Full Text

Turn on search term navigation

About the Authors:

Jo-Eun Jeong

Roles Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Writing – original draft, Writing – review & editing

Affiliation: Department of Psychiatry, Seoul St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

ORCID http://orcid.org/0000-0002-4200-278X

Je-Keun Rhee

Roles Conceptualization, Data curation, Formal analysis, Methodology, Software

Affiliation: Catholic Cancer Research Institute, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

Tae-Min Kim

Roles Conceptualization, Formal analysis, Methodology, Supervision

Affiliations Catholic Cancer Research Institute, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea, Department of Medical Informatics, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

Su-Min Kwak

Roles Data curation, Investigation

Affiliation: Department of Psychiatry, Seoul St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

Sol-hee Bang

Roles Data curation, Investigation

Affiliation: Department of Psychiatry, Seoul St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

Hyun Cho

Roles Data curation, Investigation

Affiliation: Department of Psychiatry, Seoul St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

Young-Hoon Cheon

Roles Investigation, Resources

Affiliation: Department of Psychiatry, Incheon Chamsarang Hospital, Incheon, Republic of Korea

Jung Ah Min

Roles Conceptualization, Supervision

Affiliation: Department of Psychiatry, Incheon St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

Gil Sang Yoo

Roles Investigation

Affiliation: Department of Psychiatry, Uijeongbu St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

Kyudong Kim

Roles Investigation

Affiliation: Department of Psychiatry, Uijeongbu St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

Jung-Seok Choi

Roles Investigation, Resources, Supervision

Affiliations Department of Psychiatry, SMU-SNU Boramae Medical Center, Seoul, Republic of Korea, Department of Psychiatry, Seoul National University College of Medicine, Seoul, Republic of Korea

Sam-Wook Choi

Roles Investigation, Supervision

Affiliation: Department of Psychiatry, True Mind Mental Health Clinic, Seoul, Republic of Korea

Dai-Jin Kim

Roles Conceptualization, Funding acquisition, Investigation, Methodology, Project administration, Resources, Supervision, Writing – review & editing

* E-mail: [email protected]

Affiliation: Department of Psychiatry, Seoul St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, Republic of Korea

Introduction

As the Internet becomes an essential part of everyday life, the number of Internet users is increasing worldwide [1]. In reports about Internet usage in 2016, approximately 89.9% of the population of South Korea [2] and 89.0% of North America [3] are using the Internet. As Internet use grows, concern about problematic Internet use is also increasing. Although there is no consensus as to what constitutes ‘problematic Internet use (PIU)’, it has been proposed that PIU refers to excessive Internet use that interferes with daily life [4]. Additionally, some studies have suggested that the Internet itself is not the issue, but rather the type of medium and diversity of contents, such as gambling, pornography, and gaming, that are concerning [5–7]. A previous study has also shown that there were differences between individuals with PIU who only played video games and those who only watched pornography [8]. That means that PIU should be replaced by problems more specifically pertaining to these behaviors. In this context, the categorization of PIU into more specific forms, such as Internet gaming disorder (IGD), has been proposed.

IGD is newly listed in Section III, Conditions for Further Study, of the 5th edition of the Diagnostic and Statistical Manual of Mental Disorders (DSM-5) [9] and is currently proposed as the formal diagnostic criteria for gaming disorder in the International Classification of Diseases (ICD) -11 [10]. The DSM-5 proposed that IGD is manifested by persistent or recurrent gaming behavior characterized by impaired control over gaming, leading to clinically significant impairment or distress.

Furthermore, growing evidence suggests that IGD resembles substance addiction in many domains, including phenomenology, co-morbidity, and neurobiological mechanisms [11]. In terms of genetic features, IGD associations with personality traits, such as sensation-seeking [12], impulsivity [13], and self-control [14], have been identified. In addition, several association studies showed that the Taq1A1 allele of the dopamine receptor gene (DRD2) [15], the methionine variant of dopamine degradation enzyme gene (COMT) [15], short allelic variants of the serotonin transporter gene (5-HTTLPR) [16], and polymorphisms of the nicotinic acetylcholine receptor gene (CHRNA4) [17] and neurotrophic tyrosine kinase type 3 receptor gene (NTRK3) [18] were associated with PIU. These personality traits and polymorphisms have also been shown to influence diverse substance addictions [19–24]. Although no genome wide association studies (GWAS) have been reported for IGD until now, two twin studies have shown that genetic influence on PIU was estimated at between 48% and 66% [11, 25]. These figures are comparable to the heritability of substance addictions [26, 27].

These similarities suggest that it is likely that IGD and substance addictions share a common biological underpinning, which may also be partially influenced by similar genetic factors. Previous studies indicate that multiple neurotransmitter systems may play a role in the development of substance and non-substance addictions [28, 29]. Specifically, the mesolimbic dopamine (DA) pathway is implicated in the development of addictions, and this system interacts with numerous other neurotransmitters including serotonergic, glutamatergic, r-aminobutyric acid (GABA), adrenergic, cholinergic, and opioid pathways [30, 31].

We performed a case-control association study of addiction-associated neurotransmitter system genes in both IGD and AD, which represented substance addiction. Additionally, rather than using the existing GWAS, we used targeted exome sequencing (TES), a new approach for identifying genetic variants. GWAS can cover the entire genome, but it requires a very large sample size to obtain the necessary statistical power. Using the exomes, the protein-coding regions, is more efficient since it constitutes only ~1% of the human genome, but harbors much of the functional variation [32]. TES enables focusing on specific candidate genes and achieves a very high depth of coverage (100X coverage or greater) of the regions of interest [33].

The primary aim of the study was to investigate the genetic predisposition of IGD. The secondary aim was to compare the results to those in AD. Study 1 was a case-control study of IGD and Study 2 was an independent case-control study of AD. Both studies included the same basic set of candidate genes. Study 2 added the alcohol-metabolizing enzyme genes, which were consistently reported in the results of a previous GWAS of an East Asian sample [34, 35].

Materials and methods

Study 1 (Case-control study of IGD)

Participants.

