Genetic predisposition for atopy and allergic rhinitis in the Singapore Chinese population

Abstract

INTRODUCTION

Allergic diseases represent a major health problem in the 21st century accounting for nearly one-fourth of the world's population. Allergic Rhinitis (AR) individually affects nearly 10-25% of the world population and the "Allergic rhinitis and its impact on asthma (ARIA) 2008 update" document states that over 600 million patients from all countries, all ethnic groups and of all ages suffer from AR [1, 2]. The prevalence of AR in Singapore is about 13.1%, but this is mostly represented by perennial rhinitis, as the most common allergen found in our city-state is the house dust mite - which is present throughout the year [3, 4]. AR though classically not a life threatening disease has significant influence on the quality of life of both children and adults. Along with asthma, AR forms the two major diseases affecting children worldwide. Nearly 40% of children having AR develop asthma, whereas close to 80% of asthmatic children have AR [5]. Hence from an asthma management perspective, concomitant AR should be assessed, evaluated, and managed as well [6].

AR is defined as an IgE-mediated nasal allergic disorder caused by exposure to allergens, both perennial and seasonal, which exist in our indoor and outdoor environments. It is characterized by symptoms such as rhinorrhea, sneezing, itching and nasal blockage, which are experienced even when the individual is not suffering from a cold or influenza-like diseases [1, 7]. AR, asthma and other allergic diseases have been shown to be a result of complex interactions between genetic- and environmental-factors [8-10]. A series of genetic studies in the Singapore population has identified possible candidate genes or loci associated with asthma and AR along multiple chromosomes (Table 1). However many of these candidate-gene based studies have resulted in no significant association with AR. In this review we focus mainly on evaluating the genetic basis of AR in the Singapore Chinese population.

Genetics of allergic rhinitis

Many candidate genes for AR have been identified over the past decade as summarized by Dávila et al. [11], which describes the various chromosomes and the corresponding genes which might be implicated in AR. Another review by Vercelli [8], summarizes the susceptibility genes for asthma and allergy, and in particular, those that have been successfully replicated in multiple independent populations. A striking observation from this review is that not many candidates were successfully replicated when tested by other research groups in different populations (and occasionally even in similar populations). This observation could also be made by surveying the literature for replicating genetic association studies from different independent populations [8, 12-14].

Genome-wide association studies (GWAS) is a rapid way of identifying candidate single nucleotide polymorphisms (SNPs) and/or genes associated to complex diseases, and has seen some success in identifying potential novel allergy-associated candidate [15-19]. Nevertheless, the heritability accounted for by all these genes put together clearly reveals a great amount of unaccounted or 'missing heritability' [20, 21].

Applicability of the HapMap Chinese database for Singapore Chinese

The HapMap project has been a great resource for genetic association studies. In Phase I of the project (2004), SNP variations of 270 samples from four reference populations with diverse geographic ancestry were obtained: 30 trios (mother, father, and adult child) from the Yoruba population in Ibadan, Nigeria; 30 trios from the Centre d'Etude du Polymorphisme Humain collection of Utah residents of Northern and Western European ancestry; 45 unrelated Han Chinese in Beijing (CHB); and 45 unrelated Japanese in Tokyo. Our research group evaluated the applicability of this data from the CHB population to our Singapore Chinese population. We used two main approaches to evaluate this. (1) A genome-wide comparison of SNPs genotypes from the Hapmap SNP database for CHB population to the genotypes of the Singapore Chinese [22, 23], and (2) selected re-sequencing of 20 candidate genes on the 5q31-33 region in our Singapore Chinese population [24]. Although we identified novel SNPs in our population, close to 75% of all SNPs identified through resequencing could be tagged by SNPs from the Hapmap CHB data [24]. Thus, both approaches clearly demonstrated that we could generally use the Hapmap CHB as a reference population for the Singapore Chinese population. The recent completion of Phase III of the Hapmap project contains genotypes from 11 different populations for over 1.5 million genetic variations in 1,115 individuals. This expanded dataset could serve as a better reference than the 4 main HapMap populations in Phase I when designing genetic association studies.

