A Targeted Association Study of Immunity Genes and Networks Suggests Novel Associations with Placental Malaria Infection

Martin Sikora; Hafid Laayouni; Clara Menendez; Alfredo Mayor; Azucena Bardaji; Betuel Sigauque; Mihai G. Netea; Ferran Casals; Jaume Bertranpetit

doi:10.1371/journal.pone.0024996

Abstract

A large proportion of the death toll associated with malaria is a consequence of malaria infection during pregnancy, causing up to 200,000 infant deaths annually. We previously published the first extensive genetic association study of placental malaria infection, and here we extend this analysis considerably, investigating genetic variation in over 9,000 SNPs in more than 1,000 genes involved in immunity and inflammation for their involvement in susceptibility to placental malaria infection. We applied a new approach incorporating results from both single gene analysis as well as gene-gene interactions on a protein-protein interaction network. We found suggestive associations of variants in the gene KLRK1 in the single gene analysis, as well as evidence for associations of multiple members of the IL-7/IL-7R signalling cascade in the combined analysis. To our knowledge, this is the first large-scale genetic study on placental malaria infection to date, opening the door for follow-up studies trying to elucidate the genetic basis of this neglected form of malaria.

Citation: Sikora M, Laayouni H, Menendez C, Mayor A, Bardaji A, Sigauque B, et al. (2011) A Targeted Association Study of Immunity Genes and Networks Suggests Novel Associations with Placental Malaria Infection. PLoS ONE 6(9): e24996. https://doi.org/10.1371/journal.pone.0024996

Editor: Carlos Penha-Goncalves, Instituto Gulbenkian de Ciência, Portugal

Received: June 29, 2011; Accepted: August 22, 2011; Published: September 19, 2011

Copyright: © 2011 Sikora et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: This work was supported by grant SAF-2007-63171 awarded by Ministerio de Educación y Ciencia (Spain) to JB and the CIBERESP (CIBER of Epidemiology and Public Health, Ministry of Health). Funds were also obtained from Dirreció General de Recerca of Generalitat de Catalunya (Grup de Recerca Consolidat 2005SGR/00608) and from Banco de Bilbao, Vizcaya, Argentaria Foundation (grant number BBVA 02-0). The CISM receives core support from the Spanish Agency for International Cooperation and Development (AECID). All the genotyping was provided by the Spanish “Centro Nacional de Genotipado” (CEGEN; www.cegen.org); support for computations was provided by the National Institute for Bioinformatics (www.inab.org); both are platforms of Genoma España. MGN was supported by a Vici grant of the Netherlands Organization for Scientific Research. AM was supported by the Spanish Ministry of Health (Program for the Promotion of Biomedical Research and Health Sciences, Instituto de Salud Carlos III, CP-04/00220). MS was supported by a PhD fellowship from the Programa de becas FPU del Ministerio de Educación y Ciencia, Spain (AP2005-3982). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Recent years have seen a substantial increase in efforts and funding directed at the control [1], [2] and eventual eradication of malaria [3]. However, despite these efforts, it remains one of the deadliest diseases worldwide. The global death toll has been estimated at 700,000 to 1,000,000 in 2008 alone, from a total number of cases ranging from 208 million to 276 million [4]. The majority of these deaths occur in Sub-Saharan Africa, as a consequence of infection with Plasmodium falciparum. A somewhat lesser known aspect of this statistics is the fact that a large fraction of this annual death toll is a consequence of malaria infection during pregnancy, with up to 200,000 deaths attributed to it [5], [6]. Women in their first pregnancy are particularly at risk of infection [7], [8], and both mothers and their offspring face a number of potential life-threatening complications as a consequence of infection [9], [10]. The key characteristic of the pathogenesis of this type of malaria is infection of the placenta, i.e. the sequestration and subsequent accumulation of infected erythrocytes in the intervillous space [11].

Genetic studies of malaria susceptibility have a long history, and a variety of host genetic factors have been implicated, most prominently the protective effect of the hemoglobin S (HbS) variant [12]. Notably, even this strong effect has been estimated to account for only roughly 2% of the total variation, indicating that a large proportion of genetic resistance factors remain to be discovered [13]. Efforts in discovering these factors have culminated in the recent publication of the first genome-wide association study (GWAS) of malaria, carried out in West Africa [14]. This study highlighted both the potential and the possible pitfalls of large-scale genetic association studies using single nucleotide polymorphisms (SNP) genotyping in African populations. However, its focus was on severe malaria, a complex compound phenotype consisting of severe anemia or cerebral malaria that occurs mostly in children under the age of five, which greatly differ in its physiopathology from malaria in pregnancy. Important differences between the pathophysiology of placental malaria and malaria occurring in non-pregnant patients have been extensively documented, both in terms of the erythrocyte surface antigens sequestered in the placenta that adhere specifically to chondroitin sulphate A, and the predominantly monocytic infiltrate present in placental malaria (for review see [11]). We therefore focused on a more easily measurable phenotype related to placental malaria, namely the susceptibility to infection of the placenta. We previously published the first extensive genetic association study of this phenotype, analyzing genetic variation in 64 genes, and reporting a significant association in the gene FUT9 [15]. Here, we extend this analysis considerably, by investigating genetic variation in more than 1,000 genes involved in immunity and inflammation for their involvement in placental malaria infection. To our knowledge, this is the first large-scale genetic study on this particular malaria phenotype to date.

Results

Genotyping quality and population structure

Out of a total of 347 samples for which genotyping was attempted, 68 did not pass the quality control thresholds for cluster genotyping (see Methods) and were removed. The remaining 279 samples were assayed for a total of 9,178 SNPs. Out of those, we removed all SNPs with ambiguous mapping in the latest SNP annotation (56; Affymetrix annotation release 1.5), with a call rate below 0.8 (439), all that failed testing for Hardy-Weinberg equilibrium in controls (115; p≤10⁻⁴), as well as all monomorphic SNPs (1,554). This resulted in a final analysis sample of 279 individuals (173 cases, 174 controls) and 7,442 SNPs, with an average call rate of 0.97. Testing for population stratification using EIGENSOFT revealed no significant differentiation between cases and controls (p = 0.16), therefore this final sample was used without correcting for stratification in all following analyses.

Association analysis

We performed extensive analyses to test the hypothesis that common variation in the set of host immunity and inflammatory genes is affecting the susceptibility to placental infection (defined as the presence or absence of parasites in placental tissue; see Methods).