The IGD patients were recruited from the addiction clinics of Seoul St. Mary’s Hospital and Boramae Medical Center and were diagnosed according to the DSM-5 criteria for IGD by clinically experienced psychiatrists (D.J.K. and J.S.C.). For homogeneity, the participants were restricted to male adults over 18 years of age. Based on previous studies, men are more likely than women to play [36] and be addicted to Internet games [37]. In addition, there are gender differences in the characteristics of gaming, such as motivation for playing [38, 39], and a relationship between PIU and comorbid psychiatric symptoms, such as depression [40]. There are also differences in the characteristics of gaming, such as playing frequency and game genre, between the adolescent and adult Internet game players [41]. A total of 60 unrelated participants (30 male out-patients with IGD [aged 22–42 years] and 30 sex-matched normal controls (NC) [aged 20–38 years]) were enrolled for a case-control study of IGD. IGD group participants with past or current medical disorders, neurological disorders, or other psychiatric disorders were excluded. NC with no history of medical, neurological, or psychiatric disorders were recruited from the general population. This study was conducted after written consent was obtained from all participants and was approved by the Institutional Review Board (IRB) of Seoul St. Mary’s Hospital (IRB number: KC12ONMI0377).

Measures.

The participants answered questions in regard to age, years of education, marital status, and employment status. In addition, all participants were assessed for their history of alcohol and cigarette use, the Alcohol Use Disorders Identification Test (AUDIT), Fagerstrom test for Nicotine Dependence (FTND), Beck Depression Inventory (BDI), Beck Anxiety Inventory (BAI), and Barratt’s Impulsiveness Scale-11 (BIS-11). The characteristics of IGD were measured by the main purpose of Internet use, weekday/weekend average Internet gaming usage hours, and the Korean version of Young’s Internet Addiction Test (Y-IAT).

The Y-IAT is used worldwide to screen for PIU [42]. The Y-IAT was developed based on the DSM-IV diagnostic criteria for pathological gambling and is composed of 20 items with 5 Likert scales ranging from 1 (Not at all) to 5 (Always). The total scores range from 20 to 100, with the higher scores indicating a greater tendency towards addiction. The Y-IAT scores of 20–39 are regarded as an average user, 40–69 as a possible addicted user, and more than 70 as an addicted user [42].

In this study’s sample, Cronbach’s alphas were .89, .89, .93, .93, .99, and .98 for the AUDIT, FTND, BDI, BAI, BIS-11, and Y-IAT, respectively.

Target selection.

As mentioned previously, the mesolimbic DA pathway is thought to play a key role in the development of addictions [28, 29], and serotonergic, glutamate, GABA, noradrenergic, cholinergic, and opioid neurotransmitter systems have been shown to interact with the mesolimbic DA pathway and modulate its activity [30, 31]. To date, genetic studies of IGD have shown an association between IGD and a genetic variation in a particular neurotransmitter-related gene. Therefore, we selected seventy-two individual genes, including genes of seven neurotransmitter (DA, serotonin [5-HT], glutamate, GABA, norepinephrine [NE], acetylcholine [Ach], and opioid) receptors, transporters, or synthesis and degradation enzymes. The full list of target genes is provided in the Supporting Information (S1 Table).

Target gene captured library construction, sequencing, and sequence analysis.

We generated exome libraries that were enriched for the target genes’ coding sequences using the SureSelect capture probes from Agilent Technologies (Santa Clara, CA, USA). Each library was prepared according to the manufacturer’s recommendations (Illumina, San Diego, CA, USA). Genomic deoxyribonucleic acid (DNA) was extracted from the peripheral blood and fragmented. Following end-repair, Illumina adapters were ligated to the fragments. The sample was selected by aiming for a 350 to 400 base pair product and the selected product was amplified via polymerase chain reaction (PCR). The final product was validated using an Agilent Bioanalyzer (Agilent Technologies, Santa Clara, CA, USA).

Next, the validated and enriched libraries were loaded into a HiSeq2000 (Macrogen Facility, Seoul, Korea) for sequencing. The sequences produced by HiSeq2000 were mapped to the human genome, using the University of California Santa Cruz human genome (UCSC hg19) as the reference sequence and the mapping program Burrows-Wheeler Aligner (BWA, version 0.5.9rc1) [43]. Subsequently, we applied the programs packaged in Picard-tools (version 1.59; http://www.broadinstitute.org) to remove PCR duplicates and eliminate the reads not across the targeted exonic regions. The variants (single nucleotide polymorphisms [SNPs] and insertions and deletions [indels]) were called on each sample with the GATK Haplotype Caller (version 3.4.46; http://www.broadinstitute.org). The called variants were functionally annotated by ANNOVAR (version 2016; http://www.openbioinformatics.org).

Statistical analysis.

Differences in demographic and clinical variables between the IGD and NC groups were tested using the Mann-Whitney U test or Chi-square test. The allelic association was tested using PLINK software (version 1.07) [44]. Some variants were filtered out using the Hardy-Weinberg equilibrium test (p < 1.0 X 10−5) and minor allele frequency (MAF) thresholds (MAF < 0.001). To analyze the associations, the allelic distributions between IGD and NC were compared using Fisher’s exact test. The p-values were adjusted using the genomic-control correction method [45]. Mean Y-IAT scores and weekday/weekend average Internet gaming usage hours of the groups with and without the allele that were significant between IGD and NC were compared using the Mann-Whitney U test. Statistical analyses were performed using SPSS version 24.0 (IBM Corp., Armonk, NY, USA), and p-values less than .05 were considered statistically significant.

Study 2 (Case-control study of AD)

Participants.

The AD patients were recruited from Incheon Chamsarang Hospital and were diagnosed according to the DSM-IV, Text Revision (DSM-IV-TR) criteria for AD by a clinically experienced psychiatrist (Y.H.C). For homogeneity, the participants were restricted to adult males. A total of 60 unrelated participants (31 male in-patients with AD [age range 37 to 57 years] and 29 male NC [age range 40 to 49 years]) were enrolled in a case-control study of AD. The participants of the AD group with past or current major medical disorders, neurological disorders, or other psychiatric disorders were excluded. NC with no history of medical, neurological, or psychiatric disorders were recruited from the local community. This study was approved by the IRB of Seoul St. Mary’s Hospital (IRB number: KC13ONMI0171). All participants provided written informed consent before participation.

