Genome-Wide Association Studies (GWAS) PDF

Summary

This document is a lecture on Genome-Wide Association Studies (GWAS). It covers the basics of GWAS, including its aims, experimental workflow, and visualization methods. It also discusses different types of analysis techniques commonly used for GWAS data.

Full Transcript

Genome-Wide Association Studies
(GWAS)

Instructor: Dr. Parisa Shooshtari

MBI 3100 – Lecture 11
November 13, 2024

1
 Genome-Wide Association Studies (GWAS) in One Slide
A A A 62% A
Cases
Single Nucleotide A C C
38% C
Polymorphism (SNP)
Cases (10,000)
People with disease
C
SNP
A A C
49% A
Controls
A C C 51% C

Manhattan Plot Controls (10,000)
for Schizophrenia People without disease

Is there a significant shift in
Hundreds of Genomic Regions (Loci) with allele frequency between cases
Significant Association to Disease and controls?
Significance Level

P Value of
5×10-8 Genetic Association
Per SNP

Image from: Ripke et.al., Nature 2014 Chromosome
2
Zoom In To a GWAS Locus

3
 Outline
Introduction

Experimental Workflow of GWAS
Selecting Study Population
Genotyping
Data Processing

GWAS Results

4
 Outline
Introduction

Experimental Workflow of GWAS
Selecting Study Population
Genotyping
Data Processing

GWAS Results

5
 What is GWAS?
Genome-wide association studies (GWAS) aim to identify associations of
genotypes with phenotypes by testing for differences in the allele frequency of
genetic variants between individuals who are ancestrally similar but differ
phenotypically.

GWAS can consider
Ø copy-number variants or
Ø sequence variations in the human genome,
Ø although the most commonly studied genetic variants in GWAS are single-
nucleotide polymorphisms (SNPs).

6
 Difference Between Genome-Wide Association Studies
(GWAS), Whole-Genome Sequencing (WGS), and Whole-
Exome Sequencing (WES)

Genome-wide association studies (GWAS) generally involve targeted genotyping
of specific and pre-selected variants using microarrays.

Whole-exome sequencing (WES) and whole-genome sequencing (WGS) studies
aim to capture all genetic variation.

Strictly speaking, both WES and WGS studies are also GWAS, although in the
literature ‘GWAS’ mostly refers to genome-wide studies of common variants and
is sometimes considered separate from WGS and WES studies.

7
 Common vs. Rare Genetic Variants
Declaring a variant as common or rare
is population-specific and cannot be
generalized across populations.

Common variants: Variants with a
minor allele frequency above 5%.

Although as population sizes grow this
threshold can be as low as 1% as
researchers typically adhere to a
minimum minor allele count (for
example, at least 100 individuals who
carry at least one copy of the minor Manolio, A., et. al. “Finding missing heritability od complex diseases”, Nat. Rev., 2009
allele.) 8
 Question: What is the main difference
between GWAS vs. WES/WGS?

Question: In GWAS do we mostly consider
rare or common variants? Why?

9
 Some Statistics on GWAS Studies

> 5,700 GWAS > 3,300 Traits > 1,000,000
Studies (phenotypes) participants

Thousands of
Hundreds of associated &
genomic loci replicable variants
(SNPs)
10
 Challenges in Interpreting the Associations

Variants are correlated
These variants are often with causal and non-
Individual variants confer
associated with many causal variants that are
very little risk
other traits physically close

Direct biological, causal inferences is very complicated
11
Individual variants confer
very little risk Individual Variants Confer Very Little Risk

Manolio, A., et. al. “Finding missing heritability od complex diseases”, Nat. Rev., 2009 12
These variants are often
associated with many
other traits
Variants Associated to Multiple Traits
Autoimmune Thyroid Disease
Position on Chromosome (AITD)
6 (Mbp) Celiac Disease (CEL)
Position on Chromosome 6 (Mbp)
Position on Chromosome 6 Position on Chromosome 6
89.98 90.48 90.98 91.48 91.98 89.98 90.48 90.98 91.48 91.98

Posterior 6 Posterior
6
0.95 0.23

CEL GWAS
ATD GWAS

−log10(P)
−log10(P)