As a first step we performed single marker analysis for all SNPs, testing for five models of penetrance (see Methods). Figure 1 shows a quantile-quantile (QQ) plot of the results, confirming the absence of a bias in the distribution of p-values due to population structure, as expected from the results of the EIGENSOFT analysis. The genomic distribution of the results of the single marker association tests is shown in Figure 2. The strongest signal was seen in three neighboring SNPs in the region of the gene KLRK1 on chromosome 12 (see Table 1), with the best SNP showing p = 5×10⁻⁵ (rs12821887). However, none of the SNPs reached genome-wide significance after correcting for multiple testing. In the absence of a clear association signal, we chose to further investigate all regions showing multiple SNPs among the top signals. The KLRK1 region contains three of the top four among all tested SNPs within a region of 8 kb, and therefore merits a more thorough investigation. Another region of potential interest was found in the gene IL7 on chromosome 8, where two neighboring SNPs 33 kb apart were also found among the top genome wide 10 association signals. Results for those two genes remain significant after inclusion of age, parity as well as peripheral malaria infection as covariates in a logistic regression analysis (determined from blood drawn at a visit pre-delivery) (Table 2).

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Figure 1. QQ plot of single SNP association statistics.

The negative logarithm of the ordered empirical p-values obtained from the single marker association analysis is plotted against the negative logarithm of the ordered p-values from a uniform distribution, as expected under the null hypothesis. The grey shaded area indicates the 95% concentration band. No systematic inflation was observed in the test statistics, as noted by the majority of points falling on the diagonal (red line, y = x).

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Figure 2. Genome-wide distribution of single SNP association statistics.

Manhattan plot showing the distribution of the single SNP association statistics. Colored circles indicate the negative logarithm of the empirical p-value for all QC+ SNPs, with colors differentiating the different chromosomes. The red dashed line indicates a significance level of 10⁻³. The two candidate regions IL7 and KLRK1 are also indicated.

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Table 1. Top 10 single SNP association signals.

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Table 2. Logistic regression results for top SNPs in KLRK1 and IL7.

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In order to get a more fine scale resolution of the results in both of those regions, we used BIMBAM to impute genotypes at untyped SNPs and test them for association, using the combined HapMap 2 as a reference panel. We chose to use this reference panel following the suggestions of Guan and Stephens [16], who found that accuracy was improved for situations where the population analyzed was not well represented by any single reference panel. Nevertheless, results from this analysis have to be interpreted with care, as even the African population in the reference panel (Yorubans from Nigeria) shows considerable geographic as well as genetic distance from the study population from southern Mozambique [17]. Figure 3 shows the result of the analysis. As expected by the much higher density of the reference panel, both regions show imputed SNPs with stronger association signals than any of the genotyped SNPs. Around rs2583764, the top signal of the genotyped SNPs in the IL7 region, a number of imputed SNPs with lower p-values are found. The top SNP in this region (rs2583763, p = 9×10⁻⁶), 392 bp upstream of rs2583764, is also the top hit among all imputed SNPs. In the KLRK1 region, a number of imputed SNPs within the gene region also show stronger evidence (top SNP rs7962112, p = 5×10⁻⁵).

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Figure 3. Imputation association results at IL7 and KLRK1.

Results of the association analysis using imputation in the two candidate regions IL7 (A) and KLRK1 (B). In both regions, the negative logarithm of the empirical p-values is plotted (see Methods for details), with filled circles indicating the SNPs genotyped in the respective regions, and empty circles indicating imputed SNPs using the full HapMap 2 panel as a reference. Chromosomal positions of the genes in the region are indicated below the respective panel.

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Finally, in order to investigate whether power to detect association in our sample could be improved by using combinations of multiple markers, we carried out haplotype association tests using BEAGLE. The strongest signal in this analysis was found in the gene IL7, where a cluster including rs2583764 was close to the significance level after a strict multiple test correction (minimum p = 3.2×10⁻⁶; permutation p = 0.07). Dissecting this cluster association result further, we found that a haplotype of four SNPs (ATGA; rs1441438 - rs1036751 - rs6993386 - rs2583764) explained the observed signal. A standard association test for the ATGA haplotype against all other observed haplotypes at the locus indicated a susceptibility effect (OR_ATGA = 3.1; 95% CI = 1.9–5.0; p = 1.6×10⁻⁶). Not surprisingly, this 22 kb haplotype also spans the SNP rs2583763 found in the imputation analysis.

Gene-gene interactions and network analysis

Given that our study focuses on genes related to specific organismal functions, namely inflammation and immunity, we next set out the analysis to include information on the interactions of those genes and their organization in cellular pathways in our analysis. We therefore performed SNP×SNP interaction association tests in our sample. In order to reduce the number of tests, we only analyzed those interacting SNP pairs that were found within 5 kb of genes that had evidence for interaction of their respective protein products. To that end, curated protein interactions were obtained from the Michigan Molecular Interactions database (see Methods). Querying the database with the genes included in the study resulted in a network consisting of a total of 892 genes (nodes), connected by 3789 interactions (edges), from now on referred to as “immunity network”. We then tested all resulting SNP pairs for interaction effects using logistic regression. The strongest signal comes from a SNP pair located in the genes IL7R (rs1494558) and JAK3 (rs6512227). However, this was again not significant after correcting for multiple testing (nominal p = 5.4×10⁻⁵), but given the still considerable number of tests in this pair wise analysis, this is not unexpected.

Even so, two interesting properties of this SNP pair called our attention: firstly, one of the two SNPs, rs1494558, is a non-synonymous variant responsible for a non-polar to polar amino acid substitution (Ile→Thr; Grantham distance D = 89 [18]); and second, IL7R is also interacting with IL7, one of the two regions found with the strongest signal in the single marker analysis. We therefore investigated the joint distribution of association results for both genes and interactions on the immunity network in more detail, using two different approaches.