Genetics of allergic rhinitis in Singapore Chinese

After the completion of the Hapmap project, genetic association studies could be designed using the Hapmap reference populations to identify tagSNPs to represent all SNPs in a particular gene. TagSNPs are generally marked or tagged variants which are in strong linkage (usually r² > 0.8) with other variants in the gene. Hence to save cost, it is possible to genotype only these tagSNPs in a gene which would help in identifying the position of association in this particular gene, which can then be biologically characterized to understand how it influences disease predisposition.

Candidate gene studies

Many genetic association studies have been carried out in the Singapore Chinese population to test the association of potential candidate genes to AR (Table 1). Disappointingly, most of the early results turned out not associated to AR. Replication of a locus identified from a genome-wide linkage study for asthma and allergies also yielded negative results (data not shown). However these results might be due to the small sample sizes. Hence the power of these genetic association studies is quite low which suggests that these candidate genes might actually be involved in the disease but that the studies were underpowered to detect statistical significance.

Recently we have worked on validating the association of known candidate genes for AR in a larger population. For example, we evaluated the association of UGRP1 gene to AR in our cohort with 795 AR cases and 717 healthy controls with no medical history of allergy. We identified association of the 5' upstream SNP rs7726552 to AR with a protective odds ratio of 0.81 for the minor T allele [25]. Similarly, we tested the association of SNPs in BDNF gene for AR in the Singapore Chinese population. We identified a SNP rs10767664 to be associated with AR with an odds ratio of 1.304 [26]. Interestingly, this SNP was in very strong LD (D' = 1 and r² = 0.95) with rs6265 which a non-synonymous mutation which results into an amino acid change from Val to Met and is referred to as Val66Met. Our group is currently characterizing these along with other significant SNPs to evaluate their role in conferring genetic predisposition to allergic diseases and tease out the potential mechanism and pathogenesis of AR.

GWAS

GWAS have been important in identifying many allergy candidate genes for asthma and atopic dermatitis (AD). A schematic of a typical genome wide association study design has been briefly summarized in Fig. 1. We have recently published the first GWAS on AR using the Singapore Chinese population. Although GWAS performed for asthma and AD are important for AR, we wanted to identify in a hypothesis-free manner the genetic variants associated with AR in a Singapore Chinese population consisting of 456 AR patients and 486 controls [19]. We then replicated the top findings with the highest observed p values in an independent population. The replication population consisted of 676 AR patients and 511 controls from a Singapore Chinese cohort collected in the same manner as the discovery cohort. We had identified 2 SNPs (rs8111930, rs505010) which remained significant in the replication population. Currently, our group is working on characterizing these variants and identifying the mechanism by which these genes predispose individuals to AR.

Relevance of identifying genes predisposing to both AR and asthma

Using our GWAS data we also replicated previously identified SNPs through asthma GWAS in our population for both atopy and AR phenotype [19]. SNPs from HLA-DQB1, HLA-DRB1, GRIN2B, ACO1, HLA-DQA2, CA10, FAM82A, HIVEP3, SMAD2, PIP-3E and NPSR1 were shown to be associated to atopy and AR albeit not reaching the genome-wide threshold of 5 × 10^-8. The previous article mentioned which we identified association of BDNF SNPs to AR and we have shown that the same tagSNP rs10767664 is also associated with the atopic asthma at an OR = 1.3. Taken together with other unpublished data from our group we are gaining more evidence towards the hypothesis that asthma and AR could have common SNPs/genes which might regulate their predisposition to allergic disease.

CONCLUSION

Genetic studies in Singapore Chinese for AR and also to large extent asthma show a similar trend in that a wide range of allergy candidate genes were not found to be significantly associated to disease even when tested on a larger population. There might be two main reasons for these negative results: (1) gene-gene and (2) gene-environment interactions.

Epistasis or gene-gene interaction is the masking effect of one gene by another and hence when one considers a single gene/SNP at a time, the association may not be observed statistically [20, 21]. In other cases, it might be true that because complex diseases are influenced by many SNPs - all with small effect sizes individually, one may need to analyze them together using models like Generalized Multifactor Dimensionality Reduction or synergistic regression methods to identify significant associations with disease phenotype. We have observed such interactions to be significant for AR in our Singapore Chinese population. Gene-environment interactions are another possible cause for the negative association results in allergic disease research. Allergic diseases result from a complex interplay between genes and the environment as well as the age at which the exposure occurs [8, 9]. Future studies need to focus on using larger samples sizes to detect the effect of gene-gene interactions and the role of the environment in the expression of disease. As large sample sizes are needed, it is imperative that research groups and consortiums come together to help understand allergy better. Care, however, should be taken to address the heterogeneity of such analysis; such as controlling for ethnicity, environment, age and gender of the volunteers used in the study.