4 4

2 2

0 0
0 0

Multiple
Position Sclerosis (MS)
on Chromosome 6 (Mbp) Position on
on IChromosome
Type
Position Diabetes (T1D)66 (Mbp)
Chromosome (Mbp)
Position on Chromosome 6 Position on Chromosome 6
89.98 90.48 90.98 91.48 91.98 89.98
89.98 90.48
90.48 90.98
90.98 91.48
91.48 91.98
91.98

6 Posterior
Posterior Posterior
0.48 0.85
0.59
6
GWAS
T1DGWAS
−log10(P)
MS GWAS

−log10(P)
−log10(P)

4
4
IBD

2
2
0 00
0 00
13
Shooshtari, et. al. AJHG 2017
Variants are correlated with causal and non-causal variants that
are physically close due to Linkage Disequilibrium (LD)
Variants are correlated
with causal and non-
causal variants that are
physically close

Association should not be
confused with causality
14
 Another Challenge in Interpreting the Associations
Another challenge is that
Ø genetic associations may differ across ancestries (e.g. European vs. African
or Asian), complicating direct comparisons between groups of individuals.

These limitations result in
Ø unclear conclusions about the biological meaning of GWAS result
Ø sometimes limiting their utility to produce mechanistic insights or to serve
as starting points for drug development.

15
 Genetic Associations May Differ Across Ancestries

16
Image: E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021
Question: What are the four main challenges that
make interpretation of GWAS results complicated?

17
 Outline
Introduction

Experimental Workflow of GWAS
Selecting Study Population
Genotyping
Data Processing

GWAS Results

18
 Experimental Workflow of GWAS

ØThe collection of DNA and phenotypic information from a group of individuals
(such as disease status and demographic information such as age and sex)
ØGenotyping of each individual using available GWAS arrays or sequencing
strategies
ØQuality control
ØImputation of untyped variants using haplotype phasing and reference
populations
ØConducting the statistical test for association
ØConducting a meta-analysis (optional)
ØSeeking an independent replication
ØInterpreting the results by conducting multiple post-GWAS analyses

19
 Experimental
Workflow of GWAS

Image: E. Uffelmann, et. al., “Genome-wide
association studies”, Nat. Rev., 2021 20
 Experimental Workflow: Data Collection
Data can be collected from study cohorts or available genetic and
phenotypic information can be used from biobanks or repositories.

Image: E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021 21
Experimental Workflow: Genotyping of Each Individual
Genotypic data can be collected using microarrays to capture
common variants, or next-generation sequencing methods for
whole-genome sequencing (WGS) or whole-exome sequencing
(WES)

Image: E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021 22
 Experimental Workflow: Quality Control
Quality control includes steps at:
ØThe wet-laboratory stage, such as genotype calling and DNA switches
ØThe dry-laboratory stages on called genotypes, such as deletion of bad single-
nucleotide polymorphisms (SNPs)
ØIndividuals, detection of population strata in the sample and calculation of
principle components.

Clustering individuals
according to genetic substrata

Image: E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021 23
Experimental Workflow: Imputation of Untyped Variants
Genotypic data can be phased, and untyped genotypes imputed using
information from matched reference populations from repositories such as
1000 Genomes Project or TopMed.
In this example, genotypes of SNP1 and SNP3 are imputed based on the directly
assayed genotypes of other SNPs.

Image: E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021 24
 Experimental Workflow: Genetic Association Test
Genetic association tests are run for each genetic variant, using an appropriate
model (for example, additive, non-additive, linear or logistic regression).
Confounders are corrected for, including population strata, and multiple testing
needs to be controlled.
Output is inspected for unusual patterns and summary statistics are generated.
A A A 62% A
Cases
Single Nucleotide A C C
38% C
Polymorphism (SNP)
Cases (10,000)
People with disease
C
SNP
A A C 49% A
Controls
A C C 51% C

Manhattan Plot Controls (10,000)
for Schizophrenia People without disease

Is there a significant shift in
Hundreds of Genomic Regions (Loci) with allele frequency between cases
Significant Association to Disease and controls?
Significance Level