In the first approach, we assigned a single p-value to each gene and interaction, by combining all SNP p-values mapped to a particular gene or interaction using the Simes method (see Material and Methods). We chose this method over a simpler minimum p-value method in order to avoid systematic biases due to differing number of SNPs in the respective genes/interactions. Having obtained the gene- and interaction-wise p-values, we wanted to see how unusual it was to find a low interaction p-value at one edge distance to a low gene p-value in the immunity network. To this end, we employed a network motif search algorithm to first identify all distinct network motifs composed of three nodes connected by two edges (i.e. chain motifs of length three) in the network. After having obtained the list of motifs (116,728 total), we plotted the distribution of the minimum p-values of the genes versus the minimum p-values of the interaction, for each of the motifs. Results are shown in Figure 4. As can be seen in the distribution, the motif containing both IL7 and the neighboring interaction IL7R – JAK3 is a clear outlier in the empirical distribution. Furthermore, the only other point that also behaves as an outlier for both genes and interactions is an overlapping motif to the former one, including the same IL7R - JAK3 interaction together with JAK2, a gene downstream of JAK3. A more detailed look at the subnetwork containing all first neighbors of the IL7R - JAK3 interaction is shown in Figure 5. As can be seen, the strongest signals in both genes and interactions are clustered in the module IL7-IL7R-JAK3-JAK2-CNTFR, which is part of the IL7 signaling cascade.

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Figure 4. Distribution of gene and interaction p-values for chain motifs.

Plot showing the distribution of minimum gene p-value versus minimum interaction p-value for each chain motif of length three, on a negative logarithmic scale. For clarity, only interactions with p< = 10⁻² are shown. In order to deal with the considerable amount of overplotting due to the large number of data points with similar values, alpha transparency is used for color, resulting in darker colors in regions with many overlapping points. Histograms show the marginal distributions of the minimum gene / interactions p-values, respectively. The structure of the two outlier motifs containing the interaction IL7R – JAK3 is also depicted. The gene / interaction corresponding to the values on the plot are indicated in red.

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Figure 5. Sub-network of first neighbours of IL7R – JAK3 interaction.

A sub-network of the full immune network, containing all nodes separated by one edge from the IL7R – JAK3 interaction (52), and all their interactions (425). Nodes in red indicate genes with p<10⁻². Edges in red indicate interactions with p<10⁻³, with thicker lines corresponding to lower p-values. The IL7 module is shown on the right part of the plot.

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Given the results of this first approach, we wanted to investigate the overall statistical evidence for association of the IL7 signaling cascade in more detail. To this end, we performed an adaptive combination of p-values as described in Yu et al. [19], a flexible method that allows the combination of evidence across multiple SNPs and/or genes in a pathway or network (see Methods for details). Since we were interested in combining evidence both for single SNP factors as well as SNP×SNP interactions, we computed p-values through logistic regression analysis of each SNP pair in the network of interest, comparing a full model including main effects of both SNPs and their interaction effect against a baseline model without any SNP effects. As in the previous analysis, we considered only SNP pairs that were found within 5 kb of genes that had evidence for interaction of their respective protein products, thereby taking into account the topology of the network of interest. The list of p-values was then subjected to the ARTP procedure to obtain an overall measure of significance. We performed this analysis for two different sub-networks: The “core” module of IL7 signaling comprised of IL7, its receptor and the immediate downstream adaptor molecules JAK1 and JAK3; and a more extended module considering all first neighbors of the receptor IL7R in the network (Figure 6).

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Figure 6. ARTP of IL7 sub-networks.

Sub-networks used for the ARTP analysis and their results. (A) IL7 “core” module; (B) extended module considering all first neighbor interactions of IL7R.

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Results of this analysis suggest a strong overall association of the IL7 core module (p = 0.005; 1000 permutations), whereas the larger extended module does not reach significance (p = 0.11). Taken together, these results indicate a potential role for this signal-transduction module in the susceptibility to placental malaria infection.

Discussion

The present study is the first large-scale survey on human genetic variation in the immune system and inflammatory response and its relationship to malaria in pregnancy. It is clear that both of these cellular processes are important components in the response to malaria infection, making them strong candidates for harboring loci that influence susceptibility. Nonetheless, our results show no single region standing out with a clear signal of association, if we consider the stringent statistical thresholds normally employed for GWAS. Explanations for the lack of a clear candidate can be manifold, from a genuine lack of susceptibility loci in the analyzed genes to a lack of power to detect loci with weak effects due to small sample size. For example, we note that the focus of our study was on a targeted subset of the human genome, namely a set of genes related to inflammation and immunity. It is clearly a possibility that other regions not covered by our study could harbor variants that have a strong effect on placental infection either by themselves or in interaction with the genes in our targeted set. In this context, the logical next step would be a well-powered GWAS on thousands of samples with an adequate high density SNP array. Unfortunately, the major limitation in our case was the number of well-phenotyped samples available, making this approach unfeasible. It is however also important to point out that our results mirror the observations of Jallow et al. [14] in their malaria GWAS in West Africa, namely the difficulty of achieving the thresholds normally applied in studies with samples of European descent in Africa. In their study, even in the HBB region, with its known strong protective effect due to hemoglobin S, the strongest signal only barely passes the normally applied threshold of p = 5×10⁻⁷ (p = 3.9×10⁻⁷) [20]. The reason is that due to generally lower levels of linkage disequilibrium (LD) in Africa and genotyping arrays being designed using tagSNPs derived from European populations, effective coverage of even common variants in African populations is low. The targeted genotyping array used in our study will evidently suffer from the same limitations. We therefore followed their example and considered loci with p<10⁻⁴ as interesting regions. The only region that achieves that threshold is KLRK1, which codes for a C-type lectin receptor expressed on the surface of T-cells and natural killer cells [21]. Its role lies in activation of those cells as a response to viral infections or certain tumors. It is therefore not immediately clear how it could exert a potential effect on placental malaria infection. While it is certainly a possibility that there is an effect via an unanticipated mechanism, this result has to be taken with caution until confirmed through a replication study. In addition to that, IL7 emerged as another potential candidate locus, based on the results of both imputation and haplotype association, as well as in the gene-gene interaction analysis, which will be discussed below.

An important limitation of our study is that due to our study design, we cannot formally rule out the possibility that the observed associations are with malaria infection overall, and not specific to placental infection. For example, if placental malaria infection would be associated with high levels of parasitemia, and a variant is associated with parasitemia, we would also expect to observe an association of the variant with placental malaria infection. In order to formally rule out this possibility, it would have been necessary to test for placental infection conditional on an observed peripheral infection. Although peripheral malaria status (determined from blood drawn at a visit pre-delivery) was available as a phenotype, in total there were only 39 individuals that showed evidence of acute malaria infection, and only two of those were control individuals (i.e. without placental infection), making the suggested study design unfeasible. However, performing logistic regression on the top SNPs, adjusting for peripheral malaria infection status as confounder together with parity and age does not change the strength of the association of the SNPs significantly, which would argue against this possibility. Additionally, we also confirmed that although primigravid women are significantly more frequent among the cases (p = 0.006, Fisher's exact test), the top SNPs remain significant after controlling for parity as potential confounder.

