missMethyl 1.30.0
The missMethyl package contains functions to analyse methylation data from Illumina’s HumanMethylation450 and MethylationEPIC beadchip. These arrays are a cost-effective alternative to whole genome bisulphite sequencing, and as such are widely used to profile DNA methylation. Specifically, missMethyl contains functions to perform SWAN normalisation (Maksimovic, Gordon, and Oshlack 2012),perform differential methylation analysis using RUVm (Maksimovic et al. 2015), differential variability analysis (Phipson and Oshlack 2014) and gene set enrichment analysis (Phipson, Maksimovic, and Oshlack 2016). As our lab’s research into specialised analyses of these arrays continues we anticipate that the package will be updated with new functions.
Raw data files are in IDAT format, which can be read into R using the
minfi package (Aryee et al. 2014). Statistical analyses are
usually performed on M-values, and \(\beta\) values are used for visualisation,
both of which can be extracted from MethylSet
data objects, which is a class
of object created by minfi. For detecting
differentially variable CpGs we recommend that the analysis is performed on
M-values. All analyses described here are performed at the CpG site level.
We will use the data in the minfiData package to
demonstrate the functions in missMethyl.
The example dataset has 6 samples across two slides. There are 3 cancer samples
and 3 normal sample. The sample information is in the targets file. An
essential column in the targets file is the Basename
column which tells us
where the idat files to be read in are located. The R commands to read in the
data are taken from the minfi User’s Guide. For
additional details on how to read the IDAT files into R, as well as information
regarding quality control please refer to the minfi
User’s Guide.
library(missMethyl)
library(limma)
library(minfi)
library(minfiData)
baseDir <- system.file("extdata", package = "minfiData")
targets <- read.metharray.sheet(baseDir)
## [1] "/home/biocbuild/bbs-3.15-bioc/R/library/minfiData/extdata/SampleSheet.csv"
targets[,1:9]
## Sample_Name Sample_Well Sample_Plate Sample_Group Pool_ID person age sex
## 1 GroupA_3 H5 <NA> GroupA <NA> id3 83 M
## 2 GroupA_2 D5 <NA> GroupA <NA> id2 58 F
## 3 GroupB_3 C6 <NA> GroupB <NA> id3 83 M
## 4 GroupB_1 F7 <NA> GroupB <NA> id1 75 F
## 5 GroupA_1 G7 <NA> GroupA <NA> id1 75 F
## 6 GroupB_2 H7 <NA> GroupB <NA> id2 58 F
## status
## 1 normal
## 2 normal
## 3 cancer
## 4 cancer
## 5 normal
## 6 cancer
targets[,10:12]
## Array Slide
## 1 R02C02 5723646052
## 2 R04C01 5723646052
## 3 R05C02 5723646052
## 4 R04C02 5723646053
## 5 R05C02 5723646053
## 6 R06C02 5723646053
## Basename
## 1 /home/biocbuild/bbs-3.15-bioc/R/library/minfiData/extdata/5723646052/5723646052_R02C02
## 2 /home/biocbuild/bbs-3.15-bioc/R/library/minfiData/extdata/5723646052/5723646052_R04C01
## 3 /home/biocbuild/bbs-3.15-bioc/R/library/minfiData/extdata/5723646052/5723646052_R05C02
## 4 /home/biocbuild/bbs-3.15-bioc/R/library/minfiData/extdata/5723646053/5723646053_R04C02
## 5 /home/biocbuild/bbs-3.15-bioc/R/library/minfiData/extdata/5723646053/5723646053_R05C02
## 6 /home/biocbuild/bbs-3.15-bioc/R/library/minfiData/extdata/5723646053/5723646053_R06C02
rgSet <- read.metharray.exp(targets = targets)
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
## Warning in readChar(con, nchars = n): truncating string with embedded nuls
The data is now an RGChannelSet
object and needs to be normalised and
converted to a MethylSet
object.
SWAN (subset-quantile within array normalization) is a within-array normalization method for Illumina 450k & EPIC BeadChips. Technical differencs have been demonstrated to exist between the Infinium I and Infinium II assays on a single Illumina HumanMethylation array (Bibikova et al. 2011, @Dedeurwaerder2011). Using the SWAN method substantially reduces the technical variability between the assay designs whilst maintaining important biological differences. The SWAN method makes the assumption that the number of CpGs within the 50bp probe sequence reflects the underlying biology of the region being interrogated. Hence, the overall distribution of intensities of probes with the same number of CpGs in the probe body should be the same regardless of assay type. The method then uses a subset quantile normalization approach to adjust the intensities of each array (Maksimovic, Gordon, and Oshlack 2012).
SWAN
can take a MethylSet
, RGChannelSet
or MethyLumiSet
as input. It
should be noted that, in order to create the normalization subset, SWAN
randomly selects Infinium I and II probes that have one, two and three
underlying CpGs; as such, we recommend using set.seed
before to ensure that
the normalized intensities will be
identical, if the normalization is repeated.