P Value of
5×10-8 Genetic Association
Per SNP

25
E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021 Image from: Ripke et.al., Nature 2014 Chromosome
 Experimental Workflow: Meta-Analysis
Results from multiple smaller cohorts are
combined using standardized statistical pipelines.
E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021

GWAS of Post-Traumatic Stress Disorder (PTSD)
European Ancestry
African Ancestry

Nievergelt, et. al., “International meta-analysis of PTSD genome-wide association 26
studies identifies sex- and ancestry-specific genetic risk loci”, Nat. Com. 2019
 Experimental Workflow: Replication
Results can be replicated using internal replication or external replication in an
independent cohort.
For external replication, the independent cohort must be ancestrally matched
and not share individuals or family members with the discovery cohort.

Image: E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021 27
 Experimental Workflow: Post-GWAS Analysis
In silico analysis of genome-wide association studies (GWAS), using
information from external resources. This can include:
ØIn silico fine-mapping
ØSNP to gene mapping
ØGene to function mapping
ØPathway analysis
ØGenetic correlation analysis
ØMendelian randomization
ØPolygenic risk prediction.
E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021

Also, after GWAS, functional hypotheses can be tested using
experimental techniques such as CRISPR or massively parallel reporter
assays, or results can be validated in a human trait/disease model. 28
Question: Can you
explain each step of the
GWAS experimental
workflow?

5 minutes to review this
in your group.

Image: E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021 29
 Outline
Introduction

Experimental Workflow of GWAS
Selecting Study Population
Genotyping
Data Processing

GWAS Results

30
 Selecting Study Population
GWAS often require very large sample sizes to identify reproducible genome-
wide significant associations.
Ø The desired sample size can be determined using power calculations in software tools such
as CaTS14 or GPC15.

Case and controls Quantitative
Study designs
(when the trait is (when the trait is
binary) quantitative)

The choice of data resource and study design for a GWAS depends on the
required sample size, the experimental question and the availability of pre-
existing data or the ease with which new data can be collected.

31
 Selecting Study Population (cont.)
Assembling data sets of a sufficient size to run a well-powered GWAS
for a complex trait requires major investments of time and money
that go beyond the capacity of most individual laboratories.

However, there are several excellent public resources available that
provide access to large cohorts with both genotypic and phenotypic
information, and the majority of GWAS are conducted using these
pre-existing resources.

Even when new data have been collected in-house, these will
typically be co-analysed with data from pre-existing resources

32
 Outline
Introduction

Experimental Workflow of GWAS
Selecting Study Population
Genotyping
Data Processing

GWAS Results

33
 Genotyping

NGS for both
Microarrays for
common and rare
common variants
variants

Microarray-based genotyping is the most commonly used method for
obtaining genotypes for GWAS owing to the current cost of next-
generation sequencing.
WGS (which determines nearly every genotype of a full genome) is
preferred over WES and microarrays.
WGS is expected to become the method of choice over the next couple
of years with the increasing availability of low-cost WGS technology.
34
 Outline
Introduction

Experimental Workflow of GWAS
Selecting Study Population
Genotyping
Data Processing

GWAS Results

35
 Data Processing: Input Files
Input files for a GWAS include

ØAnonymized individual ID numbers
ØCoded family relations between individuals
ØSex
ØPhenotype information (e.g. case/control)
ØCovariates
ØGenotype calls for all called variants (e.g. SNPs)
ØInformation on the genotyping batch

36
 Data Processing: Input Files (cont.)
Data format in PLINK (PED and MAP files)

The PED file is a white-space (space or tab)
delimited file. The first six columns are
mandatory:
1. Family ID
2. Individual ID
3. Paternal ID
4. Maternal ID
5. Sex (1=male; 2=female; other=unknown)
6. Phenotype (e.g. disease/control)
PLINK have been specifically designed to analyse genetic data. 37
 Data Processing: Input Files (cont.)
Data format in PLINK (PED and MAP files)

Each line of the MAP file describes
a single marker and must contain
exactly 4 columns:
1. chromosome (1-22, X, Y or 0 if
unplaced)
2. rs# or SNP identifier
3. Genetic distance (morgans)
4. Base-pair position (bp units)

In genetics, a centimorgan (cM) is a unit for measuring genetic linkage. It is defined as the distance between chromosome positions (also
termed loci or markers) for which the expected average number of intervening chromosomal crossovers in a single generation is 0.01. It is
often used to infer distance along a chromosome. One centimorgan corresponds to about 1 million base pairs in humans on average.38
Question: Can you give a list of information you
can find in the input files from genotyping?