A more general concern with association studies is the focus on single genes, without taking into account the interactions among them and their organization into functional pathways. Recent effort has therefore been aimed at incorporating this knowledge into the analysis, both in the development of methods for detecting gene-gene interactions (reviewed in [22]) as well as in the analysis of genetic association studies in the context of biological networks [23], [24], [25]. In this study, we performed an in-depth analysis to integrate the results of both single gene and gene – gene interaction tests in the context of the known interactions of the immunity network. Results of this analysis give additional support to a role of IL-7 signaling in modulating susceptibility to placental infection. Furthermore, results suggest that this role is restricted to the core of the IL-7 signaling module (Figure 6A), composed only of IL-7 and its receptor, as well as its immediate adaptor molecules. The signal is lost when considering a more extended network of downstream components (Figure 6B), due to the noise introduced from the larger number of genes without evidence for association. Integration of interaction data can therefore overcome some of the problems mentioned above, and can aid in prioritizing candidates in the absence of clear association signals. Nonetheless, there is still a general lack of powerful statistical tools to disentangle the effects of multiple interacting variants at different loci on a phenotype of interest, which, when becoming available, will certainly be of great impact in the mapping of genotypes to phenotypes.

Based on these results we therefore suggest a role of IL-7/IL-7R signaling in susceptibility of placental malaria infection. The module identified forms part of the JAK-STAT signaling pathway, which regulates cellular responses mediated by binding of cytokines like IL-7. Some of the responses mediated upon binding of cytokines include cell proliferation and differentiation, making it a key pathway in processes like hematopoiesis and immune development [26]. IL-7 in particular is an important factor in B and T cell development. Looking in more detail at the interaction results, it was intriguing that the top result involved an interaction with a non-synonymous SNP in IL7R. The variant (rs1494558) causes a change from Threonin to Isoleucin in the extracellular domain of the receptor. It is, together with other variants, implicated in autosomal recessive severe combined immunodeficiency, although impairment of IL-7 signaling was not observed [27]. The observed effect is a dominant interaction with rs6512227 (Figure S1), a SNP located upstream of JAK3, indicating a potential regulatory effect. The gene codes for the tyrosine kinase JAK3, an intracellular adaptor protein that is involved in the transduction of signal induced by cytokine receptor binding.

The involvement of the IL-7/IL-17R pathway in placental malaria may be relatively unexpected, but not illogical. Although the most studied activities of IL-7 are those related to B- and T-cell proliferation, IL-7 also exerts important proinflammatory effects. IL-7 has been shown to induce production of TNF by T- and B-cells [28], an important proinflammatory cytokine with deleterious effects in placental malaria. Moreover, IL-7 has been described to drive inflammation in several prototypic inflammatory conditions such as rheumatoid arthritis [29] or atherosclerosis [30]. The inflammatory properties of IL-7/IL-7R pathway could influence susceptibility to placental malaria infection by acting at two separate levels: by modulating direct antimalarial immunity and resistance to infection, and by modulating the inflammatory reaction in the placenta during infection, with subsequent consequences for the outcome of the pregnancy. Since we had data on the pregnancy outcome of the study individuals available, we investigated this possibility by testing the association of pregnancy outcomes (premature delivery and birth weight) with the top SNPs in IL7, as well as the significant SNP×SNP interaction. However, none of those were significant.

In conclusion, our results show evidence for association with placental malaria infection at KLRK1, a gene encoding a natural killer cell receptor molecule and point towards a likely role for IL-7 signaling through IL7R and the JAK/STAT intracellular adaptors. Our study is the first large-scale attempt to determine the genetic basis of placental infection in malaria, and suggests an important unexpected role of the IL-7/IL-7R pathway for the susceptibility of this important clinical condition.

Materials and Methods

Ethics Statement

The study received ethical clearance by the National Mozambican Ethics Review Committee and the Hospital Clinic of Barcelona Ethics Review Committee.

Study subjects

The subjects enrolled in this study have been described in detail elsewhere [15], [31]. Briefly, 360 pregnant women from Manhiça District, southern Mozambique, were chosen among the placebo group of a malaria control intervention trial to form a nested case-control sample of 180 cases and 180 controls. Our phenotype of interest was placental malaria infection, which was defined as the presence of asexual Plasmodium falciparum parasites and/or malaria pigment in placental tissue samples. Cases were chosen as pregnant women with evidence of acute, past, or chronic placental malaria infection, whereas controls were pregnant women who did not show any evidence of parasite infections in the placenta. We chose cases and controls solely on the basis of infection status of the placenta, irrespective of actually observed acute malaria infection of the individuals.

Genotyping

Genotyping was performed using the Affymetrix GeneChip Human Immune and Inflammation 9K SNP Kit, which contains approximately 9,000 SNPs located in around 1,000 genes related to the human immune and inflammatory response. Sample preparation before genotyping consisted in DNA extraction from dried blood spots on filter paper, followed by whole genome amplification (GenomiPhi kit, GE Healthcare). Genotype calling was performed using the Affymetrix GeneChip Targeted Genotyping Analysis Software (Version 1.6). Samples were included for cluster genotyping according to the following criteria: QC call rate>75%; QC half rate<17%; Signal/background ratio>20. Cluster genotyping was performed using the standard settings with the exception of parameter “MinCallConfidence”, which was reduced to 0.8 in order to increase the number of SNPs with raw genotype calls (before applying quality control data filtering, as described in the results).

Statistical analysis

Genotype data management and filtering, as well as single marker association tests and SNP-SNP interaction tests were carried out using PLINK (version 1.06) [32]. Five tests of association were applied for each SNP: allelic, dominant, recessive, full genotypic, and the Cochran-Armitage trend test. Both pointwise and multiple testing corrected estimates of empirical p-values were obtained by permutation as implemented in PLINK (100,000 replicates). SNP-SNP interaction tests were performed for all pairwise combinations, using the logistic regression option in PLINK.

Genotype imputation and Bayesian association mapping for candidate regions were performed using BIMBAM (version 0.99) [33]. Due to the lack of an appropriate Southeast African reference panel, we used the combined panel of all three HapMap populations as a reference for imputation to minimize error rates [16]. All SNPs within 20 kb of the candidate regions were considered for imputation. Bayes factors were transformed to p-values using permutation (1,000,000 replicates) [34].