Fig. 1

Flowchart for a genome-wide association study (GWAS) design. SNPs: single nucleotide polymorphisms.

Table 1

Candidate gene/region identified through genetic studies for allergies in Singapore

Footnotes

The study was supported by grants from the Singapore Immunology Network (SIgN-06-006 and SIgN-08-020); National Medical Research Council (NMRC/1150/2008), Singapore; and National University of Singapore (NUS) for the Graduate Research Scholarship for students involved in the study. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

ACKNOWLEDGEMENTS

The author would like to thank all the volunteers and their family members who participated in this study and Dr. Chew Fook Tim and Anand Kumar Andiappan for their suggestions in preparing the manuscript.

References

1. BousquetJKhaltaevNCruzAADenburgJFokkensWJTogiasAZuberbierTBaena-CagnaniCECanonicaGWvan WeelCAgacheIAït-KhaledNBachertCBlaissMSBoniniSBouletLPBousquetPJCamargosPCarlsenKHChenYCustovicADahlRDemolyPDouaguiHDurhamSRvan WijkRGKalayciOKalinerMAKimYYKowalskiMLKunaPLeLTLemiereCLiJLockeyRFMavale-ManuelSMeltzerEOMohammadYMullolJNaclerioRO'HehirREOhtaKOuedraogoSPalkonenSPapadopoulosNPassalacquaGPawankarRPopovTARabeKFRosado-PintoJScaddingGKSimonsFEToskalaEValovirtaEvan CauwenbergePWangDYWickmanMYawnBPYorganciogluAYusufOMZarHAnnesi-MaesanoIBatemanEDBen KhederABoakyeDABouchardJBurneyPBusseWWChan-YeungMChavannesNHChuchalinADolenWKEmuzyteRGrouseLHumbertMJacksonCJohnstonSLKeithPKKempJPKlossekJMLarenas-LinnemannDLipworthBMaloJLMarshallGDNaspitzCNekamKNiggemannBNizankowska-MogilnickaEOkamotoYOrruMPPotterPPriceDStoloffSWVandenplasOViegiGWilliamsDAllergic rhinitis and its impact on asthma (ARIA) 2008 update (in collaboration with the World Health Organization, GA²LEN and AllerGen)Allergy200863Suppl 868160[PubMed][Google Scholar]
2. NathanRAThe burden of allergic rhinitisAllergy Asthma Proc20072839[PubMed][Google Scholar]
3. NgTPTanWCEpidemiology of allergic rhinitis and its associated risk factors in SingaporeInt J Epidemiol199423553558[PubMed][Google Scholar]
4. WangDYGordonBRManagement of persistent allergic rhinitis in the tropics: Singapore experiencesClin Exp Allergy Rev200883744[Google Scholar]
5. PawankarRBunnagCChenYFukudaTKimYYLeLTHuong leTTO'HehirREOhtaKVichyanondPWangDYZhongNKhaltaevNBousquetJAllergic rhinitis and its impact on asthma update (ARIA 2008) - western and Asian-Pacific perspectiveAsian Pac J Allergy Immunol200927237243[PubMed][Google Scholar]
6. GuerraSSherrillDLMartinezFDBarbeeRARhinitis as an independent risk factor for adult-onset asthmaJ Allergy Clin Immunol2002109419425[PubMed][Google Scholar]
7. BousquetJvan CauwenbergePKhaltaevNAllergic rhinitis and its impact on asthmaJ Allergy Clin Immunol2001108S147S334[PubMed][Google Scholar]
8. VercelliDDiscovering susceptibility genes for asthma and allergyNat Rev Immunol20088169182[PubMed][Google Scholar]
9. VercelliDGene-environment interactions in asthma and allergy: the end of the beginning?Curr Opin Allergy Clin Immunol201010145148[PubMed][Google Scholar]
10. MösgesRKlimekLToday's allergic rhinitis patients are different: new factors that may play a roleAllergy200762969975[PubMed][Google Scholar]
11. DávilaIMullolJFerrerMBartraJdel CuvilloAMontoroJJáureguiISastreJValeroAGenetic aspects of allergic rhinitisJ Investig Allergol Clin Immunol200919Suppl 12531[Google Scholar]