39
 Data Processing: Quality Control
Following input of the data, generating reliable results from GWAS
requires careful quality control. Some example steps include:

ØRemoving rare variants
ØFiltering SNPs that are missing from a fraction of individuals in the cohort
ØIdentifying and removing genotyping errors
ØEnsuring that phenotypes are well matched with genetic data, often by
comparing self-reported sex versus sex based on the X and Y chromosomes.

PLINK have been specifically designed to analyse genetic
data and can be used to conduct many of these quality
control steps.
Link to PLINK: http://zzz.bwh.harvard.edu/plink/ 40
 Data Processing: Imputation
After quality control, variants usually undergo phasing and are
imputed using a sequenced haplotype reference panel such as the
1000 Genomes Project or TOPMed, which involves the statistical
inference of genotypes that have not been assayed directly.

Imputation servers:
Michigan Imputation Server and
TOPMed

E. Uffelmann, et. al., “Genome-wide association studies”, Nat. Rev., 2021
Local tools:
IMPUTE2, BEAGLE, MACH and
SHAPEIT2

41
 Data Processing: Imputation (cont.)
Imputation involves several steps:

ØStatistically phase individual genotypes
ØDecide whether to use hard calls or weight for uncertainty
ØSelect an appropriate reference population panel
ØConvert reference panel and target population into the same genomic build
ØResolve issues between different platforms, possibly remove ambiguous
SNPs
ØCheck for unusual minor allele frequencies and patterns of linkage
disequilibrium between reference panel and target data
ØImpute missing genotypes against the selected population panel
ØCheck imputation quality and possibly remove badly imputed SNPs

42
Question: What is imputation?

43
 Data Processing: Ancestry Consideration
Ancestry and relatedness must be carefully considered and accounted for in
GWAS, and indeed all genetic studies — particularly in data sets from
participants of diverse backgrounds to avoid false positive or negative genetic
signals and biased test statistics owing to population stratification. Cases and
controls should be matched by ancestry to avoid confounding.

For example, a GWAS for chopstick use where cases are defined as ‘using
chopsticks regularly’ and controls as ‘not using chopsticks’ would likely result in
cases being drawn more often from an East Asian population than controls. Not
accounting for ancestry in this study would identify associations among
variants more common in East Asian populations than other populations.

Image: E. Uffelmann, et. al., “Genome-wide
association studies”, Nat. Rev., 2021 44
 Data Processing: Ancestry Consideration (cont.)

Ancestry is usually considered in GWAS
through an iterative process using principal
component analysis.

The genotypes of all individuals are used to
define clusters of individuals with similar
genotypes.
Image: E. Uffelmann, et. al., “Genome-wide association
ØTo identify and exclude outliers, and then studies”, Nat. Rev., 2021
ØTo compute and include principal components as
covariates in subsequent GWAS regression models.

45
 Data Processing: Testing for Association

Association tests for GWAS: A A A
Cases
62% A
Single Nucleotide A C C
38% C
Polymorphism (SNP)
Cases (10,000)

ØLinear model is used, if the
People with disease
C
SNP
A A C 49% A

phenotype is continuous, such as
Controls
A C C 51% C

height, blood pressure or body mass
Manhattan Plot Controls (10,000)
for Schizophrenia People without disease

index.
Is there a significant shift in
Hundreds of Genomic Regions (Loci) with allele frequency between cases
Significant Association to Disease and controls?

ØLogistic regression model is used, if Significance Level
P Value of
5×10-8 Genetic Association

the phenotype is binary, such as the
Per SNP

presence or absence of disease. Image from: Ripke et.al., Nature 2014 Chromosome

46
 Data Processing: Testing for Association (cont.)
To account for stratification and avoid confounding
effects from demographic factors, covariates such as
age, sex and ancestry are included. The caveat is
that this may reduce statistical power for binary
traits in some samples.