Measures.

Participants completed questions in regards to age, years of education, marital status, and employment status. In addition, all participants were assessed for their history of alcohol and cigarette use. BDI, BAI, and BIS-11 were applied and severity of AD was measured using AUDIT. In this study’s sample, Cronbach’s alphas were .95, .98, .97, and .94 for the BDI, BAI, BIS-11, and AUDIT, respectively.

Target selection.

The same 72 genes that were included in study 1 and ten additional genes related to alcohol-metabolic enzyme were selected. The ten additional genes were alcohol dehydrogenase (ADH) 1A, ADH1B, ADH1C, ADH4, ADH5, ADH6, ADH7, aldehyde dehydrogenase (ALDH) 1A1, ALDH2, and cytochrome P450 (CYP) 2E1.

Target gene captured library construction, sequencing, and sequence and statistical analysis.

The methods of captured library construction, sequencing, bioinformatics, and statistical analysis were identical to those of study 1.

Results

Study 1 (Case-control study of IGD)

The demographic and clinical characteristics of the IGD patients and control participants are presented in Table 1. In the IGD group, the mean age was 30.73 ± 6.72 years, and the average playing duration on a weekday and weekend was 2.85 ± 1.74 hours and 4.50 ± 2.51 hours, respectively. The Y-IAT score of IGD patients was 55.60 ± 9.28, which is considered a possible addicted user. There were no differences in mean age, years of education, marital status, employment condition, history of smoking and alcohol use, and AUDIT and FTND scores between the two groups. However, the average Internet game usage hours during the weekday and weekend were significantly longer and the mean Y-IAT, BDI, BAI, and BIS-11 scores were significantly higher in the IGD group than in the NC group.

[Figure omitted. See PDF.]

Table 1. Demographics and clinical characteristics of Korean male participants in study 1.

https://doi.org/10.1371/journal.pone.0188358.t001

A total of 618 SNPs were identified in the IGD or NC group. These SNPs were then used for the association analysis. The average mean depth of the targeted regions among all samples was 757.69 ± 12.21-fold, and an average of 98.7% and 98.6% of the targeted bases were covered at 1- and 10-fold, respectively.

When the MAFs of the SNPs were compared between the IGD and NC groups, 16 variants had unadjusted p-values < .05. However, only one SNP, rs1044396 of nicotinic acetylcholine receptor alpha 4 subunit (CHRNA4) [corrected p = .043, odds ratio (OR) = 0.21], remained significant after correction of the p level and this is a synonymous SNP. The IGD group had a significantly lower number of T alleles of CHRNA4 rs1044396 when compared to that of the controls; this variant had an OR < 1, which suggests a protective effect against IGD. Table 2 shows the characteristics and results of the allelic association analysis for the significant SNP rs1044396 of CHRNA4. The genotypic association test could not be performed because only one participant in the IGD group had a TT genotype.

[Figure omitted. See PDF.]

Table 2. Characteristics and results of the allelic association analysis of the SNP showing a statistically significant difference in MAF between the IGD and NC groups.

https://doi.org/10.1371/journal.pone.0188358.t002

When the entire sample was grouped into T–(CC genotype) and T+ groups (CT and TT genotype) according to presence or absence of the T allele of CHRNA4 rs1044396, the Y-IAT score was significantly lower in the T+ group. This difference in Y-IAT remained significant after controlling for the BDI, BAI, and BIS-11 scores (Table 3).

[Figure omitted. See PDF.]

Table 3. Comparison of clinical variables according to the genotypes of rs1044396 of CHRNA4.

https://doi.org/10.1371/journal.pone.0188358.t003

Study 2 (Case-control study of AD)

The demographic and clinical features of the AD patients and control participants are shown in Table 4. There was no difference in mean age and marital status between the two groups. However, the proportion of unemployment and current smokers, frequency and amount of alcohol drinking, and AUDIT, BDI, BAI, and BIS-11 scores were significantly higher and years of education were significantly shorter in the AD group when compared to those of the NC group.

[Figure omitted. See PDF.]

Table 4. Demographics and clinical characteristics of Korean male participants in study 2.

https://doi.org/10.1371/journal.pone.0188358.t004

A total of 689 SNPs were found in the AD or NC groups. These SNPs were then used for the association analysis. The average mean depth for the targeted regions among all samples was 694.67 ± 83.51-fold. An average of 98.7% and 98.7% of targeted bases were covered at 1- and 10-fold, respectively.

When the MAFs of the SNPs were compared between the AD and NC groups, 28 variants had an unadjusted p-value < .05. In addition, two SNPs, rs1229984 [corrected p = .008, OR = 0.21] of ADH1B and rs671 [corrected p = .020, OR = 0.06] of ALDH2, remained significant after correction of the p level; all were non-synonymous SNPs.

The individuals in the AD group had a significantly lower number of the A alleles of ADH1B rs1229984 (ADH1B*2) and the A alleles of ALDH2 rs671 (ALHD2*2) when compared with that of the NC group. The characteristics and the results of the allelic association analysis for the significant SNPs are shown in Table 5.

[Figure omitted. See PDF.]

