracy Testing accuracy CVC X 2 P value Odds ratio (95% CI)
1 GAP43(rs14360) 0.604 0.5813 10/10 9.592 .002 2.33 (1.36‐3.99)
2 GAL(rs1042577)‐PTCH1(rs28485160) 0.675 0.6 10/10 27.305 <.0001 4.31 (2.46‐7.57)
3 GAL(rs1042577)‐GAP43(rs283367)‐NRSN1(rs10946675) 0.7204 0.5667 10/10 43.580 <.0001 6.64 (3.70‐11.92)
4 GAP43(rs14360)‐GAP43(rs283367)‐NRSN1(rs3829810)‐PTCH1(rs28701981) 0.7947 0.6167 7/10 79.427 <.0001 15.27 (7.97‐29.25)
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MDR, multifactor dimensionality reduction; CI, confidence interval; HSCR, Hirschsprung disease.

a

The best model was referred to as the one with the maximum testing accuracy and maximum cross‐validation consistency (CVC).

To interrogate the functional association networks among these 6 HSCR‐related genes, we included the GeneMANIA online software in the present study using the parameters limited to co‐expression, co‐localization and genetic interactions (Figure 3D). The 6 genes interacted with each other mainly through co‐expression and genetic interactions, and only the interaction between GAP43 and GABRG2 was partly due to co‐localization. Moreover, gene function prediction showed NRSN1, RELN and GABRG2 might contribute to neuron projection, neuron‐neuron synaptic transmission and neuron part.

4. DISCUSSION

HSCR is a congenital intestinal obstruction characterized by a deficit in migration of enteric neural crest cells (ENCCs), or by a defect in proliferation, differentiation or survival of ENCCs once they reach the intestinal tract.5 As a model of non‐Mendelian genetic disorder, HSCR can be attributed to multiple gene‐gene interactions that modulate the ability of ENCCs to populate the developing gut, and therefore, the synergistic effects of multiple hypomorphic mutations in HSCR‐related genes could affect disease penetrance and severity.3 However, a complete landscape of genetic networks in HSCR remains obscure. Our present study provided first evidence that genetic variants within GAL, GAP43 and NRSN1 might contribute to the altered susceptibility to HSCR, and the interaction networks among GAL, GAP43, NRSN1 and our previous identified GABRG2, RELN and PTCH1 genes might confer an increased risk in HSCR.

Our findings suggested a significant association of GAL (rs1042577) with the altered susceptibility to HSCR. As rs1042577 is located in the untranslated region, this genetic variant may exert an impact on the regulatory mechanisms of gene expression.30 Moreover, we observed that the G allele and GG genotype of rs1042577 were less frequent in HSCR group compared to normal control group, which indicated that the G allele and GG genotype might be involved in a protective effect against HSCR, and yet the A allele and AA genotype of rs1042577 were more common in HSCR cases than in controls, implying that all might be the risk factors for HSCR. Galanin encoded by GAL is a neuroendocrine peptide, which is widely expressed in the central and peripheral nervous systems and also the gastrointestinal tract.31 Additionally, galanin modulates transmitter release from myenteric neurons via inhibition of voltage‐dependent calcium channels mediated by G‐protein‐coupled receptors.32 A recent genomewide study16 suggested GAL as a candidate for HSCR due to the reduced level of GAL expression in HSCR group compared with control group, and our results further supported this opinion.

We further interrogated the association between GAP43 and HSCR, and found that 2 genetic markers (rs283367 and rs14360) within GAP43 gene presented a strong association with the HSCR risk. Saeed et al16 have pointed out that GAP43 was significantly down‐regulated in the diseased segment of HSCR cases compared to controls. The protein encoded by GAP43 is expressed at high levels in neuronal growth cones during development and axonal regeneration, suggesting its presynaptic localization in developing neurons.33 It has been suggested that GAP43 is a crucial component of an effective regenerative response in the nervous system, and the interaction of GAP43 and MASH1/Ascl1a (the basic helix‐loop‐helix transcription factor) promote functional axon regeneration in the adult central nervous system (CNS).34 Based on our data, the T allele and TT genotype of rs283367 and the G allele and GG genotype of rs14360 might be the risk factors involved in HSCR pathogenesis, whereas the C allele and CC genotype of rs283367 and the T allele and TT genotype of rs14360 might be the protective factors against HSCR. As a UTR SNP, rs14360 might play a crucial role in modulating the level of GAP43 expression. Although it is located in the intronic region of GAP43, rs283367 might still have an effect on the gene expression.

