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Research Article

Polymorphisms in the Innate Immune IFIH1 Gene, Frequency of Enterovirus in Monthly Fecal Samples during Infancy, and Islet Autoimmunity

  • Elisabet Witsø mail,

    elisabet.witso@gmail.com

    Affiliation: Norwegian Institute of Public Health, Oslo, Norway

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  • German Tapia,

    Affiliation: Norwegian Institute of Public Health, Oslo, Norway

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  • Ondrej Cinek,

    Affiliation: 2nd Faculty of Medicine, Charles University Prague, Prague, The Czech Republic

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  • Flemming Michael Pociot,

    Affiliation: Glostrup Research Institute, Glostrup, Denmark

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  • Lars C. Stene,

    Affiliation: Norwegian Institute of Public Health, Oslo, Norway

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  • Kjersti S. Rønningen

    Affiliation: Oslo University Hospital, Rikshospitalet, Oslo, Norway

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  • Published: November 14, 2011
  • DOI: 10.1371/journal.pone.0027781

Abstract

Interferon induced with helicase C domain 1 (IFIH1) senses and initiates antiviral activity against enteroviruses. Genetic variants of IFIH1, one common and four rare SNPs have been associated with lower risk for type 1 diabetes. Our aim was to test whether these type 1 diabetes-associated IFIH1 polymorphisms are associated with the occurrence of enterovirus infection in the gut of healthy children, or influence the lack of association between gut enterovirus infection and islet autoimmunity.

After testing of 46,939 Norwegian newborns, 421 children carrying the high risk genotype for type 1 diabetes (HLA-DR4-DQ8/DR3-DQ2) as well as 375 children without this genotype were included for monthly fecal collections from 3 to 35 months of age, and genotyped for the IFIH1 polymorphisms. A total of 7,793 fecal samples were tested for presence of enterovirus RNA using real time reverse transcriptase PCR.

We found no association with frequency of enterovirus in the gut for the common IFIH1 polymorphism rs1990760, or either of the rare variants of rs35744605, rs35667974, rs35337543, while the enterovirus prevalence marginally differed in samples from the 8 carriers of a rare allele of rs35732034 (26.1%, 18/69 samples) as compared to wild-type homozygotes (12.4%, 955/7724 samples); odds ratio 2.5, p = 0.06. The association was stronger when infections were restricted to those with high viral loads (odds ratio 3.3, 95% CI 1.3–8.4, p = 0.01). The lack of association between enterovirus frequency and islet autoimmunity reported in our previous study was not materially influenced by the IFIH1 SNPs.

We conclude that the type 1 diabetes-associated IFIH1 polymorphisms have no, or only minor influence on the occurrence, quantity or duration of enterovirus infection in the gut. Its effect on the risk of diabetes is likely to lie elsewhere in the pathogenic process than in the modification of gut infection.

Introduction

Enteroviruses (family Picornaviridae) cause mostly inapparent or subclinical infections; acute disease may range from minor illness to paralytic disease [1]. Enteroviruses are thought to cross the intestinal epithelium via M-cells [2] and to replicate primarily in the lymphoid tissues of the gut [3], [4].

IFIH1 (interferon induced with helicase C domain 1), also known as MDA5 (melanoma differentiation associated gene 5), encodes a cytoplasmic sensor that recognizes certain types of double stranded RNA (dsRNA) molecules, which are commonly produced during the replication of some RNA viruses. Signaling via IFIH1 triggers activation of NF-κB and interferon regulatory pathways, and induces antiviral interferon responses [5]. IFIH1 is triggered by picornaviruses [6], [7], and two recent publications have found in vivo effects of IFIH1 in mda5 knockout mice infected with coxsackievirus [8], [9].

Enteroviruses have been considered as possible environmental triggers or accelerators of islet autoimmunity leading to type 1 diabetes [10][12]. The relation seems complex, with partially conflicting results [13]; the research has been going on for more than 30 years now. This hypothesis was greatly sparked when a genome-wide association study of type 1 diabetes identified a significant relation with a common polymorphism in IFIH1 [14]. This association is now convincingly established (odds ratio around 0.85 for the minor allele) [15][19].