The technical differences between Infinium I and II assay designs can result in aberrant \(\beta\) value distributions (Figure 1, panel “Raw”). Using SWAN corrects for the technical differences between the Infinium I and II assay designs and produces a smoother overall \(\beta\) value distribution (Figure 1, panel “SWAN”).
mSet <- preprocessRaw(rgSet)
mSetSw <- SWAN(mSet,verbose=TRUE)
## [SWAN] Preparing normalization subset
## 450k
## [SWAN] Normalizing methylated channel
## [SWAN] Normalizing array 1 of 6
## [SWAN] Normalizing array 2 of 6
## [SWAN] Normalizing array 3 of 6
## [SWAN] Normalizing array 4 of 6
## [SWAN] Normalizing array 5 of 6
## [SWAN] Normalizing array 6 of 6
## [SWAN] Normalizing unmethylated channel
## [SWAN] Normalizing array 1 of 6
## [SWAN] Normalizing array 2 of 6
## [SWAN] Normalizing array 3 of 6
## [SWAN] Normalizing array 4 of 6
## [SWAN] Normalizing array 5 of 6
## [SWAN] Normalizing array 6 of 6
par(mfrow=c(1,2), cex=1.25)
densityByProbeType(mSet[,1], main = "Raw")
densityByProbeType(mSetSw[,1], main = "SWAN")
Poor quality probes can be filtered out based on the detection p-value. For this example, to retain a CpG for further analysis, we require that the detection p-value is less than 0.01 in all samples.
detP <- detectionP(rgSet)
keep <- rowSums(detP < 0.01) == ncol(rgSet)
mSetSw <- mSetSw[keep,]
Now that the data has been SWAN
normalised we can extract \(\beta\) and
M-values from the object. We prefer to add an offset to the methylated
and unmethylated intensities when calculating M-values, hence we extract
the methylated and unmethylated channels separately and perform our own
calculation. For all subsequent analyses we use a random selection of
20000 CpGs to reduce computation time.
set.seed(10)
mset_reduced <- mSetSw[sample(1:nrow(mSetSw), 20000),]
meth <- getMeth(mset_reduced)
unmeth <- getUnmeth(mset_reduced)
Mval <- log2((meth + 100)/(unmeth + 100))
beta <- getBeta(mset_reduced)
dim(Mval)
## [1] 20000 6
par(mfrow=c(1,1))
plotMDS(Mval, labels=targets$Sample_Name, col=as.integer(factor(targets$status)))
legend("topleft",legend=c("Cancer","Normal"),pch=16,cex=1.2,col=1:2)
An MDS plot (Figure 2) is a good sanity check to make sure samples cluster together according to the main factor of interest, in this case, cancer and normal.
To test for differential methylation we use the limma
package (Smyth 2005), which employs an empirical Bayes framework based on
Guassian model theory. First we need to set up the design matrix.
There are a number of ways to do this, the most straightforward is directly from
the targets file. There are a number of variables, with the status
column
indicating cancer/normal samples. From the person
column of the targets
file, we see that the cancer/normal samples are matched, with 3 individuals
each contributing both a cancer and normal sample. Since the
limma model framework can handle any experimental
design which can be summarised by a design matrix, we can take into account the
paired nature of the data in the analysis. For more complicated experimental
designs, please refer to the limma User’s Guide.
group <- factor(targets$status,levels=c("normal","cancer"))
id <- factor(targets$person)
design <- model.matrix(~id + group)
design
## (Intercept) idid2 idid3 groupcancer
## 1 1 0 1 0
## 2 1 1 0 0
## 3 1 0 1 1
## 4 1 0 0 1
## 5 1 0 0 0
## 6 1 1 0 1
## attr(,"assign")
## [1] 0 1 1 2
## attr(,"contrasts")
## attr(,"contrasts")$id
## [1] "contr.treatment"
##
## attr(,"contrasts")$group
## [1] "contr.treatment"
Now we can test for differential methylation using the lmFit
and eBayes
functions from limma. As input data we use the matrix of
M-values.
fit.reduced <- lmFit(Mval,design)
fit.reduced <- eBayes(fit.reduced, robust=TRUE)
The numbers of hyper-methylated (1) and hypo-methylated (-1) can be
displayed using the decideTests
function in limma
and the top 10 differentially methylated CpGs for cancer versus normal
extracted using topTable
.
summary(decideTests(fit.reduced))
## (Intercept) idid2 idid3 groupcancer
## Down 6967 0 117 589
## NotSig 3348 20000 19878 18938
## Up 9685 0 5 473
top<-topTable(fit.reduced,coef=4)
top
## logFC AveExpr t P.Value adj.P.Val B
## cg16969623 4.742565 -1.3204047 18.31931 5.103885e-06 0.02964104 4.436929
## cg24115221 4.254567 -0.4385152 16.35067 9.270086e-06 0.02964104 4.045795
## cg13692446 4.352444 0.2914579 15.64897 1.166356e-05 0.02964104 3.885023
## cg11334818 4.034745 0.9316454 15.33152 1.298319e-05 0.02964104 3.808085
## cg10341556 4.983097 -1.5837089 15.39833 1.376711e-05 0.02964104 3.753400
## cg17815252 3.688425 -2.3665568 14.67515 1.631705e-05 0.02964104 3.640037
## cg24331301 3.840967 -1.4279686 14.46660 1.758216e-05 0.02964104 3.583971
## cg26976732 3.840728 -0.9378972 14.38568 1.810412e-05 0.02964104 3.561851
## cg26328335 3.725002 0.3428019 14.18624 1.947077e-05 0.02964104 3.506453
## cg22196952 4.129116 -2.2957234 13.99646 2.104425e-05 0.02964104 3.445952
Note that since we performed our analysis on M-values, the logFC
and
AveExpr
columns are computed on the M-value scale. For interpretability
and visualisation we can look at the \(\beta\) values. The \(\beta\) values for
the top 4 differentially methylated CpGs shown in Figure 3.
