Practical aspects of genome-wide association interaction analysis

Gusareva, Elena S.; Steen, Kristel Van

doi:10.1007/s00439-014-1480-y

Cited by 33 publications

(40 citation statements)

References 103 publications

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“…Any GWAI analysis involves making choices about the input data (e.g., filtering using candidate genes or using prior 393 biological knowledge), about LD-pruning thresholds, about adjusting for lower order effects (and how to encode 394 these), and about the selection of the analytical tool (e.g., non-parametric, semi-parametric or fully parametric), as 395 well as, the corrective method for multiple testing (Gusareva and Van Steen 2014 …”

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confidence: 99%

A cautionary note on the impact of protocol changes for genome-wide association SNP × SNP interaction studies: an example on ankylosing spondylitis

2015

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Genome-wide association interaction (GWAI) studies have increased in popularity. Yet to date, no 13 standard protocol exists. In practice, any GWAI workflow involves making choices about quality control strategy, 14SNP filtering, linkage disequilibrium (LD) pruning, analytic tool to model or to test for genetic interactions. Each of 15 these can have an impact on the final epistasis findings and may affect their reproducibility in follow-up analyses. 16Choosing an analytic tool is not straightforward, as different such tools exist and current understanding about their 17 performance is based on often very particular simulation settings. In the present study, we wish to create awareness 18 for the impact of (minor) changes in a GWAI analysis protocol can have on final epistasis findings. In particular, we

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confidence: 99%

A cautionary note on the impact of protocol changes for genome-wide association SNP × SNP interaction studies: an example on ankylosing spondylitis

2015

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“…In addition, we considered the influence of unequal sample sizes. As epistasis analytic tool, we relied on MB-MDR analytics, which should be seen as part of an entire analysis pipeline that involves making marker selection choices and performing post-analysis steps to validate and replicate findings, as well as seeking biological evidence for flagged interacting regions [18].…”

Section: Discussionmentioning

confidence: 99%

“…However, the growing interest in the importance of detecting gene-gene interactions in the development and progression of complex diseases has led to the development of several tools; to name but a few: generalized linear regression models (GLM), BOOST [8], Model Based Multifactor Dimensionality Reduction (MB-MDR) [9,10], Multifactor Dimensionality Reduction (MDR) [11], Random Forest [12], PLINK [13], BiForce [14], Bayesian Models (e.g., BEAM) [15] and several others. For extensive reviews and appropriate references, please refer to [16][17][18][19][20]. However, the literature on epistasis detection in structured populations is very limited, apart from scenarios using a regression framework for association testing.…”

Section: Introductionmentioning

confidence: 99%

Performance of Model Based Multifactor Dimensionality Reduction Methods for Epistasis Detection by Controlling Population Structure

Abegaz

Lishout

John

et al. 2020

Preprint

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Abstract Background In genome-wide association studies the extent and impact of confounding due population structure has been well recognized. Inadequate handling of such confounding is likely to lead to spurious associations, hampering replication and the identification of causal variants. Several strategies have been developed for protecting associations against confounding, the most popular one being based on Principal Component Analysis. In contrast, the extent and impact of confounding due to population structure in gene-gene interaction association epistasis studies is much less investigated and understood. In particular, the role of nonlinear genetic population substructure in epistasis detection is largely under-investigated, especially outside a regression framework. Methods In order to identify causal variants in synergy, to improve interpretability and replicability of epistasis results, we introduce three strategies based on model-based multifactor dimensionality reduction approach for structured populations namely: MBMDR-PC, MBMDR-PG and MBMDR-GC. Results Simulation results comparing the performance of various approaches show that in the presence of population structure MBMDR-PC and MBMDR-PG consistently better control type I error rate at the nominal level than MBMDR-GC. Moreover, our proposed three methods of population structure correction outperform MDR-SP in terms of statistical power. Conclusion We demonstrate through extensive simulation studies the effect of various degrees of genetic population structure and relatedness on epistasis detection and propose appropriate remedial measures based on linear and nonlinear sample genetic similarity.

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“…Human genetic studies are conducted using either candidate-gene approaches or genomewide association studies (GWASs) [66]. Depending on the research question, both study designs have their own advantages, disadvantages, and limitations.…”

Section: Concluding Remarks and Future Directionsmentioning

confidence: 99%

Giving the Genes a Shuffle: Using Natural Variation to Understand Host Genetic Contributions to Viral Infections

Leist

Baric

2018

Trends in Genetics

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The laboratory mouse has proved an invaluable model to identify host factors that regulate the progression and outcome of virus-induced disease. The paradigm is to use single-gene knockouts in inbred mouse strains or genetic mapping studies using biparental mouse populations. However, genetic variation among these mouse strains is limited compared with the diversity seen in human populations. To address this disconnect, a multiparental mouse population has been developed to specifically dissect the multigenetic regulation of complex disease traits. The Collaborative Cross (CC) population of recombinant inbred mouse strains is a well-suited systems-genetics tool to identify susceptibility alleles that control viral and microbial infection outcomes and immune responses and to test the promise of personalized medicine.

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Practical aspects of genome-wide association interaction analysis

Cited by 33 publications

References 103 publications

A cautionary note on the impact of protocol changes for genome-wide association SNP × SNP interaction studies: an example on ankylosing spondylitis

A cautionary note on the impact of protocol changes for genome-wide association SNP × SNP interaction studies: an example on ankylosing spondylitis

Performance of Model Based Multifactor Dimensionality Reduction Methods for Epistasis Detection by Controlling Population Structure

Giving the Genes a Shuffle: Using Natural Variation to Understand Host Genetic Contributions to Viral Infections

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