When conducting a GWAS, it should be noted that
the genotypes of genetic variants that are
physically close together are not independent as
they tend to be in Linkage Disequilibrium (LD). This
dependency of tests should also be considered when
conducting a GWAS.
47
Question: Which association test model is usually
used for quantitative traits (such as height)?

Question: Which association test model is usually
used for binary traits (disease status)?

48
 Data Processing: Accounting for False Discovery
Testing millions of associations between individual genetic variants and a phenotype
of interest requires a stringent multiple-testing threshold to avoid false positives.
Recap from statistics: If you run N independent tests, in order to adjust for multiple-
testing by using Bonferroni Correction, you need to use a thresholdSingle0.05/N instead
A A A

Nucleotide A C C

of 0.05. Polymorphism (SNP)
Cases (10,000)
People with disease

The International HapMap Project and other studies have shown that there are
C
SNP
A A C

approximately 1 million independent common genetic variants across the human A C C

genome on average. Therefore, our GWAS Bonferroni testing threshold
Manhattan Plot is Controls (10,000)
People without disease
0.05/1,000,000, which is P < 5 × 10–8.
for Schizophrenia

Hundreds of Genomic Regions (Loci) with
Significant Association to Disease

Significance Level

5×10-8

Image from: Ripke et.al., Nature 2014 Chromosome 49
 Outline
Introduction

Experimental Workflow of GWAS
Selecting Study Population
Genotyping
Data Processing

GWAS Results

50
 GWAS Results: Summary Statistics
The primary output of a GWAS analysis is a list of
ØP values
ØEffect sizes, and
ØTheir directions generated from the association tests of all tested genetic
variants with a phenotype of interest.

Link to GWAS Catalog: https://www.ebi.ac.uk/gwas/home 51
52
 Diastolic Blood Pressure (Quantitative)

Risk allele frequency Odds Ratio Confidence Interval

53
 Multiple Sclerosis (Disease)
Risk allele frequency Odds Ratio Confidence Interval

54
 GWAS Results: Visualization
These data are routinely visualized using Manhattan plots and
quantile–quantile plots, generated using software tools such as R or
web platforms such as FUMA88 or LocusZoom8.
Manhattan Plot

55
 GWAS Results: Visualization (cont.)
These data are routinely visualized using Manhattan plots and
quantile–quantile plots, generated using software tools such as R or
web platforms such as FUMA88 or LocusZoom8.
Quantile-Quantile Plot (QQ-Plot)

56
Question: What is the name of a resource, where you can find
GWAS summary results?

Question: What kind of information can you obtain in this resource
for each trait?

Question: What are the two plot types that are commonly used for
visualizing GWAS results?

57
 Outline
Introduction

Experimental Workflow of GWAS
Selecting Study Population
Genotyping
Data Processing

GWAS Results

58
 PLINK Analysis Toolset

PLINK: Whole genome association analysis toolset
(https://zzz.bwh.harvard.edu/plink/)
Link to installation for PLINK 1.90 beta: (https://www.cog-
genomics.org/plink/)

59
 References
Uffelmann, E., et. al., “Genome-Wide Association Studies”, Nature
Reviews, Methods Primers, (1:59) 2021
Tam, V., “Benefits and Limitations of Genome-Wide Association
Studies”, Nature Reviews, Genetics, (volume 20) 2019
Shooshtari, et. al., “Integrative Genetic and Epigenetic Analysis
Uncovers Regulatory Mechanisms if Autoimmune Disease”, AJHG
2017
Manolio, A., et. al. “Finding missing heritability of complex diseases”,
Nat. Rev., 2009
Nievergelt, et. al., “International meta-analysis of PTSD genome-wide
association studies identifies sex- and ancestry-specific genetic risk
loci”, Nat. Com. 2019
60
 References (cont.)
Huang, H. et al. “Fine-mapping inflammatory bowel disease loci to
single variant resolution”. Nature 547, 173–178 (2017).
Ripke, S., et. al., “Biological insights from 108 schizophrenia-
associated genetic loci”, Nature, 2014.
GWAS Catalog (https://www.ebi.ac.uk/gwas/)
PLINK: Whole genome association analysis toolset
(https://zzz.bwh.harvard.edu/plink/)

61