cpgs <- rownames(top)
par(mfrow=c(2,2))
for(i in 1:4){
stripchart(beta[rownames(beta)==cpgs[i],]~design[,4],method="jitter",
group.names=c("Normal","Cancer"),pch=16,cex=1.5,col=c(4,2),ylab="Beta values",
vertical=TRUE,cex.axis=1.5,cex.lab=1.5)
title(cpgs[i],cex.main=1.5)
}
Like other platforms, 450k array studies are subject to unwanted technical variation such as batch effects and other, often unknown, sources of variation. The adverse effects of unwanted variation have been extensively documented in gene expression array studies and have been shown to be able to both reduce power to detect true differences and to increase the number of false discoveries. As such, when it is apparent that data is significantly affected by unwanted variation, it is advisable to perform an adjustment to mitigate its effects.
missMethyl provides a limma inspired interface to functions from the CRAN package ruv, which enable the removal of unwanted variation when performing a differential methylation analysis (Maksimovic et al. 2015).
RUVfit
uses the RUV-inverse method by default, as this does not require the
user to specify a \(k\) parameter. The ridged version of RUV-inverse is also
available by setting method = rinv
. The RUV-2 and RUV-4 functions can also
be used by setting method = ruv2
or method = ruv4
, respectively, and
specifying an appropriate value for k (number of components of unwanted
variation to remove) where \(0 \leq k < no. samples\).
All of the methods rely on negative control features to accurately estimate the components of unwanted variation. Negative control features are probes/genes/etc. that are known a priori to not truly be associated with the biological factor of interest, but are affected by unwanted variation. For example, in a microarray gene expression study, these could be house-keeping genes or a set of spike-in controls. Negative control features are extensively discussed in Gagnon-Bartsch and Speed (2012) and Gagnon-Bartsch et al. (2013). Once the unwanted factors are accurately estimated from the data, they are adjusted for in the linear model that describes the differential analysis.
If the negative control features are not known a priori, they can be identified empirically. This can be achieved via a 2-stage approach, RUVm. Stage 1 involves performing a differential methylation analysis using RUV-inverse (by default) and the 613 Illumina negative controls (INCs) as negative control features. This will produce a list of CpGs ranked by p-value according to their level of association with the factor of interest. This list can then be used to identify a set of empirical control probes (ECPs), which will capture more of the unwanted variation than using the INCs alone. ECPs are selected by designating a proportion of the CpGs least associated with the factor of interest as negative control features; this can be done based on either an FDR cut-off or by taking a fixed percentage of probes from the bottom of the ranked list. Stage 2 involves performing a second differential methylation analysis on the original data using RUV-inverse (by default) and the ECPs. For simplicity, we are ignoring the paired nature of the cancer and normal samples in this example.
# get M-values for ALL probes
meth <- getMeth(mSet)
unmeth <- getUnmeth(mSet)
M <- log2((meth + 100)/(unmeth + 100))
# setup the factor of interest
grp <- factor(targets$status, labels=c(0,1))
# extract Illumina negative control data
INCs <- getINCs(rgSet)
head(INCs)
## 5723646052_R02C02 5723646052_R04C01 5723646052_R05C02
## 13792480 -0.3299654 -1.0955482 -0.5266103
## 69649505 -1.0354488 -1.4943396 -1.0067050
## 34772371 -1.1286422 -0.2995603 -0.8192636
## 28715352 -0.5553373 -0.7599489 -0.7186973
## 74737439 -1.1169178 -0.8656399 -0.6429681
## 33730459 -0.7714684 -0.5622424 -0.7724825
## 5723646053_R04C02 5723646053_R05C02 5723646053_R06C02
## 13792480 -0.6374299 -1.116598 -0.4332793
## 69649505 -0.8854881 -1.586679 -0.9217329
## 34772371 -0.6895514 -1.161155 -0.6186795
## 28715352 -1.7903619 -1.348105 -1.0067259
## 74737439 -0.8872082 -1.064986 -0.9841833
## 33730459 -1.5623138 -2.079184 -1.0445246
# add negative control data to M-values
Mc <- rbind(M,INCs)
# create vector marking negative controls in data matrix
ctl1 <- rownames(Mc) %in% rownames(INCs)
table(ctl1)
## ctl1
## FALSE TRUE
## 485512 613
rfit1 <- RUVfit(Y = Mc, X = grp, ctl = ctl1) # Stage 1 analysis
rfit2 <- RUVadj(Y = Mc, fit = rfit1)
Now that we have performed an initial differential methylation analysis to rank the CpGs with respect to their association with the factor of interest, we can designate the CpGs that are least associated with the factor of interest based on FDR-adjusted p-value as ECPs.