Recently, deep sequencing of exons and splice sites in the IFIH1 gene revealed that lower risk of type 1 diabetes is also associated with two rare variants with a presumed loss of function (nonsynonymous SNPs rs35744605 (E627X) and rs35667974 (I923V)), and with two noncoding variants affecting conserved splice sites (rs35337543 (1641+1G>C)) and rs35732034 (2807+1G>A)), odds ratios of about 0.5–0.7 [20]. The mechanisms relating IFIH1 polymorphisms to type 1 diabetes, and if enterovirus is involved here, remains unclear and paradoxical. Presumably, variants associated with reduced IFIH1 function would confer the host with a mild antiviral response to enterovirus infection. If so, this would influence the observed association between enterovirus frequency and type 1 diabetes in the population, and failure to account for IFIH1 SNPs in population studies could be hypothesized to “conceal” relations between enterovirus and islet autoimmunity or type 1 diabetes.

The primary aim of the present study was to assess in healthy children whether the IFIH1 polymorphisms associated with type 1 diabetes can predict frequency, viral load, or duration of gut infections with enterovirus. We further aimed to test whether our previously reported lack of association between enterovirus and islet autoimmunity was modified by taking these IFIH1 polymorphisms into account.

Methods

Subjects and study design

The participants were identified and recruited in the MIDIA-study that during 2001–2007 screened 46,939 newborns from the Norwegian general population for the HLA genotype DRB1*04:01-DQA1*03-DQB1*03:02/DRB1*03-DQ​A1*05-DQB1*02(DR4-DQ8/DR3-DQ2) which confers high risk for type 1 diabetes [21]. The present analysis is based on nearly 8,000 fecal samples from 421 children with the HLA DR4-DQ8/DR3-DQ2 genotype and 375 children without this genotype, as described in detail in Figure 1.

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Figure 1. Flow chart illustrating the details of inclusion of children and samples in the current analysis.

*HLA-DRB1*04:01-DQA1*03-DQB1*03:02/DRB1*03-DQ​A1*05-DQB1*02 (DR4-DQ8/DR3-DQ2), conferring high risk for type 1 diabetes. **For each child identified with the high-risk genotype, about 1–4 children without the high risk genotype were enrolled from the same county.

doi:10.1371/journal.pone.0027781.g001

In a separate analysis, we studied whether the IFIH1 polymorphisms modified the risk of type 1 diabetes-related islet autoimmunity among children with the HLA-DR4-DQ8/DR3-DQ2 genotype (Figure 1). Blood samples from these children drawn at ages 3, 6, 9 and 12 months, and annually thereafter were tested for islet autoantibodies (to insulin, glutamic acid decarboxylase, or the protein phosphatase IA2) using radiobinding assays as previously described [21]. The endpoint of islet autoimmunity was defined as repeated positivity for two or three islet autoantibodies. Controls without islet autoimmunity were matched for the HLA DR4-DQ8/DR3-DQ2 genotype, date of birth, length of follow-up and county of residence [13] (Figure 1).

Ethics statement

Written informed consent was provided by participating families. The study was approved by The Regional Committee for Medical Research Ethics (IRB name: “Regional Med Resch Ethics Comm South IRB #2 - South-East A”, IRB00001871) and the Norwegian Data Inspectorate.

Detection of enterovirus RNA in fecal samples

Fecal samples were tested for enterovirus as described earlier [13]. Nucleic acids were co-purified from supernatants of centrifuged feces, and tested for human enterovirus RNA using an internally controlled quantitative reverse transcriptase real-time PCR with primers and probes described in [22]. The median number of fecal samples tested per child was 9 (range 1–36) and the median age at last fecal sample was 12.1 months (range 2.8–37.5).

Genotyping of IFIH1 SNPs

Subjects were genotyped for one common IFIH1 SNP (rs1990760, A946T), and four rare SNPs rs35744605 (E627X), rs35667974 (I923V), rs35732034 (intron 14, 2807+1) and rs35337543 (intron 18, 1641+1). SNP genotyping of rare variant SNPs was performed with the MassARRAY system using iPLEX chemistry (Sequenom, San Diego, CA). The common SNP rs1990760 was genotyped using TaqMan technology with predesigned primer-probe mixes (Applied Biosystems, Foster City, CA, USA). Among children with at least one fecal sample tested for enterovirus (n = 808), genotyping with the MassARRAY system failed in 5–8 DNA samples (<0.1%), and with TaqMan only two samples failed. Duplicate genotyping was performed in 5% randomly chosen samples, with 100% concordance.