Multi-marker association analysis was performed using BEAGLE (version 3.0.2) [35], [36], using the allelic, dominant and recessive tests. In order to account for the expected greater haplotypic diversity and therefore increased number of distinct haplotype clusters in African samples, we reduced the ‘scale’ parameter to 2. Empirical p-values were obtained using permutation (10,000 replicates). Phase estimation prior to analysis was carried out using fastPHASE (version 1.4.0) [37] with default settings.

Protein interaction network visualization and analysis was performed using Cytoscape (version 2.6.3) [38], as well as R (version 2.9.0) and Bioconductor (version 2.4) [39]. Protein interaction data was obtained using the Michigan Molecular Interactions (MiMI) plugin for Cytoscape (version 3.0.1) [40]. Network motif search was carried out using the tYNA web tool [41]. SNP-SNP interaction association statistics were mapped to a particular protein-protein interaction if both SNPs were found within 5 kb of the respective genes.

Gene-wise and interaction-wise p-values were obtained by combining the p-values of all SNPs within 5 kb of a gene, or of all SNP-SNP interactions mapped to a particular protein-protein interaction, respectively. P-values were combined using the Simes procedure:where p_i is the i^th ordered p-value of all k SNPs mapped to a particular gene or interaction. This was chosen instead of a simpler minimum p-value method, in order to avoid bias towards lower combined p-values in genes/interactions with larger number of SNPs.

The adaptive rank truncated product (ARTP) procedure for p-value combination was performed as in Yu et al. [19], and is briefly described here. The method uses a permutation procedure to obtain an empirical overall significance from a list of observed p-values. We therefore generated 1000 permuted datasets under the null hypothesis of no association, by randomly reassigning case and control labels of the samples using PLINK. Next, p-values for the ARTP were obtained by logistic regression analysis of each SNP pair in the network of interest, comparing a full model including main effects of both SNPs and their interaction effect against a baseline model without any SNP effects, both for the observed and each of the 1000 permuted datasets. Each of those vectors of p-values was then ordered, and the product of the K smallest p-values was calculated for each, using different values for the truncation point K. The truncation points we used were K = 1, 2, 5, 10, 15, and 20. For each of the truncation points (i.e. rows) in the resulting matrix of 1001 datasets×6 values of K, a p-value for both the observed as well as the 1000 permuted datasets was calculated from the full distribution of the p-value products of that particular K. The final adjusted p-value for the ARTP of the observed data was then obtained by comparing its minimal p-value over all values of K against the full distribution of minimal p-values for each dataset over all values of K.

Population structure was analyzed using EIGENSOFT (version 2.0) [42], with default settings and correcting for linkage disequilibrium (LD). Population differentiation (F_ST) and selection statistics (iHS) of the Illumina 650k Human Genome Diversity Panel (HGDP) data [43] as well as HapMap data [44] were calculated as previously described [15]. Data visualization and additional statistical analysis was performed using R.

Supporting Information

Figure S1.

Interaction effect of rs1494558–rs6512227 interaction. Log odds of disease for all allelic combinations of the two SNPs, estimated by logistic regression.

https://doi.org/10.1371/journal.pone.0024996.s001

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Acknowledgments

We are grateful to the women who participated in this study without whom it would not have been possible. We thank the staff of the Manhiça District Hospital and the Manhiça Health Research Center, for their collaboration. We also thank Elisa Serra for her help and Sergi Sanz and John Aponte, for helping with the databases.

Author Contributions

Conceived and designed the experiments: MS FC JB. Performed the experiments: MS FC. Analyzed the data: MS HL FC JB. Contributed reagents/materials/analysis tools: CM AM AB BS JB. Wrote the paper: MS MGN FC JB. Field work and epidemiology: CM AM AB BS Immunological discussions: MGN.