top1 <- topRUV(rfit2, num=Inf, p.BH = 1)
head(top1)
## F.p F.p.BH p_X1.1 p.BH_X1.1 b_X1.1 sigma2
## cg04743961 3.516091e-07 0.01017357 3.516091e-07 0.01017357 -4.838190 0.10749571
## cg07155336 3.583107e-07 0.01017357 3.583107e-07 0.01017357 -5.887409 0.16002329
## cg20925841 3.730375e-07 0.01017357 3.730375e-07 0.01017357 -4.790211 0.10714494
## cg03607359 4.721205e-07 0.01017357 4.721205e-07 0.01017357 -4.394397 0.09636129
## cg10566121 5.238865e-07 0.01017357 5.238865e-07 0.01017357 -4.787914 0.11780108
## cg07655636 6.080091e-07 0.01017357 6.080091e-07 0.01017357 -4.571758 0.11201883
## var.b_X1.1 fit.ctl mean
## cg04743961 0.07729156 FALSE -2.31731496
## cg07155336 0.11505994 FALSE -1.27676413
## cg20925841 0.07703935 FALSE -0.87168892
## cg03607359 0.06928569 FALSE -2.19187147
## cg10566121 0.08470133 FALSE 0.03138961
## cg07655636 0.08054378 FALSE -1.29294851
ctl2 <- rownames(M) %in% rownames(top1[top1$p.BH_X1.1 > 0.5,])
table(ctl2)
## ctl2
## FALSE TRUE
## 172540 312972
We can then use the ECPs to perform a second differential methylation with RUV-inverse, which is adjusted for the unwanted variation estimated from the data.
# Perform RUV adjustment and fit
rfit3 <- RUVfit(Y = M, X = grp, ctl = ctl2) # Stage 2 analysis
rfit4 <- RUVadj(Y = M, fit = rfit3)
# Look at table of top results
topRUV(rfit4)
## F.p F.p.BH p_X1.1 p.BH_X1.1 b_X1.1 sigma2 var.b_X1.1 fit.ctl
## cg07155336 1e-24 1e-24 1e-24 1e-24 -5.769286 0.1668414 0.1349771 FALSE
## cg06463958 1e-24 1e-24 1e-24 1e-24 -5.733093 0.1668414 0.1349771 FALSE
## cg00024472 1e-24 1e-24 1e-24 1e-24 -5.662959 0.1668414 0.1349771 FALSE
## cg02040433 1e-24 1e-24 1e-24 1e-24 -5.651399 0.1668414 0.1349771 FALSE
## cg13355248 1e-24 1e-24 1e-24 1e-24 -5.595396 0.1668414 0.1349771 FALSE
## cg02467990 1e-24 1e-24 1e-24 1e-24 -5.592707 0.1668414 0.1349771 FALSE
## cg00817367 1e-24 1e-24 1e-24 1e-24 -5.527501 0.1668414 0.1349771 FALSE
## cg11396157 1e-24 1e-24 1e-24 1e-24 -5.487992 0.1668414 0.1349771 FALSE
## cg16306898 1e-24 1e-24 1e-24 1e-24 -5.466780 0.1668414 0.1349771 FALSE
## cg03735888 1e-24 1e-24 1e-24 1e-24 -5.396242 0.1668414 0.1349771 FALSE
## mean
## cg07155336 -1.2767641
## cg06463958 0.2776252
## cg00024472 -2.4445762
## cg02040433 -1.2918259
## cg13355248 -0.8483387
## cg02467990 -0.4154370
## cg00817367 -0.2911294
## cg11396157 -1.3800170
## cg16306898 -2.1469768
## cg03735888 -1.1527557
If the number of samples in your experiment is greater than the number of Illumina negative controls on the array platform used - 613 for 450k, 411 for EPIC - stage 1 of RUVm will not work. In such cases, we recommend performing a standard limma analysis in stage 1.
# setup design matrix
des <- model.matrix(~grp)
des
## (Intercept) grp1
## 1 1 1
## 2 1 1
## 3 1 0
## 4 1 0
## 5 1 1
## 6 1 0
## attr(,"assign")
## [1] 0 1
## attr(,"contrasts")
## attr(,"contrasts")$grp
## [1] "contr.treatment"
# limma differential methylation analysis
lfit1 <- lmFit(M, design=des)
lfit2 <- eBayes(lfit1) # Stage 1 analysis
# Look at table of top results
topTable(lfit2)
## Removing intercept from test coefficients
## logFC AveExpr t P.Value adj.P.Val B
## cg07155336 -6.037439 -1.276764 -19.22210 1.175108e-07 0.005755968 7.635736
## cg04743961 -4.887986 -2.317315 -19.21709 1.177367e-07 0.005755968 7.634494
## cg03607359 -4.393946 -2.191871 -18.07007 1.852304e-07 0.005755968 7.334032
## cg13272280 -4.559707 -2.099665 -17.25531 2.599766e-07 0.005755968 7.099628
## cg22263007 -4.438420 -1.010994 -17.12384 2.749857e-07 0.005755968 7.060036
## cg03556069 -5.456754 -1.811718 -17.00720 2.891269e-07 0.005755968 7.024476
## cg08443814 -4.597347 -2.062275 -16.80835 3.151706e-07 0.005755968 6.962907
## cg18672939 -5.159383 -0.705992 -16.65643 3.368597e-07 0.005755968 6.915046
## cg24385334 -4.157473 -1.943370 -16.59313 3.463909e-07 0.005755968 6.894890
## cg18044663 -4.426118 -1.197724 -16.57851 3.486357e-07 0.005755968 6.890216
The results of this can then be used to define ECPs for stage 2, as in the previous example.
