Session 08 - Exercises

Last updated: 2022-07-25

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Before you begin:

Make sure that R is installed on your computer
For this lab, we will use the following R libraries:

require(data.table)
require(dplyr)
require(tidyr)
require(GWASTools)
require(ggplot2)
require(patchwork)

The R template to do the exercises is here.

Case-control imbalance in GWAS

Introduction

We will use a simulated dataset consisting of 3 binary traits with different amounts of case-control imbalance, as well as a genetic data set of null SNPs to examine the null distribution of the test statistics from GWAS.

Simulate the data

We can use PLINK1.9 to simulate the genetic dataset. For \(N=10,000\) samples, Let’s simulate 10,000 variants where 5,000 are common with MAF chosen from a Uniform(0.05, 0.5) distribution and for the rare variants, we will use a Uniform(0.001, 0.01) distribution. Run the following command in R:

N <- 10e3
# Generate a configuration file specifying allele frequencies (a,b) for Uniform(a,b) distribution
write(paste0("5000 common 0.05 0.5 1 1"), "tmp/sim.config")
write(paste0("5000 rare 0.001 0.01 1 1"), "tmp/sim.config", append = TRUE)
# Run PLINK1.9
system(paste0("plink1.9 --make-bed --simulate tmp/sim.config --simulate-ncases ", N, " --simulate-ncontrols 0 --simulate-prevalence 0.1  --out tmp/cc_imb_geno"))

You should now have files tmp/cc_imb_geno.{bed,bim,fam}.

For the phenotype data simulation, we will simulate 3 phenotypes with different levels of case-control imbalance (CCR 1:9, 1:99, and 1:199). Run the following code

# get FID/IID from FAM file
sample.ids <- fread("tmp/cc_imb_geno.fam", header = FALSE)
N <- nrow(sample.ids)

## Set prevalence = 10% (CCR 1:9)
y1 <- rbinom(N, 1, prob = 0.1 )
## Set prevalence = 1% (CCR 1:99)
y2 <- rbinom(N, 1, prob = 0.01 )
## Set prevalence = 0.5% (CCR 1:199)
y3 <- rbinom(N, 1, prob = 0.005 )

# write to file
data.frame(FID = sample.ids$V1, IID = sample.ids$V2, Y1 = y1, Y2 = y2, Y3 = y3) %>%
  fwrite("tmp/cc_imb_pheno.txt", sep = "\t", na = NA, quote = FALSE)

You should now have file tmp/cc_imb_pheno.txt.

Exercises

We will assess the null distribution of our test statistics when performing association mapping using different models. Here are some things to try:

Run GWAS in REGENIE (step 2) analyzing all 3 traits as quantitative. The basic command would be

system("regenie --bed tmp/cc_imb_geno --phenoFile tmp/cc_imb_pheno.txt --step 2 --bsize 400 --qt  --ignore-pred --out <output_prefix>")

This will produce three files (one for each phenotype): <output_prefix>_Y1.regenie, <output_prefix>_Y2.regenie, <output_prefix>_Y3.regenie

Read in the three summary statistics files in R and make a QQ plot of the p-values for each phenotype. Since these are null SNPs, how does it compare to what we expect? The basic command for one phenotype would be

sumstats.y1 <- fread("<output_prefix>_Y1.regenie") %>% mutate(Pval = 10^(-LOG10P), Z = sign(BETA) * sqrt(CHISQ))
qqPlot( pval = sumstats.y1$Pval )

Make a histogram of the test statistics for each phenotype and overlay with a normal distribution. How well do they match? We will create a R function to easily make this plot for different phenotypes. The basic command for one phenotype would be

plot.sumstats.hist <- function(df, title = ""){
  df %>%
  ggplot( aes(x = Z) ) +
  geom_histogram(aes(y = ..density..), colour="black", fill="white", bins = 100) +
  stat_function(
    fun = dnorm, 
    col = "red",
    args = list(mean = mean(df$Z), sd = sd(df$Z))
  ) +
    labs(title = title)
}

# for Y1
plot.sumstats.hist(sumstats.y1, title = "Y1")

What do you observe as the case-control imbalance gets more severe?

Re-do 3 but now separate the histogram for common and rare SNPs.

First separate the data frame based on common/rare simulated SNPs. For example for trait Y1:

sumstats.y1.common <- sumstats.y1[ grepl("common", ID), ]
sumstats.y1.rare <- sumstats.y1[ grepl("rare", ID), ]

Make a histogram of the test statistics distribution at common/rare SNPs. What do you observe across the different case-control imbalances? To easily make side-by-side plots, we can use functionality from the R patchwork library (e.g. p1|p2). For example

plot.sumstats.hist(sumstats.y1.common, title = "Y1 - Common SNPs") | plot.sumstats.hist(sumstats.y1.rare, title = "Y1 - Rare SNPs")

sessionInfo()

R version 3.6.1 (2019-07-05)
Platform: x86_64-apple-darwin15.6.0 (64-bit)
Running under: macOS  10.16

Matrix products: default
BLAS:   /Library/Frameworks/R.framework/Versions/3.6/Resources/lib/libRblas.0.dylib
LAPACK: /Library/Frameworks/R.framework/Versions/3.6/Resources/lib/libRlapack.dylib

locale:
[1] en_US.UTF-8/en_US.UTF-8/en_US.UTF-8/C/en_US.UTF-8/en_US.UTF-8

attached base packages:
[1] stats     graphics  grDevices utils     datasets  methods   base     

other attached packages:
[1] workflowr_1.7.0

loaded via a namespace (and not attached):
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