Statistical analysis

The final sample for analysis included 796 children and their 7,793 fecal samples (Figure 1). There was no evidence for deviation from Hardy–Weinberg equilibrium (χ2 test) in either of the polymorphisms. Haploview 4.2 was used to assess linkage disequilibria between the alleles of the typed SNPs. Association analyses were performed using logistic regression models with enterovirus infection (yes or no) as the response, individual SNP genotypes as predictors, and a random intercept to account for potential intra-individual correlation (clustering) of infections (xtmelogit in STATA11, StataCorp).

Apart from taking enterovirus positivity as an outcome, in further sensitivity analysis we restricted infections to those with above median quantity of enterovirus RNA among positive samples (defined as high viral load: 10,000 or more virus copies/µl), or to the first enterovirus RNA positive samples among series of two or more consecutively positive samples. Prolonged infection episodes with at least two consecutively positive samples were assessed by excluding other positive samples.

Furthermore, cases of islet autoimmunity and matched controls from our previous publication [13] were compared with respect to enterovirus frequency, and the influence of the IFIH1 SNPs evaluated. This was modeled similarly as for the IFIH1 SNP-enterovirus relation, but with autoimmunity status as a covariate and an additional random intercept to specify matched set (three level random intercept model [23]). These analyses were adjusted for, and stratified by the common variants of IFIH1 SNP rs1990760. The impact of the four rare variant IFIH1 SNPs on the relation between enterovirus infections and islet autoimmunity could only be evaluated by exclusion of subjects with rare variant of either SNP. Matched case-control data at the individual level were done using conditional logistic regression, with additional adjustment for cumulative number of enterovirus infections before seroconversion for islet autoantibodies for cases, and the corresponding time for matched controls.

In our pre-study power considerations, we used parameters from our previously published pilot studies [22], [24] and the literature [14], [20], and estimated that we could detect odds ratios of at least 1.3 of the common IFIH1 A946T variant, and odds ratios at about 2–4 for the various rare variants with approximately 80% power.

Results

Cohort study of IFIH1 SNPs and enterovirus frequency

The frequencies of enterovirus in fecal samples by genotypes of the five SNPs are shown in Table 1. While neither the common polymorphism rs1990760, nor the rare rs35744605, rs35337543, rs35667974 of IFIH1 showed any association with presence, quantity or duration of enterovirus RNA in the gut (Table 1 and Table S1), we observed a statistically non-significant tendency towards association for rs35732034 (Table 1). Here the enterovirus prevalence was 26.1% (18/69 samples) among the 8 children carrying the GA genotype, and 12.4% (955/7724 samples) among children with the wild type variant (OR = 2.5, P = 0.06).

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Table 1. Prevalence (%) of enterovirus RNA in fecal samples and frequency of positive samples with a high viral load according to IFIH1 genotypes.

doi:10.1371/journal.pone.0027781.t001

This suggestive association was strengthened when the analysis was restricted to infections with high viral loads (OR = 3.4, P = 0.01, Table 1). The association with high viral load remained significant after adjustment for age, calendar year and season of sample collection (p-values 0.01 to 0.025 and ORs 3.35 to 2.97, data not shown). The association with this rare variant of rs35732034 was also consistent (but not statistically significant) when restricting the analysis to infectious episodes (OR = 1.9, P = 0.06) or to prolonged infections (OR = 2.5, P = 0.09) (Table S1). As there were no correlations between the tested SNPs (all r2<0.04), the above association is unlikely to be explained by linkage disequilibrium to other known diabetes-associated variants. The association of each IFIH1 SNP with enterovirus was similar among children with and without the type 1 diabetes-associated HLA DR4-DQ8/DR3-DQ2 high-risk genotype, respectively (data not shown).