Table 5. Characteristics and results of the allelic association analysis of SNPs showing statistically significant difference in MAF between the AD and NC groups.

https://doi.org/10.1371/journal.pone.0188358.t005

Discussion

Our primary aim of the present study was to investigate the genetic predisposition of IGD with the secondary aim of comparing the results to those with AD. We performed a case-control association study for IGD in Korean male adults using 618 SNPs located in 72 candidate genes that encode addiction-associated neurotransmitter systems. In addition, we conducted a case-control study for AD using the same candidate genes and the same method (TES). Consequently, we found that the marker rs1044396 (CHRNA4) was significantly associated with IGD. The IGD group had lower numbers of the T allele of rs1044396, and this variant represents a trend of protective effect (OR, 0.21; 95% CI, 0.07–0.62) against IGD. Moreover, the T+ group (CT and TT genotype) of rs1044396 had lower Y-IAT scores when compared to that of the T– group (CC genotype). This finding is consistent with the result of a German case-control study of 132 Internet addicts (Y-IAT scores higher than 39) and 132 controls [17]. The German study reported that the CC genotype (T– variant) of the rs1044396 polymorphism on the CHRNA4 gene occurred more frequently in the case group [17]. In other words, our study replicated the findings of the CHRNA4 polymorphism association with IGD in a sample of German adults.

Although there have been few studies on the neurobiology of IGD, dopaminergic systems influencing reward and reinforcing behaviors have been implicated in IGD [14, 46, 47]. A study using single photon emission computed tomography (SPECT) suggested that the level of dopamine release in the ventral striatum during a motorcycle riding computer game is comparable to that induced by addictive substances [14, 48]. Additionally, a previous case-control study of seventy-nine male adolescents with excessive Internet video game play (played Internet video games more than 1 hour/day and a Y-IAT score higher than 50) and 75 healthy adolescents showed that the Taq1A1 allele of dopamine receptor gene (DRD2) was associated with excessive game play; individuals with this allele scored higher on a reward-dependence scale [15].

Another association study that examined the genetic polymorphisms of the serotonin transporter gene (5-HTTLPR) showed that 91 male adolescents with excessive Internet use (used the Internet more than 1 hour/day and a Y-IAT score higher than 50) had a higher homozygous short allelic variant of 5-HTTLPR frequencies and BDI scores when compared to that of 75 healthy participants [16].

We also investigated dopaminergic and serotonergic system-related genes, including DRD2 and 5-HTTLPR as target genes, but we did not find allelic differences within the dopaminergic and serotonergic pathway genes between the case and control groups. This may be partially due to differences in participants and the selection criteria for the case group. We recruited young male adults rather than adolescents and the participants in the case group were examined by direct interview according to the DSM-5 criteria for IGD instead of using questionnaire scores.

The present study identified the influence of the gene coding for the alpha4 subunit of the nicotinic acetylcholine receptor (CHRNA4) on IGD. With respect to addiction, a biological link between CHRNA4 and the nicotine-addiction phenotype has been established [21, 49–51]. Knock-in mice with a point mutation in the CHRNA4 gene showed reduced nigrostriatal dopaminergic function [52]. Family-based association testing showed that rs1044396 of the CHRNA4 gene was significantly associated with a protective effect against nicotine addiction [21], similar to our results. One possible explanation for the effect of the CHRNA4 gene on addiction is that the cholinergic pathway is involved in actions in the mesolimbic dopaminergic system, which serves a principal role in the acquisition of addictive behavior [53]. Nearly all ventral tegmental area (VTA) DA neurons display an Ach-induced current with α4β2-type nicotinic acetylcholine receptors (nAchRs) and the activation of the α4 subunit is especially important for the modulation of nicotine-induced reward, sensitization, and tolerance [54].

Furthermore, previous studies have shown a significant association between polymorphisms in CHRNA4 and the psychological risk attitude, response inhibition, and harm avoidance [55, 56]. Impaired response inhibition is an important issue in behavioral addiction [57–59] and previous works have revealed significant associations between harm avoidance and pathological gambling [60–62].

These combined results suggest that the nicotinic acetylcholine receptor may play a role in IGD by modulating the dopaminergic pathway and may affect the addiction phenotype, such as response inhibition. There were no differences in BDI, BAI, and BIS-11 scores, regardless of whether participants have the T allele of rs1044396 CHRNA4, but Y-IAT remained significant after controlling for these scores.

We also conducted an independent case-control association study for AD using the same 72 candidate genes included in study 1 and ten additional alcohol-metabolizing enzyme genes. The participants of study 2 were in-patients and years of education were shorter than those of the control group. In addition, the proportions of unemployment and current smokers were higher than those of the control group. According to previous studies, the prevalence of AD is negatively associated with years of education [63] and the unemployment rates in alcohol treatment programs are remarkably high [64]. Additionally, smoking is more common in the treatment-seeking alcoholic participants than in the non-alcoholic participants [65] and there appeared to be overlap in the genetic factors that influence both conditions, such as the genes that encode receptors for the neurotransmitter GABA [66]. However, we did not find any significant differences in the polymorphisms of the 72 genes that encode neurotransmitter systems between the two groups. Two polymorphisms in the alcohol-metabolizing enzyme gene were identified. The frequencies of the ADH1B*2 (rs1229984) and ALDH2*2 (rs671) alleles were significantly lower in AD than in NC, which is consistent with the results of previous studies [34, 67]. Multiple studies have reported lower frequencies of both the ADH1B*2 and ALDH2*2 alleles in alcoholic participants when compared to that of nonalcoholics participants in a variety of East Asian populations [68–72].

Few studies have compared IGD and substance addictions and comparisons of genetic studies are limited. The existing data suggest that IGD frequently co-occurs with substance addiction [73, 74], and this co-morbidity suggests a common underlying genetic vulnerability for IGD and substance addiction, including AD. To address this assumption, the present study conducted two case-control studies of IGD and AD using the same candidate genes, but the results do not support the assumption. Although rs1044396 of the CHRNA4 gene was associated with nicotine addiction and the addiction phenotype [21, 49–51, 55], further association, family-aggregation, or twin studies are needed to examine the extent to which IGD shares a common genetic vulnerability with substance addictions.

This study has the following limitations. First, our sample size was small, and the study was limited to males. In addition, the genotypic association test could not be performed because only one participant in the IGD group had the TT genotype. Although we used a new method to identify the genetic variants and males are more likely to be addicted to the Internet games than females [75], the results may not be completely generalizable. Second, we did not have a replication sample. While our results are consistent with those of a German case-control association study, a replication of this study using a larger, independent sample with females is essential to validate the results. Third, we compared the results of two independent case-control studies that did not use the same control group because of age differences between IGD and AD patients, although we utilized the same method and the same candidate genes. Fourth, there are some limitations to the measurement of the Y-IAT. Though the Y-IAT is one of the most common instruments used to assess problematic Internet use and had good internal consistency in this study, the composition of questions are not limited to Internet gaming and some items have conflicting results in regards to its psychometric properties [76].