References

1. Alonso PL, Sacarlal J, Aponte JJ, Leach A, Macete E, et al. (2004) Efficacy of the RTS,S/AS02A vaccine against Plasmodium falciparum infection and disease in young African children: randomised controlled trial. Lancet 364: 1411–1420.
- View Article
- Google Scholar
2. Sacarlal J, Aide P, Aponte JJ, Renom M, Leach A, et al. (2009) Long-term safety and efficacy of the RTS,S/AS02A malaria vaccine in Mozambican children. Journal of Infectious Diseases 200: 329–336.
- View Article
- Google Scholar
3. Roberts L, Enserink M (2007) Malaria. Did they really say … eradication? Science 318: 1544–1545.
- View Article
- Google Scholar
4. World Health Organization (2009) World Malaria Report 2009.
5. Steketee RW, Nahlen BL, Parise ME, Menendez C (2001) The burden of malaria in pregnancy in malaria-endemic areas. American Journal of Tropical Medicine and Hygiene 64: 28–35.
- View Article
- Google Scholar
6. Desai M, ter Kuile FO, Nosten F, McGready R, Asamoa K, et al. (2007) Epidemiology and burden of malaria in pregnancy. Lancet Infectious Disease 7: 93–104.
- View Article
- Google Scholar
7. McGregor IA, Wilson ME, Billewicz WZ (1983) Malaria infection of the placenta in The Gambia, West Africa; its incidence and relationship to stillbirth, birthweight and placental weight. Transactions of the Royal Society of Tropical Medicine and Hygiene 77: 232–244.
- View Article
- Google Scholar
8. Menendez C (1996) An immunological hypothesis to explain the enhanced susceptibility to malaria during pregnancy: Reply. Parasitology Today 12: 41–42.
- View Article
- Google Scholar
9. Menendez C, Ordi J, Ismail MR, Ventura PJ, Aponte JJ, et al. (2000) The impact of placental malaria on gestational age and birth weight. Journal of Infectious Diseases 181: 1740–1745.
- View Article
- Google Scholar
10. Mutabingwa TK, Bolla MC, Li JL, Domingo GJ, Li X, et al. (2005) Maternal malaria and gravidity interact to modify infant susceptibility to malaria. PLoS Medicine 2: e407.
- View Article
- Google Scholar
11. Rogerson SJ, Hviid L, Duffy PE, Leke RF, Taylor DW (2007) Malaria in pregnancy: pathogenesis and immunity. Lancet Infectious Disease 7: 105–117.
- View Article
- Google Scholar
12. Kwiatkowski DP (2005) How malaria has affected the human genome and what human genetics can teach us about malaria. American Journal of Human Genetics 77: 171–192.
- View Article
- Google Scholar
13. Mackinnon MJ, Mwangi TW, Snow RW, Marsh K, Williams TN (2005) Heritability of malaria in Africa. PLoS Medicine 2: e340.
- View Article
- Google Scholar
14. Jallow M, Teo YY, Small KS, Rockett KA, Deloukas P, et al. (2009) Genome-wide and fine-resolution association analysis of malaria in West Africa. Nature Genetics.
- View Article
- Google Scholar
15. Sikora M, Ferrer-Admetlla A, Laayouni H, Menendez C, Mayor A, et al. (2009) A variant in the gene FUT9 is associated with susceptibility to placental malaria infection. Human Molecular Genetics 18: 3136–3144.
- View Article
- Google Scholar
16. Guan Y, Stephens M (2008) Practical issues in imputation-based association mapping. PLoS Genetics 4: e1000279.
- View Article
- Google Scholar
17. Sikora M, Laayouni H, Calafell F, Comas D, Bertranpetit J (2011) A genomic analysis identifies a novel component in the genetic structure of sub-Saharan African populations. European Journal of Human Genetics 19: 84–88.
- View Article
- Google Scholar
18. Grantham R (1974) Amino acid difference formula to help explain protein evolution. Science 185: 862–864.
- View Article
- Google Scholar
19. Yu K, Li Q, Bergen AW, Pfeiffer RM, Rosenberg PS, et al. (2009) Pathway analysis by adaptive combination of P-values. Genetic Epidemiology 33: 700–709.
- View Article
- Google Scholar
20. The Wellcome Trust Case Control Consortium (2007) Genome-wide association study of 14,000 cases of seven common diseases and 3,000 shared controls. Nature 447: 661–678.
- View Article
- Google Scholar
21. Bauer S, Groh V, Wu J, Steinle A, Phillips JH, et al. (1999) Activation of NK cells and T cells by NKG2D, a receptor for stress-inducible MICA. Science 285: 727–729.
- View Article
- Google Scholar
22. Cordell HJ (2009) Genome-wide association studies: Detecting gene-gene interactions that underlie human diseases. Nature Reviews Genetics.
- View Article
- Google Scholar
23. Baranzini SE, Galwey NW, Wang J, Khankhanian P, Lindberg R, et al. (2009) Pathway and network-based analysis of genome-wide association studies in multiple sclerosis. Human Molecular Genetics 18: 2078–2090.
- View Article
- Google Scholar
24. Peng G, Luo L, Siu H, Zhu Y, Hu P, et al. (2010) Gene and pathway-based second-wave analysis of genome-wide association studies. European Journal of Human Genetics 18: 111–117.
- View Article
- Google Scholar
25. Emily M, Mailund T, Hein J, Schauser L, Schierup MH (2009) Using biological networks to search for interacting loci in genome-wide association studies. European Journal of Human Genetics 17: 1231–1240.
- View Article
- Google Scholar
26. Rawlings JS, Rosler KM, Harrison DA (2004) The JAK/STAT signaling pathway. Journal of Cell Science 117: 1281–1283.
- View Article
- Google Scholar
27. Puel A, Ziegler SF, Buckley RH, Leonard WJ (1998) Defective IL7R expression in T(−)B(+)NK(+) severe combined immunodeficiency. Nature Genetics 20: 394–397.
- View Article
- Google Scholar
28. Roato I, Gorassini E, Brunetti G, Grano M, Ciuffreda L, et al. (2007) IL-7 modulates osteoclastogenesis in patients affected by solid tumors. Annals of the New York Academy of Sciences 1117: 377–384.
- View Article
- Google Scholar
29. van Amelsfort JM, van Roon JA, Noordegraaf M, Jacobs KM, Bijlsma JW, et al. (2007) Proinflammatory mediator-induced reversal of CD4+,CD25+ regulatory T cell-mediated suppression in rheumatoid arthritis. Arthritis and Rheumatism 56: 732–742.
- View Article
- Google Scholar
30. Damas JK, Waehre T, Yndestad A, Otterdal K, Hognestad A, et al. (2003) Interleukin-7-mediated inflammation in unstable angina: possible role of chemokines and platelets. Circulation 107: 2670–2676.
- View Article
- Google Scholar
31. Menendez C, Bardaji A, Sigauque B, Romagosa C, Sanz S, et al. (2008) A randomized placebo-controlled trial of intermittent preventive treatment in pregnant women in the context of insecticide treated nets delivered through the antenatal clinic. PLoS ONE 3: e1934.
- View Article
- Google Scholar
32. Purcell S, Neale B, Todd-Brown K, Thomas L, Ferreira MA, et al. (2007) PLINK: a tool set for whole-genome association and population-based linkage analyses. American Journal of Human Genetics 81: 559–575.
- View Article
- Google Scholar
33. Servin B, Stephens M (2007) Imputation-based analysis of association studies: candidate regions and quantitative traits. PLoS Genetics 3: e114.
- View Article
- Google Scholar
34. Stephens M, Balding DJ (2009) Bayesian statistical methods for genetic association studies. Nature Reviews Genetics 10: 681–690.
- View Article
- Google Scholar
35. Browning BL, Browning SR (2007) Efficient multilocus association testing for whole genome association studies using localized haplotype clustering. Genetic Epidemiology 31: 365–375.
- View Article
- Google Scholar
36. Browning SR (2006) Multilocus association mapping using variable-length Markov chains. American Journal of Human Genetics 78: 903–913.
- View Article
- Google Scholar
37. Scheet P, Stephens M (2006) A fast and flexible statistical model for large-scale population genotype data: applications to inferring missing genotypes and haplotypic phase. American Journal of Human Genetics 78: 629–644.
- View Article
- Google Scholar
38. Shannon P, Markiel A, Ozier O, Baliga NS, Wang JT, et al. (2003) Cytoscape: a software environment for integrated models of biomolecular interaction networks. Genome Research 13: 2498–2504.
- View Article
- Google Scholar
39. Gentleman RC, Carey VJ, Bates DM, Bolstad B, Dettling M, et al. (2004) Bioconductor: open software development for computational biology and bioinformatics. Genome Biol 5: R80.
- View Article
- Google Scholar
40. Gao J, Ade AS, Tarcea VG, Weymouth TE, Mirel BR, et al. (2009) Integrating and annotating the interactome using the MiMI plugin for cytoscape. Bioinformatics 25: 137–138.
- View Article
- Google Scholar
41. Yip KY, Yu H, Kim PM, Schultz M, Gerstein M (2006) The tYNA platform for comparative interactomics: a web tool for managing, comparing and mining multiple networks. Bioinformatics 22: 2968–2970.
- View Article
- Google Scholar
42. Patterson N, Price AL, Reich D (2006) Population structure and eigenanalysis. PLoS Genetics 2: e190.
- View Article
- Google Scholar
43. Li JZ, Absher DM, Tang H, Southwick AM, Casto AM, et al. (2008) Worldwide human relationships inferred from genome-wide patterns of variation. Science 319: 1100–1104.
- View Article
- Google Scholar
44. The International HapMap Consortium (2007) A second generation human haplotype map of over 3.1 million SNPs. Nature 449: 851–861.
- View Article
- Google Scholar