Nested case control study of islet autoimmunity

We next assessed whether taking the IFIH1 polymorphisms into account would modify our previously published observation of no association between enterovirus frequency and islet autoimmunity [13]. Adjusting for rs1990760 and excluding the 1 case and 6 controls with a rare variant of rs35744605, rs35667974, rs35732034, or rs35337543 did not influence the results materially (Table 2). There was no significant heterogeneity in the association between enterovirus frequency and islet autoimmunity that would depend on the common IFIH1 rs1990760 (Table 2). Finally, rs1990760 was not significantly associated with persistent autoimmunity before or after adjusting for the cumulative number of enterovirus infections within a child prior to the development of persistent autoimmunity (Table 2).

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Table 2. Frequency of enterovirus RNA in faecal samples prior to islet autoimmunity and matched controls and influence of IFIH1 polymorphisms.

doi:10.1371/journal.pone.0027781.t002

Discussion

We found a potential association between a presumed loss of function variant in the IFIH1 gene, the rare SNP rs35732034, and a higher frequency of high quantity fecal shedding of enterovirus in infants. Our most important finding however, was the lack or minor influence of the IFIH1 gene variants on the occurrence, quantity or duration of enterovirus gut infections of healthy infants. Furthermore, taking all these five IFIH1 polymorphisms into account did not influence our previously reported lack of association between enterovirus frequency and risk of islet autoimmunity in children with the type 1 diabetes susceptibility HLA-DR4-DQ8/DR3-DQ2 genotype.

Strengths and limitations

To our knowledge, this is the first study investigating the potential impact of diabetes-associated IFIH1 polymorphisms on the frequency and viral load of enterovirus in the gut of healthy infants. Strengths of the present study are the very large number of samples analysed, the population based, longitudinal design, and the rather frequent interval of fecal sample collection. As enteroviruses are thought to replicate primarily in the intestine, and the virus is shed for weeks after an infection, our study is likely to cover the majority of enterovirus infections. We did not study systemic spread of enterovirus, as blood samples would have to be extremely frequent in order to systematically cover most infections: enterovirus is usually present in the blood for a much shorter period than in the gut [1].

We are aware of only two previous studies relating IFIH1 variants to enterovirus RNA in humans, one that investigated the common rs1990760 but which was severely underpowered for genetic association analysis [25] and one relatively large study of young adult patients with established type 1 diabetes (and non-diabetic controls) that investigated two rare type 1 diabetes IFIH1 variants (rs35744605 and rs35667974) [26]. Both of these studies assayed samples from a single time point from each subject, and may consequently have missed important information on the temporal dimension of the infection. Nevertheless, the rare variant of rs35667974 was slightly more frequent among patients positive for enterovirus RNA in blood compared to enterovirus negative patients [26]. These studies [25], [26], like ours, lack information on enterovirus serotype (genotype). The high number of specific types of enterovirus would require a prohibitively large number of samples for reasonable statistical power for individual serotypes. While we had good power to detect potential associations of small to moderate magnitude (OR<2.0) of the common IFIH1 SNP our data suggest that the per allele odds ratio is highly unlikely to be greater than about 1.2 (upper 95% CI for per allele trend OR). We cannot exclude weak to moderate effects of the rare variants because of limited power, but the possible existence of such weak effects of rare IFIH1 variants on enterovirus infections would have limited population impact on the epidemiology of enterovirus infections, if any at all.