topl1 <- topTable(lfit2, num=Inf)
## Removing intercept from test coefficients
head(topl1)
## logFC AveExpr t P.Value adj.P.Val B
## cg07155336 -6.037439 -1.276764 -19.22210 1.175108e-07 0.005755968 7.635736
## cg04743961 -4.887986 -2.317315 -19.21709 1.177367e-07 0.005755968 7.634494
## cg03607359 -4.393946 -2.191871 -18.07007 1.852304e-07 0.005755968 7.334032
## cg13272280 -4.559707 -2.099665 -17.25531 2.599766e-07 0.005755968 7.099628
## cg22263007 -4.438420 -1.010994 -17.12384 2.749857e-07 0.005755968 7.060036
## cg03556069 -5.456754 -1.811718 -17.00720 2.891269e-07 0.005755968 7.024476
ctl3 <- rownames(M) %in% rownames(topl1[topl1$adj.P.Val > 0.5,])
table(ctl3)
## ctl3
## FALSE TRUE
## 199150 286362
We can then use the ECPs to perform a second differential methylation
with RUV-inverse
as before.
# Perform RUV adjustment and fit
rfit5 <- RUVfit(Y = M, X = grp, ctl = ctl3) # Stage 2 analysis
rfit6 <- RUVadj(Y = M, fit = rfit5)
# Look at table of top results
topRUV(rfit6)
## F.p F.p.BH p_X1.1 p.BH_X1.1 b_X1.1 sigma2 var.b_X1.1 fit.ctl
## cg06463958 1e-24 1e-24 1e-24 1e-24 -5.910598 0.1667397 0.1170589 FALSE
## cg07155336 1e-24 1e-24 1e-24 1e-24 -5.909549 0.1667397 0.1170589 FALSE
## cg02467990 1e-24 1e-24 1e-24 1e-24 -5.841079 0.1667397 0.1170589 FALSE
## cg00024472 1e-24 1e-24 1e-24 1e-24 -5.823529 0.1667397 0.1170589 FALSE
## cg01893212 1e-24 1e-24 1e-24 1e-24 -5.699627 0.1667397 0.1170589 FALSE
## cg11396157 1e-24 1e-24 1e-24 1e-24 -5.699331 0.1667397 0.1170589 FALSE
## cg13355248 1e-24 1e-24 1e-24 1e-24 -5.658606 0.1667397 0.1170589 FALSE
## cg00817367 1e-24 1e-24 1e-24 1e-24 -5.649284 0.1667397 0.1170589 FALSE
## cg16306898 1e-24 1e-24 1e-24 1e-24 -5.610118 0.1667397 0.1170589 FALSE
## cg16556906 1e-24 1e-24 1e-24 1e-24 -5.567659 0.1667397 0.1170589 FALSE
## mean
## cg06463958 0.27762518
## cg07155336 -1.27676413
## cg02467990 -0.41543703
## cg00024472 -2.44457624
## cg01893212 -0.08273355
## cg11396157 -1.38001701
## cg13355248 -0.84833866
## cg00817367 -0.29112939
## cg16306898 -2.14697683
## cg16556906 -0.96821744
To visualise the effect that the RUVm adjustment is having on the data,
using an MDS plot for example, the getAdj
function can be used to extract
the adjusted values from the RUVm fit object produced by RUVfit
.
NOTE: The adjusted values should only be used for visualisations - it is NOT
recommended that they are used in any downstream analysis.
Madj <- getAdj(M, rfit5) # get adjusted values
The MDS plots below show how the relationship between the samples changes with and without RUVm adjustment. RUVm reduces the distance between the samples in each group by removing unwanted variation. It can be useful to examine this type of plot when trying to decide on the best set of ECPs or to help select the optimal value of \(k\), if using RUV-4 or RUV-2.
par(mfrow=c(1,2))
plotMDS(M, labels=targets$Sample_Name, col=as.integer(factor(targets$status)),
main="Unadjusted", gene.selection = "common")
legend("right",legend=c("Cancer","Normal"),pch=16,cex=1,col=1:2)
plotMDS(Madj, labels=targets$Sample_Name, col=as.integer(factor(targets$status)),
main="Adjusted: RUV-inverse", gene.selection = "common")
## Warning in plotMDS.default(Madj, labels = targets$Sample_Name, col =
## as.integer(factor(targets$status)), : dimension 2 is degenerate or all zero
legend("topright",legend=c("Cancer","Normal"),pch=16,cex=1,col=1:2)
To illustrate how the getAdj
function can be used to help select an
appropriate value for \(k\), we will run the second stage of the RUVm analysis
using RUV-4 with two different \(k\) values.