Despite these limitations, this study demonstrated that rs1044396 in exon 5 of CHRNA4 is significantly associated with a protective effect against IGD and a quantitative phenotype (Y-IAT), which was consistent with the results of a German case-control study. To the best of our knowledge, the present investigation is the first study to replicate positive findings in a genetic association study of IGD diagnosed via the DSM-5 criteria and to compare the results of substance addiction and IGD under the several neurotransmitter system genes that have been implicated in the pathogenesis of addiction.

In conclusion, this study showed that a SNP (rs1044396 of CHRNA4) was significantly associated with IGD based on a case-control study using a sample of Korean male adults. The IGD was associated with a lower frequency of the T allele of rs1044396, and the CT and TT genotypes referred to lower addiction severity. These results suggest that the cholinergic system may be involved in the pathogenesis of IGD similar to substance addictions. Subsequent studies are needed to clarify the role of this promising gene in the pathogenesis and genetics of IGD.

Supporting information

[Figure omitted. See PDF.]

S1 Table. Seventy-two target genes used in both study 1 and study 2.

https://doi.org/10.1371/journal.pone.0188358.s001

(DOCX)

S1 File. Raw data.

https://doi.org/10.1371/journal.pone.0188358.s002

(XLSX)

Citation: Jeong J-E, Rhee J-K, Kim T-M, Kwak S-M, Bang S-h, Cho H, et al. (2017) The association between the nicotinic acetylcholine receptor α4 subunit gene (CHRNA4) rs1044396 and Internet gaming disorder in Korean male adults. PLoS ONE 12(12): e0188358. https://doi.org/10.1371/journal.pone.0188358

References

1. Davis RA, Flett GL, Besser A. Validation of a new scale for measuring problematic internet use: implications for pre-employment screening. Cyberpsychology & behavior: the impact of the Internet, multimedia and virtual reality on behavior and society. 2002;5(4):331–45. Epub 2002/09/10. pmid:12216698.

2. Korean Statistical Information Service. Internet Usage 2016 [cited 2017 28 January]. http://kosis.kr/statHtml/statHtml.do?orgId=101&tblId=DT_2KAAA13&conn_path=I2.

3. Internet-World-Stats. World Internet Usage 2016 [cited 2017 28 January]. http://www.internetworldstats.com/stats.htm.

4. Byun S, Ruffini C, Mills JE, Douglas AC, Niang M, Stepchenkova S, et al. Internet addiction: metasynthesis of 1996–2006 quantitative research. Cyberpsychology & behavior: the impact of the Internet, multimedia and virtual reality on behavior and society. 2009;12(2):203–7. Epub 2008/12/17. pmid:19072075.

5. Davis RA. A cognitive-behavioral model of pathological Internet use. Computers in Human Behavior. 2001;17(2):187–95. http://dx.doi.org/10.1016/S0747-5632(00)00041-8.

6. Griffiths M. Does Internet and Computer "Addiction" Exist? Some Case Study Evidence. CyberPsychology & Behavior. 2000;3(2):211–8. EPTOC5323482.

7. Starcevic V, Aboujaoude E. Internet addiction: reappraisal of an increasingly inadequate concept. CNS spectrums. 2017;22(1):7–13. Epub 2016/02/03. pmid:26831456.

8. Pawlikowski M, Nader IW, Burger C, Stieger S, Brand M. Pathological Internet use—It is a multidimensional and not a unidimensional construct. Addiction Research & Theory. 2014;22(2):166–75.

9. The American Psychiatric Association. Internet use disorder: The American Psychiatric Association; 2012. http://www.dsm5.org/ProposedRevision/Pages/proposedrevision.aspx?rid=573#.

10. World Health Organization. ICD-11 Beta Draft: World Health Organization; 2016. http://apps.who.int/classifications/icd11/browse/l-m/en.

11. Vink JM, van Beijsterveldt TC, Huppertz C, Bartels M, Boomsma DI. Heritability of compulsive Internet use in adolescents. Addiction biology. 2016;21(2):460–8. Epub 2015/01/15. pmid:25582809.

12. Chiu SI, Lee JZ, Huang DH. Video game addiction in children and teenagers in Taiwan. Cyberpsychology & behavior: the impact of the Internet, multimedia and virtual reality on behavior and society. 2004;7(5):571–81. Epub 2005/01/26. pmid:15667052.

13. Cao F, Su L, Liu T, Gao X. The relationship between impulsivity and Internet addiction in a sample of Chinese adolescents. European psychiatry: the journal of the Association of European Psychiatrists. 2007;22(7):466–71. Epub 2007/09/04. pmid:17765486.

14. Yau YH, Crowley MJ, Mayes LC, Potenza MN. Are Internet use and video-game-playing addictive behaviors? Biological, clinical and public health implications for youths and adults. Minerva psichiatrica. 2012;53(3):153–70. Epub 2012/09/01. pmid:24288435.

15. Han DH, Lee YS, Yang KC, Kim EY, Lyoo IK, Renshaw PF. Dopamine genes and reward dependence in adolescents with excessive internet video game play. Journal of addiction medicine. 2007;1(3):133–8. Epub 2007/09/01. pmid:21768948.

16. Lee YS, Han DH, Yang KC, Daniels MA, Na C, Kee BS, et al. Depression like characteristics of 5HTTLPR polymorphism and temperament in excessive internet users. Journal of affective disorders. 2008;109(1–2):165–9. Epub 2007/11/30. pmid:18045695.

17. Montag C, Kirsch P, Sauer C, Markett S, Reuter M. The role of the CHRNA4 gene in Internet addiction: a case-control study. Journal of addiction medicine. 2012;6(3):191–5. Epub 2012/06/23. pmid:22722381.