[ref1] 1. Alonso PL, Sacarlal J, Aponte JJ, Leach A, Macete E, et al. (2004) Efficacy of the RTS,S/AS02A vaccine against Plasmodium falciparum infection and disease in young African children: randomised controlled trial. Lancet 364: 1411–1420.
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. Sacarlal J, Aide P, Aponte JJ, Renom M, Leach A, et al. (2009) Long-term safety and efficacy of the RTS,S/AS02A malaria vaccine in Mozambican children. Journal of Infectious Diseases 200: 329–336.
View Article
Google Scholar

[5] View Article

[6] Google Scholar

[ref3] 3. Roberts L, Enserink M (2007) Malaria. Did they really say … eradication? Science 318: 1544–1545.
View Article
Google Scholar

[8] View Article

[9] Google Scholar

[ref4] 4. World Health Organization (2009) World Malaria Report 2009.

[ref5] 5. Steketee RW, Nahlen BL, Parise ME, Menendez C (2001) The burden of malaria in pregnancy in malaria-endemic areas. American Journal of Tropical Medicine and Hygiene 64: 28–35.
View Article
Google Scholar

[12] View Article

[13] Google Scholar

[ref6] 6. Desai M, ter Kuile FO, Nosten F, McGready R, Asamoa K, et al. (2007) Epidemiology and burden of malaria in pregnancy. Lancet Infectious Disease 7: 93–104.
View Article
Google Scholar

[15] View Article

[16] Google Scholar

[ref7] 7. McGregor IA, Wilson ME, Billewicz WZ (1983) Malaria infection of the placenta in The Gambia, West Africa; its incidence and relationship to stillbirth, birthweight and placental weight. Transactions of the Royal Society of Tropical Medicine and Hygiene 77: 232–244.
View Article
Google Scholar

[18] View Article

[19] Google Scholar

[ref8] 8. Menendez C (1996) An immunological hypothesis to explain the enhanced susceptibility to malaria during pregnancy: Reply. Parasitology Today 12: 41–42.
View Article
Google Scholar

[21] View Article

[22] Google Scholar

[ref9] 9. Menendez C, Ordi J, Ismail MR, Ventura PJ, Aponte JJ, et al. (2000) The impact of placental malaria on gestational age and birth weight. Journal of Infectious Diseases 181: 1740–1745.
View Article
Google Scholar

[24] View Article

[25] Google Scholar

[ref10] 10. Mutabingwa TK, Bolla MC, Li JL, Domingo GJ, Li X, et al. (2005) Maternal malaria and gravidity interact to modify infant susceptibility to malaria. PLoS Medicine 2: e407.
View Article
Google Scholar

[27] View Article

[28] Google Scholar

[ref11] 11. Rogerson SJ, Hviid L, Duffy PE, Leke RF, Taylor DW (2007) Malaria in pregnancy: pathogenesis and immunity. Lancet Infectious Disease 7: 105–117.
View Article
Google Scholar

[30] View Article

[31] Google Scholar

[ref12] 12. Kwiatkowski DP (2005) How malaria has affected the human genome and what human genetics can teach us about malaria. American Journal of Human Genetics 77: 171–192.
View Article
Google Scholar

[33] View Article

[34] Google Scholar

[ref13] 13. Mackinnon MJ, Mwangi TW, Snow RW, Marsh K, Williams TN (2005) Heritability of malaria in Africa. PLoS Medicine 2: e340.
View Article
Google Scholar

[36] View Article

[37] Google Scholar

[ref14] 14. Jallow M, Teo YY, Small KS, Rockett KA, Deloukas P, et al. (2009) Genome-wide and fine-resolution association analysis of malaria in West Africa. Nature Genetics.
View Article
Google Scholar

[39] View Article

[40] Google Scholar

[ref15] 15. Sikora M, Ferrer-Admetlla A, Laayouni H, Menendez C, Mayor A, et al. (2009) A variant in the gene FUT9 is associated with susceptibility to placental malaria infection. Human Molecular Genetics 18: 3136–3144.
View Article
Google Scholar

[42] View Article

[43] Google Scholar

[ref16] 16. Guan Y, Stephens M (2008) Practical issues in imputation-based association mapping. PLoS Genetics 4: e1000279.
View Article
Google Scholar

[45] View Article

[46] Google Scholar

[ref17] 17. Sikora M, Laayouni H, Calafell F, Comas D, Bertranpetit J (2011) A genomic analysis identifies a novel component in the genetic structure of sub-Saharan African populations. European Journal of Human Genetics 19: 84–88.
View Article
Google Scholar

[48] View Article

[49] Google Scholar

[ref18] 18. Grantham R (1974) Amino acid difference formula to help explain protein evolution. Science 185: 862–864.
View Article
Google Scholar

[51] View Article

[52] Google Scholar

[ref19] 19. Yu K, Li Q, Bergen AW, Pfeiffer RM, Rosenberg PS, et al. (2009) Pathway analysis by adaptive combination of P-values. Genetic Epidemiology 33: 700–709.
View Article
Google Scholar

[54] View Article

[55] Google Scholar

[ref20] 20. The Wellcome Trust Case Control Consortium (2007) Genome-wide association study of 14,000 cases of seven common diseases and 3,000 shared controls. Nature 447: 661–678.
View Article
Google Scholar

[57] View Article

[58] Google Scholar

[ref21] 21. Bauer S, Groh V, Wu J, Steinle A, Phillips JH, et al. (1999) Activation of NK cells and T cells by NKG2D, a receptor for stress-inducible MICA. Science 285: 727–729.
View Article
Google Scholar

[60] View Article

[61] Google Scholar

[ref22] 22. Cordell HJ (2009) Genome-wide association studies: Detecting gene-gene interactions that underlie human diseases. Nature Reviews Genetics.
View Article
Google Scholar