# Use RUV-4 in stage 2 of RUVm with k=1 and k=2
rfit7 <- RUVfit(Y = M, X = grp, ctl = ctl3,
method = "ruv4", k=1) # Stage 2 with RUV-4, k=1
rfit9 <- RUVfit(Y = M, X = grp, ctl = ctl3,
method = "ruv4", k=2) # Stage 2 with RUV-4, k=2
# get adjusted values
Madj1 <- getAdj(M, rfit7)
Madj2 <- getAdj(M, rfit9)
The following MDS plots show how the relationship between the samples changes from the unadjusted data to data adjusted with RUV-inverse and RUV-4 with two different \(k\) values. For this small dataset, RUV-inverse appears to be removing far too much variation as we can see the samples in each group are completely overlapping. Using RUV-4 and choosing a smaller value for \(k\) produces more sensible results.
par(mfrow=c(2,2))
plotMDS(M, labels=targets$Sample_Name, col=as.integer(factor(targets$status)),
main="Unadjusted", gene.selection = "common")
legend("top",legend=c("Cancer","Normal"),pch=16,cex=1,col=1:2)
plotMDS(Madj, labels=targets$Sample_Name, col=as.integer(factor(targets$status)),
main="Adjusted: RUV-inverse", gene.selection = "common")
## Warning in plotMDS.default(Madj, labels = targets$Sample_Name, col =
## as.integer(factor(targets$status)), : dimension 2 is degenerate or all zero
legend("topright",legend=c("Cancer","Normal"),pch=16,cex=1,col=1:2)
plotMDS(Madj1, labels=targets$Sample_Name, col=as.integer(factor(targets$status)),
main="Adjusted: RUV-4, k=1", gene.selection = "common")
legend("bottom",legend=c("Cancer","Normal"),pch=16,cex=1,col=1:2)
plotMDS(Madj2, labels=targets$Sample_Name, col=as.integer(factor(targets$status)),
main="Adjusted: RUV-4, k=2", gene.selection = "common")
legend("bottomright",legend=c("Cancer","Normal"),pch=16,cex=1,col=1:2)
More information about the various RUV methods can be found at http://www-personal.umich.edu/~johanngb/ruv/, including links to all relevant publications. Further examples of RUV analyses, with code, can be found at https://github.com/johanngb/ruv-useR2018. The tutorials demonstrate how the various plotting functions available in the ruv package (which are not covered in this vignette) can be used to select sensible parameters and assess if the adjustment is “helping” your analysis.
Rather than testing for differences in mean methylation, we may be interested in testing for differences between group variances. For example, it has been hypothesised that highly variable CpGs in cancer are important for tumour progression (Hansen et al. 2011). Hence we may be interested in CpG sites that are consistently methylated in the normal samples, but variably methylated in the cancer samples.
In general we recommend at least 10 samples in each group for accurate variance estimation, however for the purpose of this vignette we perform the analysis on 3 vs 3. In this example, we are interested in testing for differential variability in the cancer versus normal group.
An important note on the coef
parameter: please always explicitly state which
columns of design matrix correspond to the groups that you are interested in
testing for differential variability. The default setting for coef
is to
include all columns of the design matrix when calculating the Levene residuals,
which is not suitable for when there are additional variables that need to be
taken into account in the linear model. To avoid misspecification of the model,
it is best to explicitly state the coef
parameter. The additional nuisance or
confounding variables will still be taken into account in the linear
modelling step, however we find that including them when calculating Levene
residuals often removes all the (possibly interesting) variation in the data.
When the design matrix includes an intercept term, the coef
parameter must
include both the intercept and groups of interest. Consider the design matrix
that was used when performing the limma analysis:
design
## (Intercept) idid2 idid3 groupcancer
## 1 1 0 1 0
## 2 1 1 0 0
## 3 1 0 1 1
## 4 1 0 0 1
## 5 1 0 0 0
## 6 1 1 0 1
## attr(,"assign")
## [1] 0 1 1 2
## attr(,"contrasts")
## attr(,"contrasts")$id
## [1] "contr.treatment"
##
## attr(,"contrasts")$group
## [1] "contr.treatment"
The first column of the design matrix is the intercept term, and the fourth
column tells us which samples are cancer and normal samples. The 2nd and 3rd
columns correspond to the ID parameter, which is not interesting in terms of
finding differentially variable CpGs, but may be important to include in the
linear model. Hence for this example we would specify coef = c(1,4)
in the
call to varFit
.
For methylation data, the varFit
function will take
either a matrix of M-values, \(\beta\) values or a MethylSet
object as input. If
\(\beta\) values are supplied, a logit transformation is performed. Note
that as a default, varFit
uses the robust setting in the
limma framework, which requires the use of the
statmod package.
fitvar <- varFit(Mval, design = design, coef = c(1,4))
The numbers of hyper-variable (1) and hypo-variable (-1) genes in cancer
vs normal can be obtained using decideTests
. In the cancer vs normal
context, we would expect to see more variability in methylation in cancer
compared to normal (i.e. hyper-variable).
summary(decideTests(fitvar))
## (Intercept) idid2 idid3 groupcancer
## Down 0 3 1 0
## NotSig 19735 19996 19992 19991
## Up 265 1 7 9
topDV <- topVar(fitvar, coef=4)
topDV
## SampleVar LogVarRatio DiffLevene t P.Value Adj.P.Value
## cg13516820 5.655938 3.430946 2.879133 5.421279 5.951601e-08 0.001190320
## cg22091297 6.114050 4.040779 2.806703 4.842465 1.287170e-06 0.007461497
## cg14267725 8.235053 4.327289 2.864090 4.837709 1.318322e-06 0.007461497
## cg26744375 6.166232 2.687510 2.487741 4.812991 1.492299e-06 0.007461497
## cg23071808 5.516404 3.362872 2.638585 4.672655 2.982975e-06 0.010743792
## cg24879782 4.755737 3.859502 2.717716 4.656723 3.223138e-06 0.010743792
## cg15174834 4.875825 3.824230 2.628820 4.433304 9.304676e-06 0.026584790
## cg09912667 4.199307 5.066491 2.773138 4.384165 1.167279e-05 0.029181966
## cg09028204 5.188900 2.955333 2.403254 4.328539 1.504660e-05 0.033436891
## cg17969902 4.845701 3.683594 2.489746 4.091855 4.287744e-05 0.085754878
An alternate parameterisation of the design matrix that does not include
an intercept term can also be used (i.e. a cell means model), and specific
contrasts tested with contrasts.varFit
.
