Use of Mendelian Randomization for Identifying Risk Factors for Brain Tumors

Howell, Amy; Zheng, Jie; Haycock, Philip C; McAleenan, Alexandra; Relton, Caroline L; Martin, Richard M.; Kurian, Kathreena M.

doi:10.3389/fgene.2018.00525

Cited by 19 publications

(13 citation statements)

References 163 publications

(201 reference statements)

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“…Because of the inherent bias, it is not possible to determine the direction of causality between the serum UA level and risk of MS from the above-mentioned case-control studies. The method of MR can be used to clarify the causality of exposure factors in disease etiology (Smith and Ebrahim, 2003;Mokry et al, 2015a;Harroud and Richards, 2018;Howell et al, 2018). In MR analysis, genetic variations such as SNPs will be used as surrogate measures of genetically determined lifetime exposure of the trait of interest.…”

Section: Introductionmentioning

confidence: 99%

Serum Uric Acid Level and Multiple Sclerosis: A Mendelian Randomization Study

et al. 2020

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Previous observational studies have shown that the serum uric acid (UA) level is decreased in persons with multiple sclerosis (MS). We used the two-sample Mendelian randomization (MR) method to determine whether the serum UA level is causally associated with the risk of MS. We screened 26 single-nucleotide polymorphisms (SNPs) in association with serum UA level (p < 5 × 10 −8) from a large genome-wide meta-analysis involving 110,347 individuals. The SNP outcome effects were obtained from two large international genetic studies of MS involving 38,589 individuals and 27,148 individuals. A total of 18 SNPs, including nine proxy SNPs, were included in the MR analysis. The estimate based on SNP rs12498742 that explained the largest proportion of variance showed that the odds ratio (OR) of UA (per mg/dl increase) for MS was 1.00 [95% confidence interval (CI) 0.90-1.11; p = 0.96]. The main MR analysis based on the random effects inverse variance weighted method showed that the pooled OR was 1.05 (95% CI 0.92-1.19; p = 0.50). Although there was no evidence of net horizontal pleiotropy in MR-Egger regression (p = 0.48), excessive heterogeneity was found via Cochran's Q statistic (p = 9.6 × 10 −4). The heterogeneity showed a substantial decrease after exclusion of two outlier SNPs (p = 0.17). The pooled ORs for the other MR methods ranged from 0.89 (95% CI 0.65-1.20; p = 0.45) to 1.05 (95% CI 0.96-1.14; p = 0.29). The results of sensitivity analyses and additional analyses all showed similar pooled estimates. MR analyses by using 81 MS-associated SNPs as instrumental variables showed that genetically predicted risk of MS was not significantly associated with serum UA level. The pooled OR was 1.00 (95% CI 0.99-1.02; p = 0.74) for the main MR analysis. This MR study does not support a causal effect of genetically determined serum UA level on the risk of MS, nor does it support a causal effect of genetically determined risk of MS on serum UA level.

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Section: Introductionmentioning

confidence: 99%

Serum Uric Acid Level and Multiple Sclerosis: A Mendelian Randomization Study

et al. 2020

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“…Much of the literature on IVs assumes the first case, whereas some applications, in particular Mendelian randomisation, fall into the second category. As the two are not always clearly distinguished in the MR literature (Thanassoulis and O'Donnell 2009;Thompson 2013, 2015;Howell et al 2018), we feel it is important to highlight and discuss the differences here.…”

Section: Two Types Of Instrumental Variablesmentioning

confidence: 95%

Epidemiology, genetic epidemiology and Mendelian randomisation: more need than ever to attend to detail

Sheehan

Didelez

2019

Hum Genet

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In the current era, with increasing availability of results from genetic association studies, finding genetic instruments for inferring causality in observational epidemiology has become apparently simple. Mendelian randomisation (MR) analyses are hence growing in popularity and, in particular, methods that can incorporate multiple instruments are being rapidly developed for these applications. Such analyses have enormous potential, but they all rely on strong, different, and inherently untestable assumptions. These have to be clearly stated and carefully justified for every application in order to avoid conclusions that cannot be replicated. In this article, we review the instrumental variable assumptions and discuss the popular linear additive structural model. We advocate the use of tests for the null hypothesis of 'no causal effect' and calculation of the bounds for a causal effect, whenever possible, as these do not rely on parametric modelling assumptions. We clarify the difference between a randomised trial and an MR study and we comment on the importance of validating instruments, especially when considering them for joint use in an analysis. We urge researchers to stand by their convictions, if satisfied that the relevant assumptions hold, and to interpret their results causally since that is the only reason for performing an MR analysis in the first place.

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“…In another branch of causal discovery, Mendelian randomization (MR) uses genetic variants, such as single-nucleotide polymorphisms (SNPs), that are robustly associated with an exposure as proxies for the risk factor of interest [ 154 ], therefore eliminating confounding and reverse causation effects between the exposure of interest and outcome. Howell et al (2020) [ 155 ] used MR to assess the causal relationship of associations of 36 reported glioma risk factors obtained from a systematic MEDLINE search on observational epidemiology studies.…”

Section: Network Discovery In Glioblastomamentioning

confidence: 99%

The Role of Network Science in Glioblastoma

Lopes

Martins

Vinga

et al. 2021

Cancers

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Network science has long been recognized as a well-established discipline across many biological domains. In the particular case of cancer genomics, network discovery is challenged by the multitude of available high-dimensional heterogeneous views of data. Glioblastoma (GBM) is an example of such a complex and heterogeneous disease that can be tackled by network science. Identifying the architecture of molecular GBM networks is essential to understanding the information flow and better informing drug development and pre-clinical studies. Here, we review network-based strategies that have been used in the study of GBM, along with the available software implementations for reproducibility and further testing on newly coming datasets. Promising results have been obtained from both bulk and single-cell GBM data, placing network discovery at the forefront of developing a molecularly-informed-based personalized medicine.

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Use of Mendelian Randomization for Identifying Risk Factors for Brain Tumors

Cited by 19 publications

References 163 publications

Serum Uric Acid Level and Multiple Sclerosis: A Mendelian Randomization Study

Serum Uric Acid Level and Multiple Sclerosis: A Mendelian Randomization Study

Epidemiology, genetic epidemiology and Mendelian randomisation: more need than ever to attend to detail

The Role of Network Science in Glioblastoma

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