On the other hand, we tried to assess the relationship between NRSN1 gene and HSCR risk. As rs10946675 and rs3829810, the 2 positive SNPs found within NRSN1, were located in the intronic and untranslated regions, respectively, these polymorphisms might be involved in the regulatory mechanisms of gene expression. Specifically, we noticed the G allele and GG genotype of rs10946675 and the C allele and CC genotype of rs3829810 were more frequent in HSCR group than in control group, indicating that all may contribute to the altered risk of HSCR. Neurensin 1 (NRSN1) is a neuron‐specific protein comprising one microtubule‐binding domain and several membrane domains, and it is particularly abundant in neuronal processes, such as the process of neurite extension.35 NRSN1, as a key regulator, may function in neuronal organelle transport and in the conduction of nerve signals, therefore contributing to axonal regeneration and development.36 In addition, the expression of NRSN1 has been proved to be down‐regulated in HSCR cases compared with normal controls,16 further supporting NRSN1 gene as a potential susceptibility gene to HSCR.

In the present study, the significance regarding haplotypes might contribute to the altered risk of HSCR as well (Table S1), as under certain conditions haplotype analysis may increase the power to detect disease loci compared with the single SNP analysis.37 As for each of the 3 genes, the most significant haplotype involved all genetic variants in the corresponding gene (Table S1). Interestingly, certain significant haplotypes might be the protective factors in HSCR, such as GAL_T‐C‐T‐G (rs1546309‐rs3136540‐rs3136541‐rs1042577, P = 1.62 × 10−5, OR = 0.43, 95% CI 0.29‐0.64).

As the interactions among GAL, GABA signalling, GAP43, PTCH1 and reelin might play a crucial role in the neural functions and related disease processes,18, 19, 20 we utilized the SNPsyn platform to further interrogate the SNP‐SNP interaction networks among GAL, GAP43, NRSN1 and our previous identified GABRG2, RELN and PTCH1 genes. On the other hand, synergistic combinations carry more information compared to the sum of information contained in individual SNPs and specifically may carry information in regard to the phenotypes.38 In the present study, we found significant interaction networks in the GAL‐GAP43‐NRSN1 and GAL‐GAP43‐NRSN1‐GABRG2‐RELN‐PTCH1 group, respectively (Figure 2). All the 5 positive genetic variants observed within GAL, GAP43 and NRSN1 were involved in the interaction networks (Figure 2C,D). Moreover, we noticed that certain SNP pairs involved in the networks were located within the same gene, such as rs283367‐rs14360 (GAP43), indicating that the cis‐regulation effect might facilitate this kind of SNP‐SNP interaction.39

We further recruited multifactor dimensionality reduction (MDR) method to evaluate the gene‐gene interactions on the risk of HSCR using the data in regard to the 6 HSCR‐associated genes. MDR was a nonparametric approach that does not require specification of a genetic model to detect gene‐gene interactions without main gene effects.40 Taking advantage of the MDR analysis, we assessed the best interaction model with the maximum testing accuracy and maximum CVC between all the genes involved in our study. Of note, all the positive SNPs within GAL, GAP43 and NRSN1 were included in the best models obtained from the MDR analysis (Table 4). Specifically, the best two‐factor model, GAL (rs1042577)‐PTCH1 (rs28485160), was also identified in the SNPsyn analysis (Figure 2). Compared with other models, the best four‐factor model, GAP43 (rs14360)‐GAP43 (rs283367)‐NRSN1 (rs3829810)‐PTCH1 (rs28701981), presented the most significant OR, raising the possibility that a multifactor model was more likely to facilitate the increased risk to HSCR.

By utilizing the GeneMANIA approach, we further explore the functional networks between these 6 genes involved in HSCR risk (Figure 3D). These 6 genes functionally connected to each other via co‐expression, co‐localization and genetic interactions, and in particular NRSN1, RELN and GABRG2 were predicted to be involved in the processes of neuron projection, neuron‐neuron synaptic transmission and neuron part, further supporting all might contribute to the development of HSCR as HSCR is essentially caused by the defects in the enteric nervous system.

To sum up, our findings firstly demonstrated that genetic variants within GAL, GAP43 and NRSN1 might contribute to the altered susceptibility to HSCR in the Han Chinese population. The interaction networks among GAL, GAP43, NRSN1 and our previous identified GABRG2, RELN and PTCH1 genes might be involved in the risk of HSCR, and specifically, the interactions between GAP43, NRSN1 and PTCH1 might confer the increased risk to HSCR. Our present study points to the need for more independent replication studies with more markers and larger sample size in other ethnic groups. Finally, describing the complete landscape of genetic networks in the pathogenesis of HSCR will definitely depend on technological and conceptual advances.

CONFLICT OF INTEREST

The authors confirm that there are no conflict of interests.

Supporting information

 

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ACKNOWLEDGEMENTS

The authors thank all the members for their contribution to the present study. This work was supported by the National Nature Science Foundation of China (81200259, 81670469 and 81630039), Science and Technology Commission of Shanghai Municipality (14411950405), Shanghai Key Laboratory of Pediatric Gastroenterology and Nutrition (17DZ2272000),”Medicine and Engineering” Interdisciplinary Research Foundation of Shanghai Jiao Tong University (YG2012MS04) and SMC‐Chenxing Young Scholar Program of Shanghai Jiao Tong University.