Here we specify the design matrix such that the first two columns
correspond to the normal and cancer groups, respectively. Note that we
now specify coef=c(1,2)
.
design2 <- model.matrix(~0+group+id)
fitvar.contr <- varFit(Mval, design=design2, coef=c(1,2))
contr <- makeContrasts(groupcancer-groupnormal,levels=colnames(design2))
fitvar.contr <- contrasts.varFit(fitvar.contr,contrasts=contr)
The results are identical to before.
summary(decideTests(fitvar.contr))
## groupcancer - groupnormal
## Down 0
## NotSig 19991
## Up 9
topVar(fitvar.contr,coef=1)
## SampleVar LogVarRatio DiffLevene t P.Value Adj.P.Value
## cg13516820 5.655938 3.430946 2.879133 5.421279 5.951601e-08 0.001190320
## cg22091297 6.114050 4.040779 2.806703 4.842465 1.287170e-06 0.007461497
## cg14267725 8.235053 4.327289 2.864090 4.837709 1.318322e-06 0.007461497
## cg26744375 6.166232 2.687510 2.487741 4.812991 1.492299e-06 0.007461497
## cg23071808 5.516404 3.362872 2.638585 4.672655 2.982975e-06 0.010743792
## cg24879782 4.755737 3.859502 2.717716 4.656723 3.223138e-06 0.010743792
## cg15174834 4.875825 3.824230 2.628820 4.433304 9.304676e-06 0.026584790
## cg09912667 4.199307 5.066491 2.773138 4.384165 1.167279e-05 0.029181966
## cg09028204 5.188900 2.955333 2.403254 4.328539 1.504660e-05 0.033436891
## cg17969902 4.845701 3.683594 2.489746 4.091855 4.287744e-05 0.085754878
The \(\beta\) values for the top 4 differentially variable CpGs can be seen in Figure 6.
cpgsDV <- rownames(topDV)
par(mfrow=c(2,2))
for(i in 1:4){
stripchart(beta[rownames(beta)==cpgsDV[i],]~design[,4],method="jitter",
group.names=c("Normal","Cancer"),pch=16,cex=1.5,col=c(4,2),ylab="Beta values",
vertical=TRUE,cex.axis=1.5,cex.lab=1.5)
title(cpgsDV[i],cex.main=1.5)
}
Testing for differential variability in expression data is
straightforward if the technology is gene expression microarrays. The
matrix of expression values can be supplied directly to the varFit
function.
For RNA-Seq data, the mean-variance relationship that occurs in count
data needs to be taken into account. In order to deal with this issue,
we apply a voom
transformation (Law et al. 2014) to obtain observation weights, which
are then used in the linear modelling step. For RNA-Seq data, the varFit
function will take a DGElist
object as input.
To demonstrate this, we use data from the tweeDEseqCountData package. This data is part of the International HapMap project, consisting of RNA-Seq profiles from 69 unrelated Nigerian individuals (Pickrell et al. 2010). The only covariate is gender, so we can look at differentially variable expression between males and females. We follow the code from the limma vignette to read in and process the data before testing for differential variability.
First we load up the data and extract the relevant information.
library(tweeDEseqCountData)
data(pickrell1)
counts<-exprs(pickrell1.eset)
dim(counts)
## [1] 38415 69
gender <- pickrell1.eset$gender
table(gender)
## gender
## female male
## 40 29
rm(pickrell1.eset)
data(genderGenes)
data(annotEnsembl63)
annot <- annotEnsembl63[,c("Symbol","Chr")]
rm(annotEnsembl63)
We now have the counts, gender of each sample and annotation (gene
symbol and chromosome) for each Ensemble gene. We can form a DGElist
object
using the edgeR package.
library(edgeR)
y <- DGEList(counts=counts, genes=annot[rownames(counts),])
We filter out lowly expressed genes by keeping genes with at least 1 count per million reads in at least 20 samples, as well as genes that have defined annotation. Finally we perform scaling normalisation.
isexpr <- rowSums(cpm(y)>1) >= 20
hasannot <- rowSums(is.na(y$genes))==0
y <- y[isexpr & hasannot,,keep.lib.sizes=FALSE]
dim(y)
## [1] 17310 69
y <- calcNormFactors(y)
We set up the design matrix and test for differential variability.
