Last updated: 2018-05-18
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File | Version | Author | Date | Message |
---|---|---|---|---|
Rmd | 37ef62c | Peter Carbonetto | 2018-05-18 | wflow_publish(“Fig.Uk*.Rmd“) |
html | 02aae6b | Peter Carbonetto | 2018-05-18 | Revised Fig.Uk8.Rmd for analysis of testis-specific effects components. |
Rmd | e1016bb | Peter Carbonetto | 2018-05-18 | wflow_publish(c(“Fig.Uk8.Rmd”, “Fig.Uk3.Rmd”, “Fig.Uk2.Rmd”)) |
html | 64f1730 | Peter Carbonetto | 2018-05-18 | Small revision to Uk3 Rmd file, and extensive revisions to Uk2 Rmd file. |
Rmd | 73c0ebd | Peter Carbonetto | 2018-05-18 | wflow_publish(c(“Fig.Uk2.Rmd”, “Fig.Uk3.Rmd”)) |
html | 957b7e4 | Peter Carbonetto | 2018-05-18 | Created separate code chunk in Fig.Uk2.Rmd for computed correlation matrix. |
Rmd | 178efd2 | Peter Carbonetto | 2018-05-18 | wflow_publish(“Fig.Uk3.Rmd”) |
Rmd | 725c305 | Peter Carbonetto | 2018-05-16 | Added a sentence to Fig.Uk2.Rmd. |
Rmd | 04f6a21 | Peter Carbonetto | 2018-05-16 | Working on revisions to Fig.Uk2.Rmd. |
html | 04f6a21 | Peter Carbonetto | 2018-05-16 | Working on revisions to Fig.Uk2.Rmd. |
Rmd | d255419 | Peter Carbonetto | 2018-05-16 | wflow_publish(“Fig.Uk3.Rmd”) |
Rmd | cb41bec | Peter Carbonetto | 2018-05-09 | In Fig.Uk3.Rmd, added pathnames for files containing results from Gao’s analysis pipeline. |
html | cb41bec | Peter Carbonetto | 2018-05-09 | In Fig.Uk3.Rmd, added pathnames for files containing results from Gao’s analysis pipeline. |
Rmd | 0dacdff | Peter Carbonetto | 2018-05-07 | wflow_publish(“Fig.Uk3.Rmd”) |
Rmd | 80f285f | Gao Wang | 2017-09-20 | Update figures |
html | 80f285f | Gao Wang | 2017-09-20 | Update figures |
“Uk3” is the covariance matrix corresponding to the output of the ExtremeDeconvolution algorithm that was initialized with the rank3 SVD approximation of \(X^TX\). It is the pattern of sharing identified from the dominant covariance matrix (the one with the largest mixture weight).
Here we plot the correlation matrix and the first 3 eigenvectors of “Uk3”. This provides a visualization of the primary patterns of genetic sharing identified by our method, MASH. This code should closely reproduce Figure 3 of the paper.
First, we load a couple plotting packages used in the code chunks below.
library(lattice)
library(colorRamps)
We load some GTEx summary statistics, as well as some of the results generated from the MASH analysis of the GTEx data.
covmat <- readRDS(paste("../output/MatrixEQTLSumStats.Portable.Z.coved.K3.P3",
"lite.single.expanded.rds",sep = "."))
pis <- readRDS(paste("../output/MatrixEQTLSumStats.Portable.Z.coved.K3.P3",
"lite.single.expanded.V1.pihat.rds",sep = "."))$pihat
z.stat <- readRDS("../data/MatrixEQTLSumStats.Portable.Z.rds")$test.z
pi.mat <- matrix(pis[-length(pis)],ncol = 54,nrow = 22,byrow = TRUE)
names <- colnames(z.stat)
colnames(pi.mat) <-
c("ID","X'X","SVD","F1","F2","F3","F4","F5","SFA_Rank5",names,"ALL")
Compute the correlations from the \(k=3\) covariance matrix.
k <- 3
x <- cov2cor(covmat[[k]])
x[x < 0] <- 0
Next, we load the tissue indices and tissue names:
colnames(x) <- names
rownames(x) <- names
h <- read.table("../output/uk3rowindices.txt")[,1]
For the plots of the eigenvectors, we load the colours that are conventionally used to represent the tissues in plots.
missing.tissues <- c(7,8,19,20,24,25,31,34,37)
color.gtex <- read.table("../data/GTExColors.txt",sep = "\t",
comment.char = '')[-missing.tissues,]
The posterior mixture weights give the relative importance of the covariance matrices for capturing patterns in the data.
barplot(colSums(pi.mat),las = 2,cex.names = 0.5)
Here we see that the SVD component has the largest weight.
Now we produce the heatmap showing the full covariance matrix.
smat <- (x[(h),(h)])
smat[lower.tri(smat)] <- NA
clrs <- colorRampPalette(rev(c("#D73027","#FC8D59","#FEE090","#FFFFBF",
"#E0F3F8","#91BFDB","#4575B4")))(64)
lat <- x[rev(h),rev(h)]
lat[lower.tri(lat)] <- NA
n <- nrow(lat)
print(levelplot(lat[n:1,],col.regions = clrs,xlab = "",ylab = "",
colorkey = TRUE,at = seq(0,1,length.out = 64),
scales = list(cex = 0.6,x = list(rot = 45))))
The eigenvectors capture the predominant patterns in the Uk3 covariance matrix.
k <- 3
vold <- svd(covmat[[k]])$v
u <- svd(covmat[[k]])$u
d <- svd(covmat[[k]])$d
v <- vold[h,] # Shuffle so correct order
names <- names[h]
color.gtex <- color.gtex[h,]
for (j in 1:3)
barplot(v[,j]/v[,j][which.max(abs(v[,j]))],names = "",cex.names = 0.5,
las = 2,main = paste0("EigenVector",j,"Uk",k),
col = as.character(color.gtex[,2]))
The first eigenvector reflects broad sharing among tissues, with all effects in the same direction; the second eigenvector captures differences between brain (and, to a less extent, testis and pituitary) vs other tissues; the third eigenvector primarily captures effects that are stronger in whole blood than elsewhere.
sessionInfo()
R version 3.4.3 (2017-11-30)
Platform: x86_64-apple-darwin15.6.0 (64-bit)
Running under: macOS High Sierra 10.13.4
Matrix products: default
BLAS: /Library/Frameworks/R.framework/Versions/3.4/Resources/lib/libRblas.0.dylib
LAPACK: /Library/Frameworks/R.framework/Versions/3.4/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] colorRamps_2.3 lattice_0.20-35
loaded via a namespace (and not attached):
[1] workflowr_1.0.1.9000 Rcpp_0.12.16 digest_0.6.15
[4] rprojroot_1.3-2 R.methodsS3_1.7.1 grid_3.4.3
[7] backports_1.1.2 git2r_0.21.0 magrittr_1.5
[10] evaluate_0.10.1 stringi_1.1.7 whisker_0.3-2
[13] R.oo_1.21.0 R.utils_2.6.0 rmarkdown_1.9
[16] tools_3.4.3 stringr_1.3.0 yaml_2.1.18
[19] compiler_3.4.3 htmltools_0.3.6 knitr_1.20
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