Potential explanations of our main findings

If the suggestive association between the rare A variant of rs35732034 and frequency of high quantity enteroviral infections is true, this indicates a dominant or dose-dependent effect of the predicted interference with splicing of the intron [20]. We can only speculate on the potential mechanisms explaining this phenomenon, while the other established type 1 diabetes associated polymorphisms did not predict enterovirus infections. Predictions based on sequence analysis of the rare variants [20], supported by some experimental functional studies [26][28], suggest that the rare variants associated with lower risk of type 1 diabetes are loss of function variants (functional studies are reviewed in [29]). Most such functional in vitro studies are limited to one or a few aspects of function in one or a few cell types taken out of their in vivo context, and perhaps with limited or uncertain sensitivity. We must keep in mind that the endpoint observed in the current study, fecal shedding of enteroviral RNA, is the likely the result of a very complex interaction between the human host and the viral agent and probably activation of a number of signaling pathways in multiple cell types. While there is no obvious reason to suspect that the functional consequences of the rare variant of rs35732034 should be more severe than that of the other three rare variant SNPs studied, our results indicate that one normal allele is sufficient for eliciting a physiological normal antiviral host immune control of enterovirus infections in the gut of otherwise healthy infants, at least for the SNPs not associated with enterovirus frequency. One reason for lack of association could be the involvement of complementary innate antiviral pathways, such as those involving the Toll-like receptors (reviewed in [30]), explaining why IFIH1 was not essential for IFN-production after an enterovirus infection in mda5 knockout mice [8]. Another potential explanation could be one of the pathogen survival strategies of host immune evasion involving degradation of host IFIH1 signaling molecules [31]. The two groups who have experimentally infected mda5 knockout mice with coxsackievirus have produced partially conflicting results, but one group showed significantly decreased production of type I IFN, but this was not correlated with increased virus titers [9]. The other group showed that type I IFN levels were not affected, but viruses titers were markedly increased transiently [8].

Enterovirus infections and type 1 diabetes related islet autoimmunity

The evidence for the involvement of the enterovirus genus in type 1 diabetes pathogenesis seem likely, yet the limited numbers of available longitudinal studies of islet autoimmunity where enteroviral RNA have been tested as a risk factor have been inconsistent between populations and sources of the sample [13], [32][38]. The evidence seems to be limited to detection in blood or its fractions and predominantly studies done in Finland where serum enterovirus RNA [38] or combined with increases in enterovirus antibodies have been used as indicators of infection [34][36]. This is in contrast to studies from other countries (USA and Germany) showing no association [32], [33]. Neither, studies assessing enterovirus RNA in fecal specimens show any association with islet autoimmunity [13], [32], [37].

The IFIH1 alleles that had been previously associated with reduced type 1 diabetes risk were predicted to be loss of function variants, and may thus confer increased risk for enterovirus infection. We therefore reasoned that our previously published lack of association between enterovirus RNA and islet autoimmunity [13] could be influenced by adjustment for the IFIH1 SNPs. However, adjusting for IFIH1 (rs1990760) and the exclusion of children with rare IFIH1 alleles did not influence the lack of association. A prospective cohort study recently reported lack of association with islet autoantibody development for genotypes of the IFIH1 SNP rs2111485, a SNP in close proximity and in strong linkage disequilibrium with rs1990760. While this may partially be explained by limited statistical power, their study showed an association with faster progression from autoimmunity to type 1 diabetes [39]. This may hint towards a potential role in a different immunological context, but which would be very demanding to study in humans.

In conclusion, despite the predictions that rare IFIH1 variants previously associated with type 1 diabetes are loss of function variants, and experimental data showing an important role of IFIH1 in antiviral immunity to enteroviruses, out data suggests that these variants have no or just minor impact on the frequency and duration of gut infection with enterovirus in healthy infants. Its effect on the risk of diabetes is likely to lie elsewhere in the pathogenic process than in the modification of gut infection frequency.

Supporting Information

Table S1.

The effect of IFIH1 genotypes on different measures of enterovirus infection in longitudinal fecal samples.

doi:10.1371/journal.pone.0027781.s001

(DOC)

Acknowledgments

We thank the public health care nurses, in particular Turid Wetlesen and Lene Gustavsen, for their effort in the recruitment to the MIDIA study and follow-up of participating families. We also thank Trond Rasmussen for excellent data base management, and Caroline Anna Brorsson, Regine Bergholdt, Bodil Bosmann Jørgensen, Rikke Bonne and others at Hagedorn Research Institute, Novo Nordisk, Denmark, for help with planning the genotyping experiments and for valuable inputs. Peter A. Torjussen was responsible for islet autoantibody testing. The staff at the Biobank, Norwegian Institute of Public Health, helped with sample registration and initial handling. We express our gratitude to all the parents and children for participating in the study.

Author Contributions

Conceived and designed the experiments: EW LCS OC KSR FMP. Performed the experiments: GT OC EW. Analyzed the data: EW LCS. Contributed reagents/materials/analysis tools: EW OC KSR FMP. Wrote the paper: EW LCS OC KSR GT FMP.

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