18. Kim JY, Jeong JE, Rhee JK, Cho H, Chun JW, Kim TM, et al. Targeted exome sequencing for the identification of a protective variant against Internet gaming disorder at rs2229910 of neurotrophic tyrosine kinase receptor, type 3 (NTRK3): A pilot study. Journal of behavioral addictions. 2016;5(4):631–8. Epub 2016/11/09. pmid:27826991.

19. Munafo MR, Matheson IJ, Flint J. Association of the DRD2 gene Taq1A polymorphism and alcoholism: a meta-analysis of case-control studies and evidence of publication bias. Molecular psychiatry. 2007;12(5):454–61. Epub 2007/04/25. pmid:17453061.

20. Pinto E, Reggers J, Gorwood P, Boni C, Scantamburlo G, Pitchot W, et al. The short allele of the serotonin transporter promoter polymorphism influences relapse in alcohol dependence. Alcohol and alcoholism (Oxford, Oxfordshire). 2008;43(4):398–400. Epub 2008/03/28. pmid:18364363.

21. Feng Y, Niu T, Xing H, Xu X, Chen C, Peng S, et al. A common haplotype of the nicotine acetylcholine receptor alpha 4 subunit gene is associated with vulnerability to nicotine addiction in men. American journal of human genetics. 2004;75(1):112–21. Epub 2004/05/22. pmid:15154117.

22. Sargent JD, Tanski S, Stoolmiller M, Hanewinkel R. Using sensation seeking to target adolescents for substance use interventions. Addiction (Abingdon, England). 2010;105(3):506–14. Epub 2010/04/21. pmid:20402995.

23. Dawe S, Gullo MJ, Loxton NJ. Reward drive and rash impulsiveness as dimensions of impulsivity: implications for substance misuse. Addictive behaviors. 2004;29(7):1389–405. Epub 2004/09/04. pmid:15345272.

24. Kreek MJ, Nielsen DA, Butelman ER, LaForge KS. Genetic influences on impulsivity, risk taking, stress responsivity and vulnerability to drug abuse and addiction. Nature neuroscience. 2005;8(11):1450–7. Epub 2005/10/28. pmid:16251987.

25. Li M, Chen J, Li N, Li X. A twin study of problematic internet use: its heritability and genetic association with effortful control. Twin research and human genetics: the official journal of the International Society for Twin Studies. 2014;17(4):279–87. Epub 2014/06/17. pmid:24933598.

26. Agrawal A, Lynskey MT. Are there genetic influences on addiction: evidence from family, adoption and twin studies. Addiction (Abingdon, England). 2008;103(7):1069–81. Epub 2008/05/23. pmid:18494843.

27. Li MD, Cheng R, Ma JZ, Swan GE. A meta-analysis of estimated genetic and environmental effects on smoking behavior in male and female adult twins. Addiction (Abingdon, England). 2003;98(1):23–31. Epub 2002/12/21. pmid:12492752.

28. Li MD, Burmeister M. New insights into the genetics of addiction. Nature reviews Genetics. 2009;10(4):225–31. Epub 2009/02/25. pmid:19238175.

29. Ball D. Addiction science and its genetics. Addiction (Abingdon, England). 2008;103(3):360–7. Epub 2007/11/29. pmid:18042191.

30. Enoch MA. Genetic influences on the development of alcoholism. Current psychiatry reports. 2013;15(11):412. Epub 2013/10/05. pmid:24091936 mc4159132.

31. Tomkins DM, Sellers EM. Addiction and the brain: the role of neurotransmitters in the cause and treatment of drug dependence. CMAJ: Canadian Medical Association journal = journal de l’Association medicale canadienne. 2001;164(6):817–21. Epub 2001/03/30. pmid:11276551 mc80880.

32. Ng SB, Turner EH, Robertson PD, Flygare SD, Bigham AW, Lee C, et al. Targeted capture and massively parallel sequencing of 12 human exomes. Nature. 2009;461(7261):272–6. Epub 2009/08/18. pmid:19684571 mc2844771.

33. Bashiardes S, Veile R, Helms C, Mardis ER, Bowcock AM, Lovett M. Direct genomic selection. Nature methods. 2005;2(1):63–9. Epub 2005/09/13. pmid:16152676.

34. Dick DM, Foroud T. Candidate genes for alcohol dependence: a review of genetic evidence from human studies. Alcoholism, clinical and experimental research. 2003;27(5):868–79. Epub 2003/05/27. pmid:12766633.

35. Park BL, Kim JW, Cheong HS, Kim LH, Lee BC, Seo CH, et al. Extended genetic effects of ADH cluster genes on the risk of alcohol dependence: from GWAS to replication. Human genetics. 2013;132(6):657–68. Epub 2013/03/05. pmid:23456092.

36. Ogletree SM, Drake R. College Students’ Video Game Participation and Perceptions: Gender Differences and Implications. Sex Roles. 2007;56(7):537–42.

37. Ko CH, Yen JY, Chen CC, Chen SH, Yen CF. Gender differences and related factors affecting online gaming addiction among Taiwanese adolescents. The Journal of nervous and mental disease. 2005;193(4):273–7. Epub 2005/04/05. pmid:15805824.

38. Hartmann T, Klimmt C. Gender and Computer Games: Exploring Females’ Dislikes. Journal of Computer-Mediated Communication. 2006;11(4):910–31.

39. Yee N. Motivations for play in online games. Cyberpsychology & behavior: the impact of the Internet, multimedia and virtual reality on behavior and society. 2006;9(6):772–5. Epub 2007/01/05. pmid:17201605.

40. Liang L, Zhou D, Yuan C, Shao A, Bian Y. Gender differences in the relationship between internet addiction and depression: A cross-lagged study in Chinese adolescents. Computers in Human Behavior. 2016;63:463–70. http://dx.doi.org/10.1016/j.chb.2016.04.043.

