Exome-wide age-of-onset analysis reveals exonic variants in<i>ERN1, TACR3</i>and<i>SPPL2C</i>associated with Alzheimer’s disease

He, Liang; Loika, Yury; Park, Yong‐Jin; Bennett, David A.; Kellis, M; Kulminski, Alexander M.

doi:10.1101/2020.01.28.923789

Cited by 2 publications

(3 citation statements)

References 98 publications

(129 reference statements)

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“…2 In response to this observation, there has been a shift to start using exome sequencing (ES) or genome sequencing (GS) to help capture rare and/or coding variants that contribute to AD risk, which has led to several recent initial successes. [7][8][9][10][11][12][13][14][15] In the United States, the Alzheimer Disease Sequencing Project (ADSP) has taken a leading role in the sequencing of AD-related samples at scale, with resultant data being made publicly available to researchers to generate new insights into the genetic etiology of AD. The ADSP has pursued both "whole" ES (WES) and "whole" GS (WGS) approaches (although it should be noted that these for now do not actually provide whole coverage due to technical limitations), where most recently, the focus is increasingly on GS.…”

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A Fast and Robust Strategy to Remove Variant-Level Artifacts in Alzheimer Disease Sequencing Project Data

et al. 2022

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Background and ObjectivesExome sequencing (ES) and genome sequencing (GS) are expected to be critical to further elucidate the missing genetic heritability of Alzheimer disease (AD) risk by identifying rare coding and/or noncoding variants that contribute to AD pathogenesis. In the United States, the Alzheimer Disease Sequencing Project (ADSP) has taken a leading role in sequencing AD-related samples at scale, with the resultant data being made publicly available to researchers to generate new insights into the genetic etiology of AD. To achieve sufficient power, the ADSP has adapted a study design where subsets of larger AD cohorts are collected and sequenced across multiple centers, using a variety of sequencing platforms. This approach may lead to variable variant quality across sequencing centers and/or platforms. In this study, we sought to implement and evaluate filters that can be applied fast to robustly remove variant-level artifacts in the ADSP data.MethodsWe implemented a robust quality control procedure to handle ADSP data. We evaluated this procedure while performing exome-wide and genome-wide association analyses on AD risk using the latest ADSP whole ES (WES) and whole GS (WGS) data releases (NG00067.v5).ResultsWe observed that many variants displayed large variation in allele frequencies across sequencing centers/platforms and contributed to spurious association signals with AD risk. We also observed that sequencing platform/center adjustment in association models could not fully account for these spurious signals. To address this issue, we designed and implemented variant filters that could capture and remove these center-specific/platform-specific artifactual variants.DiscussionWe derived a fast and robust approach to filter variants that represent sequencing center-related or platform-related artifacts underlying spurious associations with AD risk in ADSP WES and WGS data. This approach will be important to support future robust genetic association studies on ADSP data, as well as other studies with similar designs.

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A Fast and Robust Strategy to Remove Variant-Level Artifacts in Alzheimer Disease Sequencing Project Data

et al. 2022

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“…Despite these important advances, most risk variants identified so far have common allele frequencies and it's estimated that only about half of AD's genetic heritability has been captured, such that much of AD's genetic component remains to be identified 2 . In response to this observation, there has been a shift to start using whole-exome sequencing (WES) or whole-genome sequencing (WGS) to help capture rare and/or coding variants that contribute to AD risk, which has led to several recent initial successes [7][8][9][10][11][12][13][14][15] .…”

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A fast and robust strategy to remove variant level artifacts in Alzheimer’s Disease Sequencing Project data

Belloy

Guen

Eger

et al. 2021

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Whole-exome sequencing (WES) and whole-genome sequencing (WGS) are expected to be critical to further elucidate the missing genetic heritability of Alzheimer’s disease (AD) risk by identifying rare coding and/or noncoding variants that contribute to AD pathogenesis. In the United States, the Alzheimer’s Disease Sequencing Project (ADSP) has taken a leading role in sequencing AD-related samples at scale, with the resultant data being made publicly available to researchers to generate new insights into the genetic etiology of AD. In order to achieve sufficient power, the ADSP has adapted a study design where subsets of larger AD cohorts are collected and sequenced across multiple centers, using a variety of sequencing kits. This approach may lead to variable variant quality across sequencing centers and/or kits. Here, we performed exome-wide and genome-wide association analyses on AD risk using the latest ADSP WES and WGS data releases. We observed that many variants displayed large variation in allele frequencies across sequencing centers/kits and contributed to spurious association signals with AD risk. We also observed that sequencing kit/center adjustment in association models could not fully account for these spurious signals. To address this issue, we designed and implemented novel filters that aim to capture and remove these center/kit-specific artifactual variants. We conclude by deriving a novel, fast, and robust approach to filter variants that represent sequencing center- or kit-related artifacts underlying spurious associations with AD risk in ADSP WES and WGS data. This approach will be important to support future robust genetic association studies on ADSP data, as well as other studies with similar designs.Author SummaryNext generation sequencing data represents a highly valuable resource to uncover rare coding and/or noncoding genetic variants that contribute to Alzheimer’s disease risk. In order to achieve large sample sizes that are required for such data, the Alzheimer’s Disease Sequencing Project (ADSP) has taken the leading role in sequencing Alzheimer’s disease related samples at scale in the United States. The ADSP’s study design however leads to variable variant quality across the involved sequencing centers, necessitating a quality control approach that ensures robust genetic association analyses. Here, we present and validate a rigorous quality control pipeline, where we specifically developed a new strategy to handle inter-center variant quality issues in the ADSP. In doing so, we provide a first glance into exome- and genome-wide associations with Alzheimer’s disease risk using the latest releases of ADSP data (respectively 20.5k and 16.9k individuals). In sum, our pipeline is important to support future robust genetic association studies on ADSP data, as well as other studies with similar design. This in turn will contribute to accelerating Alzheimer’s disease gene discovery and gene-driven therapy development.

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Exome-wide age-of-onset analysis reveals exonic variants inERN1, TACR3andSPPL2Cassociated with Alzheimer’s disease

Cited by 2 publications

References 98 publications

A Fast and Robust Strategy to Remove Variant-Level Artifacts in Alzheimer Disease Sequencing Project Data

A Fast and Robust Strategy to Remove Variant-Level Artifacts in Alzheimer Disease Sequencing Project Data

A fast and robust strategy to remove variant level artifacts in Alzheimer’s Disease Sequencing Project data

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