Wang Y, Yan W, Wang J, et al. Common genetic variants in GAL, GAP43 and NRSN1 and interaction networks confer susceptibility to Hirschsprung disease. J Cell Mol Med. 2018;22:3377–3387. https://doi.org/10.1111/jcmm.13612

Yang Wang and Weihui Yan are contributed equally to this work.

REFERENCES

  • 1. Amiel J, Sproat‐Emison E, Garcia‐Barcelo M, et al. Hirschsprung disease, associated syndromes and genetics: a review. J Med Genet. 2008;45:1‐14. [DOI] [PubMed] [Google Scholar]
  • 2. Tang CS, Cheng G, So MT, et al. Genome‐wide copy number analysis uncovers a new HSCR gene: NRG3. PLoS Genet. 2012;8:e1002687. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 3. Dang R, Torigoe D, Suzuki S, et al. Genetic background strongly modifies the severity of symptoms of Hirschsprung disease, but not hearing loss in rats carrying Ednrb(sl) mutations. PLoS ONE. 2011;6:e24086. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 4. Tam PK, Garcia‐Barcelo M. Genetic basis of Hirschsprung's disease. Pediatr Surg Int. 2009;25:543‐558. [DOI] [PubMed] [Google Scholar]
  • 5. Alves MM, Sribudiani Y, Brouwer RW, et al. Contribution of rare and common variants determine complex diseases‐Hirschsprung disease as a model. Dev Biol. 2013;382:320‐329. [DOI] [PubMed] [Google Scholar]
  • 6. Wallace AS, Anderson RB. Genetic interactions and modifier genes in Hirschsprung's disease. World J Gastroenterol. 2011;17:4937‐4944. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 7. Borrego S, Ruiz‐Ferrer M, Fernandez RM, et al. Hirschsprung's disease as a model of complex genetic etiology. Histol Histopathol. 2013;28:1117‐1136. [DOI] [PubMed] [Google Scholar]
  • 8. Emison ES, Garcia‐Barcelo M, Grice EA, et al. Differential contributions of rare and common, coding and noncoding Ret mutations to multifactorial Hirschsprung disease liability. Am J Hum Genet. 2010;87:60‐74. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 9. Gui H, Schriemer D, Cheng WW, et al. Whole exome sequencing coupled with unbiased functional analysis reveals new Hirschsprung disease genes. Genome Biol. 2017;18:48. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 10. Luzon‐Toro B, Gui H, Ruiz‐Ferrer M, et al. Exome sequencing reveals a high genetic heterogeneity on familial Hirschsprung disease. Sci Rep. 2015;5:16473. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 11. Zhang Z, Li Q, Diao M, et al. Sporadic Hirschsprung disease: mutational spectrum and novel candidate genes revealed by next‐generation sequencing. Sci Rep. 2017;7:14796. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 12. Yang J, Duan S, Zhong R, et al. Exome sequencing identified NRG3 as a novel susceptible gene of Hirschsprung's disease in a Chinese population. Mol Neurobiol. 2013;47:957‐966. [DOI] [PubMed] [Google Scholar]
  • 13. Wang Y, Wang J, Zhou Y, et al. Contribution of common variants in GABRG2, RELN and NRG3 and interaction networks to the risk of Hirschsprung disease. Cell Physiol Biochem. 2016;40:509‐526. [DOI] [PubMed] [Google Scholar]
  • 14. Bae JS, Koh I, Cheong HS, et al. A genome‐wide association analysis of chromosomal aberrations and Hirschsprung disease. Transl Res. 2016;177:31‐40 e6. [DOI] [PubMed] [Google Scholar]
  • 15. Jiang Q, Arnold S, Heanue T, et al. Functional loss of semaphorin 3C and/or semaphorin 3D and their epistatic interaction with ret are critical to Hirschsprung disease liability. Am J Hum Genet. 2015;96:581‐596. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 16. Saeed A, Barreto L, Neogii SG, et al. Identification of novel genes in Hirschsprung disease pathway using whole genome expression study. J Pediatr Surg. 2012;47:303‐307. [DOI] [PubMed] [Google Scholar]
  • 17. Miao X, Garcia‐Barcelo MM, So MT, et al. Role of RET and PHOX2B gene polymorphisms in risk of Hirschsprung's disease in Chinese population. Gut. 2007;56:736. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 18. Qualls‐Creekmore E, Yu S, Francois M, et al. Galanin‐expressing GABA neurons in the lateral hypothalamus modulate food reward and noncompulsive locomotion. J Neurosci. 2017;37:6053‐6065. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 19. Haag D, Zipper P, Westrich V, et al. Nos2 inactivation promotes the development of medulloblastoma in Ptch1(+/−) mice by deregulation of Gap43‐dependent granule cell precursor migration. PLoS Genet. 2012;8:e1002572. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 20. Antonioli‐Santos R, Lanzillotta‐Mattos B, Hedin‐Pereira C, et al. The fine tuning of retinocollicular topography depends on reelin signaling during early postnatal development of the rat visual system. Neuroscience. 2017;357:264‐272. [DOI] [PubMed] [Google Scholar]