41. Griffiths MD, Davies MNO, Chappell D. Online computer gaming: a comparison of adolescent and adult gamers. Journal of Adolescence. 2004;27(1):87–96. http://dx.doi.org/10.1016/j.adolescence.2003.10.007. pmid:15013262

42. Young KS. Internet Addiction: The Emergence of a New Clinical Disorder. Cyberpsychology & behavior. 1998;1(3):237–44.

43. Li H, Durbin R. Fast and accurate short read alignment with Burrows-Wheeler transform. Bioinformatics (Oxford, England). 2009;25(14):1754–60. Epub 2009/05/20. pmid:19451168.

44. Purcell S, Neale B, Todd-Brown K, Thomas L, Ferreira MA, Bender D, et al. PLINK: a tool set for whole-genome association and population-based linkage analyses. American journal of human genetics. 2007;81(3):559–75. Epub 2007/08/19. pmid:17701901.

45. Devlin B, Roeder K, Bacanu SA. Unbiased methods for population-based association studies. Genetic epidemiology. 2001;21(4):273–84. Epub 2002/01/05. pmid:11754464.

46. Kim SH, Baik SH, Park CS, Kim SJ, Choi SW, Kim SE. Reduced striatal dopamine D2 receptors in people with Internet addiction. Neuroreport. 2011;22(8):407–11. Epub 2011/04/19. pmid:21499141.

47. Koepp MJ, Gunn RN, Lawrence AD, Cunningham VJ, Dagher A, Jones T, et al. Evidence for striatal dopamine release during a video game. Nature. 1998;393(6682):266–8. Epub 1998/06/02. pmid:9607763.

48. Weinstein AM. Computer and video game addiction-a comparison between game users and non-game users. The American journal of drug and alcohol abuse. 2010;36(5):268–76. Epub 2010/06/16. pmid:20545602.

49. Portugal GS, Gould TJ. Genetic variability in nicotinic acetylcholine receptors and nicotine addiction: converging evidence from human and animal research. Behavioural brain research. 2008;193(1):1–16. Epub 2008/06/24. pmid:18571741 mc2602830.

50. Breitling LP, Dahmen N, Mittelstrass K, Rujescu D, Gallinat J, Fehr C, et al. Association of nicotinic acetylcholine receptor subunit alpha 4 polymorphisms with nicotine dependence in 5500 Germans. The pharmacogenomics journal. 2009;9(4):219–24. Epub 2009/03/18. pmid:19290018.

51. Rocha Santos J, Tomaz PR, Issa JS, Abe TO, Krieger JE, Pereira AC, et al. CHRNA4 rs1044396 is associated with smoking cessation in varenicline therapy. Frontiers in genetics. 2015;6:46. Epub 2015/03/17. pmid:25774163 mc4343187.

52. Labarca C, Schwarz J, Deshpande P, Schwarz S, Nowak MW, Fonck C, et al. Point mutant mice with hypersensitive alpha 4 nicotinic receptors show dopaminergic deficits and increased anxiety. Proceedings of the National Academy of Sciences of the United States of America. 2001;98(5):2786–91. Epub 2001/02/28. pmid:11226318.

53. de Kloet SF, Mansvelder HD, De Vries TJ. Cholinergic modulation of dopamine pathways through nicotinic acetylcholine receptors. Biochemical pharmacology. 2015;97(4):425–38. Epub 2015/07/26. pmid:26208783.

54. Tapper AR, McKinney SL, Nashmi R, Schwarz J, Deshpande P, Labarca C, et al. Nicotine activation of alpha4* receptors: sufficient for reward, tolerance, and sensitization. Science (New York, NY). 2004;306(5698):1029–32. Epub 2004/11/06. pmid:15528443.

55. Hutchison KE, Allen DL, Filbey FM, Jepson C, Lerman C, Benowitz NL, et al. CHRNA4 and tobacco dependence: from gene regulation to treatment outcome. Archives of general psychiatry. 2007;64(9):1078–86. Epub 2007/09/05. pmid:17768273.

56. Roe BE, Tilley MR, Gu HH, Beversdorf DQ, Sadee W, Haab TC, et al. Financial and psychological risk attitudes associated with two single nucleotide polymorphisms in the nicotine receptor (CHRNA4) gene. PloS one. 2009;4(8):e6704. Epub 2009/08/21. pmid:19693267.

57. Goudriaan AE, Oosterlaan J, de Beurs E, van den Brink W. Decision making in pathological gambling: a comparison between pathological gamblers, alcohol dependents, persons with Tourette syndrome, and normal controls. Brain research Cognitive brain research. 2005;23(1):137–51. Epub 2005/03/30. pmid:15795140.

58. Fuentes D, Tavares H, Artes R, Gorenstein C. Self-reported and neuropsychological measures of impulsivity in pathological gambling. Journal of the International Neuropsychological Society: JINS. 2006;12(6):907–12. Epub 2006/10/27. pmid:17064453.

59. Kertzman S, Lowengrub K, Aizer A, Vainder M, Kotler M, Dannon PN. Go-no-go performance in pathological gamblers. Psychiatry research. 2008;161(1):1–10. Epub 2008/09/16. pmid:18789539.

60. Forbush KT, Shaw M, Graeber MA, Hovick L, Meyer VJ, Moser DJ, et al. Neuropsychological characteristics and personality traits in pathological gambling. CNS spectrums. 2008;13(4):306–15. Epub 2008/04/15. pmid:18408650.

61. Alvarez-Moya EM, Jimenez-Murcia S, Granero R, Vallejo J, Krug I, Bulik CM, et al. Comparison of personality risk factors in bulimia nervosa and pathological gambling. Comprehensive psychiatry. 2007;48(5):452–7. Epub 2007/08/21. pmid:17707254.

62. Nordin C, Nylander PO. Temperament and character in pathological gambling. Journal of gambling studies. 2007;23(2):113–20. Epub 2007/01/06. pmid:17205401.

63. Helzer JE, Pryzbeck TR. The co-occurrence of alcoholism with other psychiatric disorders in the general population and its impact on treatment. Journal of studies on alcohol. 1988;49(3):219–24. Epub 1988/05/01. pmid:3374135.