12. KabeschMThe art of replicationThorax200964370371[PubMed][Google Scholar]
13. OberCHoffjanSAsthma genetics 2006: the long and winding road to gene discoveryGenes Immun2006795100[PubMed][Google Scholar]
14. ZhangJParéPDSandfordAJRecent advances in asthma geneticsRespir Res200894[PubMed][Google Scholar]
15. MichelSLiangLDepnerMKloppNRuetherAKumarASchedelMVogelbergCvon MutiusEvon BergABufeARietschelEHeinzmannALaubOSimmaBFrischerTGenuneitJGutIGSchreiberSLathropMIlligTKabeschMUnifying candidate gene and GWAS approaches in asthmaPLoS One20105e13894[PubMed][Google Scholar]
16. TamariMTomitaKHirotaTGenome-Wide Association studies of asthmaAllergol Int2011[Epub ahead of print][Google Scholar]
17. ZhangGGoldblattJLeSouëfPThe era of genome-wide association studies: opportunities and challenges for asthma geneticsJ Hum Genet200954624628[PubMed][Google Scholar]
18. Willis-OwenSACooksonWOMoffattMFGenome-wide association studies in the genetics of asthmaCurr Allergy Asthma Rep2009939[PubMed][Google Scholar]
19. AndiappanAKWang deYAnantharamanRParatePNSuriBKLowHQLiYZhaoWCastagnoliPLiuJChewFTGenome-wide association study for atopy and allergic rhinitis in a Singapore Chinese populationPLoS ONE20116e19719[PubMed][Google Scholar]
20. OberCYaoTCThe genetics of asthma and allergic disease: a 21st century perspectiveImmunol Rev20112421030[PubMed][Google Scholar]
21. OberCVercelliDGene-environment interactions in human disease: nuisance or opportunity?Trends Genet201127107115[PubMed][Google Scholar]
22. AndiappanAKAnantharamanRNilkanthPPWang deYChewFTEvaluating the transferability of Hapmap SNPs to a Singapore Chinese populationBMC Genet20101136[PubMed][Google Scholar]
23. AnantharamanRChewFTValidation of pooled genotyping on the Affymetrix 500 k and SNP6.0 genotyping platforms using the polynomial-based probe-specific correctionBMC Genet20091082[PubMed][Google Scholar]
24. ParatePNWang deYChewFTLinkage disequilibrium pattern in asthma candidate genes from 5q31-q33 in the Singapore Chinese populationAnn Hum Genet201074137145[PubMed][Google Scholar]
25. AndiappanAKYeoWSParatePNAnantharamanRSuriBKWang deYChewFTVariation in Uteroglobin-Related Protein 1 (UGRP1) gene is associated with allergic rhinitis in Singapore ChineseBMC Med Genet20111239[PubMed][Google Scholar]
26. AndiappanAKParatePNAnantharamanRSuriBKWangDYChewFTGenetic variation in BDNF is associated with allergic asthma and allergic rhinitis in an ethnic Chinese population in SingaporeCytokine2011[Epub ahead of print][Google Scholar]
27. ShekLPTayAHChewFTGohDLLeeBWGenetic susceptibility to asthma and atopy among Chinese in Singapore--linkage to markers on chromosome 5q31-33Allergy200156749753[PubMed][Google Scholar]
28. LiangXHCheungWHengCKWangDYAbsence of the toll-like receptor 4 gene polymorphisms Asp299Gly and Thr399Ile in Singaporean ChineseTher Clin Risk Manag20051243246[PubMed][Google Scholar]
29. LiangXHCheungWHengCKLiuJJLiCWLimBWang deYCD14 promoter polymorphisms have no functional significance and are not associated with atopic phenotypesPharmacogenet Genomics200616229236[PubMed][Google Scholar]
30. LiangXHCheungWHengCKWangDYReduced transcriptional activity in individuals with IL-18 gene variants detected from functional but not association studyBiochem Biophys Res Commun2005338736741[PubMed][Google Scholar]