[63] View Article

[64] Google Scholar

[ref23] 23. Baranzini SE, Galwey NW, Wang J, Khankhanian P, Lindberg R, et al. (2009) Pathway and network-based analysis of genome-wide association studies in multiple sclerosis. Human Molecular Genetics 18: 2078–2090.
View Article
Google Scholar

[66] View Article

[67] Google Scholar

[ref24] 24. Peng G, Luo L, Siu H, Zhu Y, Hu P, et al. (2010) Gene and pathway-based second-wave analysis of genome-wide association studies. European Journal of Human Genetics 18: 111–117.
View Article
Google Scholar

[69] View Article

[70] Google Scholar

[ref25] 25. Emily M, Mailund T, Hein J, Schauser L, Schierup MH (2009) Using biological networks to search for interacting loci in genome-wide association studies. European Journal of Human Genetics 17: 1231–1240.
View Article
Google Scholar

[72] View Article

[73] Google Scholar

[ref26] 26. Rawlings JS, Rosler KM, Harrison DA (2004) The JAK/STAT signaling pathway. Journal of Cell Science 117: 1281–1283.
View Article
Google Scholar

[75] View Article

[76] Google Scholar

[ref27] 27. Puel A, Ziegler SF, Buckley RH, Leonard WJ (1998) Defective IL7R expression in T(−)B(+)NK(+) severe combined immunodeficiency. Nature Genetics 20: 394–397.
View Article
Google Scholar

[78] View Article

[79] Google Scholar

[ref28] 28. Roato I, Gorassini E, Brunetti G, Grano M, Ciuffreda L, et al. (2007) IL-7 modulates osteoclastogenesis in patients affected by solid tumors. Annals of the New York Academy of Sciences 1117: 377–384.
View Article
Google Scholar

[81] View Article

[82] Google Scholar

[ref29] 29. van Amelsfort JM, van Roon JA, Noordegraaf M, Jacobs KM, Bijlsma JW, et al. (2007) Proinflammatory mediator-induced reversal of CD4+,CD25+ regulatory T cell-mediated suppression in rheumatoid arthritis. Arthritis and Rheumatism 56: 732–742.
View Article
Google Scholar

[84] View Article

[85] Google Scholar

[ref30] 30. Damas JK, Waehre T, Yndestad A, Otterdal K, Hognestad A, et al. (2003) Interleukin-7-mediated inflammation in unstable angina: possible role of chemokines and platelets. Circulation 107: 2670–2676.
View Article
Google Scholar

[87] View Article

[88] Google Scholar

[ref31] 31. Menendez C, Bardaji A, Sigauque B, Romagosa C, Sanz S, et al. (2008) A randomized placebo-controlled trial of intermittent preventive treatment in pregnant women in the context of insecticide treated nets delivered through the antenatal clinic. PLoS ONE 3: e1934.
View Article
Google Scholar

[90] View Article

[91] Google Scholar

[ref32] 32. Purcell S, Neale B, Todd-Brown K, Thomas L, Ferreira MA, et al. (2007) PLINK: a tool set for whole-genome association and population-based linkage analyses. American Journal of Human Genetics 81: 559–575.
View Article
Google Scholar

[93] View Article

[94] Google Scholar

[ref33] 33. Servin B, Stephens M (2007) Imputation-based analysis of association studies: candidate regions and quantitative traits. PLoS Genetics 3: e114.
View Article
Google Scholar

[96] View Article

[97] Google Scholar

[ref34] 34. Stephens M, Balding DJ (2009) Bayesian statistical methods for genetic association studies. Nature Reviews Genetics 10: 681–690.
View Article
Google Scholar

[99] View Article

[100] Google Scholar

[ref35] 35. Browning BL, Browning SR (2007) Efficient multilocus association testing for whole genome association studies using localized haplotype clustering. Genetic Epidemiology 31: 365–375.
View Article
Google Scholar

[102] View Article

[103] Google Scholar

[ref36] 36. Browning SR (2006) Multilocus association mapping using variable-length Markov chains. American Journal of Human Genetics 78: 903–913.
View Article
Google Scholar

[105] View Article

[106] Google Scholar

[ref37] 37. Scheet P, Stephens M (2006) A fast and flexible statistical model for large-scale population genotype data: applications to inferring missing genotypes and haplotypic phase. American Journal of Human Genetics 78: 629–644.
View Article
Google Scholar

[108] View Article

[109] Google Scholar

[ref38] 38. Shannon P, Markiel A, Ozier O, Baliga NS, Wang JT, et al. (2003) Cytoscape: a software environment for integrated models of biomolecular interaction networks. Genome Research 13: 2498–2504.
View Article
Google Scholar

[111] View Article

[112] Google Scholar

[ref39] 39. Gentleman RC, Carey VJ, Bates DM, Bolstad B, Dettling M, et al. (2004) Bioconductor: open software development for computational biology and bioinformatics. Genome Biol 5: R80.
View Article
Google Scholar

[114] View Article

[115] Google Scholar

[ref40] 40. Gao J, Ade AS, Tarcea VG, Weymouth TE, Mirel BR, et al. (2009) Integrating and annotating the interactome using the MiMI plugin for cytoscape. Bioinformatics 25: 137–138.
View Article
Google Scholar

[117] View Article

[118] Google Scholar

[ref41] 41. Yip KY, Yu H, Kim PM, Schultz M, Gerstein M (2006) The tYNA platform for comparative interactomics: a web tool for managing, comparing and mining multiple networks. Bioinformatics 22: 2968–2970.
View Article
Google Scholar

[120] View Article

[121] Google Scholar

[ref42] 42. Patterson N, Price AL, Reich D (2006) Population structure and eigenanalysis. PLoS Genetics 2: e190.
View Article
Google Scholar

[123] View Article

[124] Google Scholar

[ref43] 43. Li JZ, Absher DM, Tang H, Southwick AM, Casto AM, et al. (2008) Worldwide human relationships inferred from genome-wide patterns of variation. Science 319: 1100–1104.
View Article
Google Scholar

[126] View Article

[127] Google Scholar

[ref44] 44. The International HapMap Consortium (2007) A second generation human haplotype map of over 3.1 million SNPs. Nature 449: 851–861.
View Article
Google Scholar

[129] View Article

[130] Google Scholar

Figures

Abstract

Introduction

Results

Genotyping quality and population structure

Association analysis

Gene-gene interactions and network analysis

Discussion

Materials and Methods

Ethics Statement

Study subjects

Genotyping

Statistical analysis

Supporting Information

Figure S1.

Acknowledgments

Author Contributions

References