64. Forcier MW. Unemployment and Alcohol Abuse: A Review. Journal of Occupational and Environmental Medicine. 1988;30(3):246–51. 00005122-198803000-00011.

65. Maletzky BM, Klotter J. Smoking and alcoholism. The American journal of psychiatry. 1974;131(4):445–7. Epub 1974/04/01. pmid:4814915.

66. Grucza RA, Bierut LJ. Co-occurring risk factors for alcohol dependence and habitual smoking: update on findings from the Collaborative Study on the Genetics of Alcoholism. Alcohol research & health: the journal of the National Institute on Alcohol Abuse and Alcoholism. 2006;29(3):172–8. Epub 2007/03/22. pmid:17373405.

67. Higuchi S. Polymorphisms of ethanol metabolizing enzyme genes and alcoholism. Alcohol and alcoholism (Oxford, Oxfordshire) Supplement. 1994;2:29–34. Epub 1994/01/01. pmid:8974313.

68. Maezawa Y, Yamauchi M, Toda G, Suzuki H, Sakurai S. Alcohol-metabolizing enzyme polymorphisms and alcoholism in Japan. Alcoholism, clinical and experimental research. 1995;19(4):951–4. Epub 1995/08/01. pmid:7485844.

69. Muramatsu T, Wang ZC, Fang YR, Hu KB, Yan H, Yamada K, et al. Alcohol and aldehyde dehydrogenase genotypes and drinking behavior of Chinese living in Shanghai. Human genetics. 1995;96(2):151–4. Epub 1995/08/01. pmid:7635462.

70. Nakamura K, Iwahashi K, Matsuo Y, Miyatake R, Ichikawa Y, Suwaki H. Characteristics of Japanese alcoholics with the atypical aldehyde dehydrogenase 2*2. I. A comparison of the genotypes of ALDH2, ADH2, ADH3, and cytochrome P-4502E1 between alcoholics and nonalcoholics. Alcoholism, clinical and experimental research. 1996;20(1):52–5. Epub 1996/02/01. pmid:8651462.

71. Lee HC, Lee HS, Jung SH, Yi SY, Jung HK, Yoon JH, et al. Association between polymorphisms of ethanol-metabolizing enzymes and susceptibility to alcoholic cirrhosis in a Korean male population. Journal of Korean medical science. 2001;16(6):745–50. Epub 2001/12/19. pmid:11748356.

72. Shen YC, Fan JH, Edenberg HJ, Li TK, Cui YH, Wang YF, et al. Polymorphism of ADH and ALDH genes among four ethnic groups in China and effects upon the risk for alcoholism. Alcoholism, clinical and experimental research. 1997;21(7):1272–7. Epub 1997/11/05. 9347089. pmid:9347089

73. Shapira NA, Goldsmith TD, Keck PE Jr., Khosla UM, McElroy SL. Psychiatric features of individuals with problematic internet use. Journal of affective disorders. 2000;57(1–3):267–72. Epub 2000/03/10. pmid:10708842.

74. Yen JY, Ko CH, Yen CF, Chen CS, Chen CC. The association between harmful alcohol use and Internet addiction among college students: comparison of personality. Psychiatry and clinical neurosciences. 2009;63(2):218–24. Epub 2009/04/02. pmid:19335391.

75. Fattore L, Melis M, Fadda P, Fratta W. Sex differences in addictive disorders. Frontiers in neuroendocrinology. 2014;35(3):272–84. Epub 2014/04/29. pmid:24769267.

76. Faraci P, Craparo G, Messina R, Severino S. Internet Addiction Test (IAT): which is the best factorial solution? Journal of medical Internet research. 2013;15(10):e225. Epub 2013/11/05. pmid:24184961.

Word count: 6728

Show less

© 2017 Jeong et al. This is an open access article distributed under the terms of the Creative Commons Attribution License: http://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.

Abstract

The primary aim of this study was to investigate the genetic predisposition of Internet gaming disorder (IGD), and the secondary aim was to compare the results to those of alcohol dependence (AD). Two independent case-control studies were conducted. A total of 30 male participants with IGD, diagnosed according to the 5th edition of the Diagnostic and Statistical Manual of Mental Disorders (DSM-5) criteria, and 30 sex-matched controls participated in study 1. We designed targeted exome sequencing (TES) to test for 72 candidate genes that have been implicated in the pathogenesis of addiction. The genes included seven neurotransmitter (dopamine, serotonin, glutamate, r-aminobutyric acid (GABA), norepinephrine, acetylcholine, and opioid) system genes. A total of 31 male in-patients with AD and 29 normal male controls (NC) were enrolled in study 2. The same 72 genes included in study 1 and ten additional genes related to alcohol-metabolic enzyme were selected as the target genes, and we identified the genetic variants using the same method (TES). The IGD group had a lower frequency of the T allele of rs1044396 in the nicotinic acetylcholine receptor alpha 4 subunit (CHRNA4), and this variant represents a protective allele against IGD. However, we did not find a significant difference in the polymorphisms of the 72 genes that encode neurotransmitter systems between the AD and NC groups. This study demonstrated that rs1044396 of CHRNA4 was significantly associated with IGD.

Details

Title
The association between the nicotinic acetylcholine receptor α4 subunit gene (CHRNA4) rs1044396 and Internet gaming disorder in Korean male adults
Author
Jo-Eun, Jeong; Rhee, Je-Keun; Tae-Min, Kim; Su-Min Kwak; Sol-hee Bang; Cho, Hyun; Young-Hoon, Cheon; Jung Ah Min; Yoo, Gil Sang; Kim, Kyudong; Jung-Seok, Choi; Sam-Wook Choi; Dai-Jin, Kim
First page
e0188358
Section
Research Article
Publication year
2017
Publication date
Dec 2017
Publisher
Public Library of Science
e-ISSN
19326203
Source type
Scholarly Journal
Language of publication
English
DOI
https://doi.org/10.1371/journal.pone.0188358
ProQuest document ID
1977213981
Copyright
© 2017 Jeong et al. This is an open access article distributed under the terms of the Creative Commons Attribution License: http://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.