  • 21. Wang Y, Wang J, Pan W, et al. Common genetic variations in Patched1 (PTCH1) gene and risk of hirschsprung disease in the Han Chinese population. PLoS ONE. 2013;8:e75407. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 22. Curk T, Rot G, Zupan B. SNPsyn: detection and exploration of SNP‐SNP interactions. Nucleic Acids Res. 2011;39:W444‐W449. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 23. Benjamini Y, Drai D, Elmer G, et al. Controlling the false discovery rate in behavior genetics research. Behav Brain Res. 2001;125:279‐284. [DOI] [PubMed] [Google Scholar]
  • 24. Hahn LW, Ritchie MD, Moore JH. Multifactor dimensionality reduction software for detecting gene‐gene and gene‐environment interactions. Bioinformatics. 2003;19:376‐382. [DOI] [PubMed] [Google Scholar]
  • 25. Zuberi K, Franz M, Rodriguez H, et al. GeneMANIA prediction server 2013 update. Nucleic Acids Res. 2013;41:W115‐W122. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 26. Shi YY, He L. SHEsis, a powerful software platform for analyses of linkage disequilibrium, haplotype construction, and genetic association at polymorphism loci. Cell Res. 2005;15:97‐98. [DOI] [PubMed] [Google Scholar]
  • 27. Purcell S, Neale B, Todd‐Brown K, et al. PLINK: a tool set for whole‐genome association and population‐based linkage analyses. Am J Hum Genet. 2007;81:559‐575. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 28. Dudbridge F. Likelihood‐based association analysis for nuclear families and unrelated subjects with missing genotype data. Hum Hered. 2008;66:87‐98. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 29. Faul F, Erdfelder E, Lang AG, et al. G*Power 3: a flexible statistical power analysis program for the social, behavioral, and biomedical sciences. Behav Res Methods. 2007;39:175‐191. [DOI] [PubMed] [Google Scholar]
  • 30. Orr N, Chanock S. Common genetic variation and human disease. Adv Genet. 2008;62:1‐32. [DOI] [PubMed] [Google Scholar]
  • 31. Mechenthaler I. Galanin and the neuroendocrine axes. Cell Mol Life Sci. 2008;65:1826‐1835. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 32. Anselmi L, Stella SL Jr, Lakhter A, et al. Galanin receptors in the rat gastrointestinal tract. Neuropeptides. 2005;39:349‐352. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 33. Gorup D, Bohacek I, Milicevic T, et al. Increased expression and colocalization of GAP43 and CASP3 after brain ischemic lesion in mouse. Neurosci Lett. 2015;597:176‐182. [DOI] [PubMed] [Google Scholar]
  • 34. Williams RR, Venkatesh I, Pearse DD, et al. MASH1/Ascl1a leads to GAP43 expression and axon regeneration in the adult CNS. PLoS ONE. 2015;10:e0118918. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 35. Suzuki H, Tohyama K, Nagata K, et al. Regulatory expression of Neurensin‐1 in the spinal motor neurons after mouse sciatic nerve injury. Neurosci Lett. 2007;421:152‐157. [DOI] [PubMed] [Google Scholar]
  • 36. Ida M, Suzuki H, Mori N, et al. Neuro‐p24 plays an essential role in neurite extension: antisense oligonucleotide inhibition of neurite extension in cultured DRG neurons and neuroblastoma cells. Neurosci Res. 2004;50:199‐208. [DOI] [PubMed] [Google Scholar]
  • 37. Clark AG. The role of haplotypes in candidate gene studies. Genet Epidemiol. 2004;27:321‐333. [DOI] [PubMed] [Google Scholar]
  • 38. Gerke J, Lorenz K, Cohen B. Genetic interactions between transcription factors cause natural variation in yeast. Science. 2009;323:498‐501. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 39. Becker J, Wendland JR, Haenisch B, et al. A systematic eQTL study of cis‐trans epistasis in 210 HapMap individuals. Eur J Hum Genet. 2012;20:97‐101. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 40. Ritchie MD, Hahn LW, Roodi N, et al. Multifactor‐dimensionality reduction reveals high‐order interactions among estrogen‐metabolism genes in sporadic breast cancer. Am J Hum Genet. 2001;69:138‐147. [DOI] [PMC free article] [PubMed] [Google Scholar]

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