design.hapmap <- model.matrix(~gender)
fitvar.hapmap <- varFit(y, design = design.hapmap, coef=c(1,2))
## Converting counts to log counts-per-million using voom.
fitvar.hapmap$genes <- y$genes
We can display the results of the test:
summary(decideTests(fitvar.hapmap))
## (Intercept) gendermale
## Down 0 2
## NotSig 0 17308
## Up 17310 0
topDV.hapmap <- topVar(fitvar.hapmap,coef=ncol(design.hapmap))
topDV.hapmap
## Symbol Chr SampleVar LogVarRatio DiffLevene t
## ENSG00000213318 RP11-331F4.1 16 5.69839463 -2.562939 -0.9859943 -8.031243
## ENSG00000129824 RPS4Y1 Y 2.32497726 -2.087025 -0.4585620 -4.957005
## ENSG00000233864 TTTY15 Y 6.79004140 -2.245369 -0.6085233 -4.612934
## ENSG00000176171 BNIP3 10 0.41317384 1.199292 0.3632133 4.219404
## ENSG00000197358 BNIP3P1 14 0.39969125 1.149754 0.3353288 4.058147
## ENSG00000025039 RRAGD 6 0.91837213 1.091229 0.4926839 3.977022
## ENSG00000103671 TRIP4 15 0.07456448 -1.457139 -0.1520583 -3.911300
## ENSG00000171100 MTM1 X 0.44049558 -1.133295 -0.3334619 -3.896490
## ENSG00000149476 DAK 11 0.13289523 -1.470460 -0.1919880 -3.785893
## ENSG00000064886 CHI3L2 1 2.70234584 1.468059 0.8449434 3.782010
## P.Value Adj.P.Value
## ENSG00000213318 7.238039e-12 1.252905e-07
## ENSG00000129824 3.960855e-06 3.428120e-02
## ENSG00000233864 1.496237e-05 8.633290e-02
## ENSG00000176171 6.441668e-05 2.787632e-01
## ENSG00000197358 1.147886e-04 3.973982e-01
## ENSG00000025039 1.527695e-04 4.375736e-01
## ENSG00000103671 1.921104e-04 4.375736e-01
## ENSG00000171100 2.022293e-04 4.375736e-01
## ENSG00000149476 2.956364e-04 4.425050e-01
## ENSG00000064886 2.995692e-04 4.425050e-01
The log counts per million for the top 4 differentially variable genes can be seen in Figure 7.
genesDV <- rownames(topDV.hapmap)
par(mfrow=c(2,2))
for(i in 1:4){
stripchart(cpm(y,log=TRUE)[rownames(y)==genesDV[i],]~design.hapmap[,ncol(design.hapmap)],method="jitter",
group.names=c("Female","Male"),pch=16,cex=1.5,col=c(4,2),ylab="Log counts per million",
vertical=TRUE,cex.axis=1.5,cex.lab=1.5)
title(genesDV[i],cex.main=1.5)
}
Once a differential methylation or differential variability analysis has been performed, it may be of interest to know which gene pathways are targeted by the significant CpG sites. Geeleher et al. (Geeleher et al. 2013) showed there is a severe bias when performing gene ontology analysis with methylation data. This is due to the fact that there are differing numbers of probes per gene on several different array technologies. For the Illumina Infinium HumanMethylation450 array the number of probes per gene ranges from 1 to 1299, with a median of 15 probes per gene. For the EPIC array, the range is 1 to 1487, with a median of 20 probes per gene. This means that when annotating CpG sites to genes, a gene is more likely to be identified as differentially methylated if there are many CpG sites associated with the gene. We refer to this source of bias as “probe number bias”.
One way to take into account this selection bias is to model the relationship between the number of probes per gene and the probability of being differentially methylated. This can be performed by adapting the goseq method of Young et al. (Young et al. 2010). Each gene then has a prior probability associated with it, and a modified version of a hypergeometric test can be performed, testing for over-representation of the selected genes in each gene set. The BiasedUrn package can be used to obtain p-values from the Wallenius’ noncentral hypergeometric distribution, taking into account the odds of differential methylation for each gene set. Note that the BiasedUrn package can occassionally return p-values of 0. For the gene sets where a p-value of exactly zero is outputted we perform a hypergeometric test, which ensures non-zero p-values and hence false discovery rates.
We have recently uncovered a new source of bias in gene set testing for methylation array data (Maksimovic, Oshlack, and Phipson 2020) that we refer to as “multi-gene bias”. This second source of bias arises due to the fact that around 10% of gene-annotated CpGs are annotated to more than one gene, violating assumptions of independently measured genes. This can lead to some GO categories being identified as significantly enriched as they contain genes with methylation measurements from shared CpGs. This can occur for large gene families such as the protocadherin gamma gene cluster which happen to be over-represented in the GO category “GO:0007156: homophilic cell adhesion via plasma membrane adhesion molecules”. This is now taken into account in the gene set testing functions in missMethyl.
We have developed methods for both CpG and region level analyses. The gometh
function performs gene set testing on GO categories or KEGG pathways for
significant CpG sites. The gsameth
function is a more generalised gene set
testing function which can take as input a list of user specified gene sets.
Note that for gsameth
, the format for the gene ids for each gene in the gene
set needs to be Entrez Gene IDs. For example, the entire curated gene
set list (C2) from the Broad’s Molecular Signatures Database can be
specified as input. The R version of these lists can be downloaded from
http://bioinf.wehi.edu.au/software/MSigDB/index.html. Both functions
take a vector of significant CpG probe names as input. For a region level
analysis, using the DMRcate package, for example,
goregion
and gsaregion
can perform gene set enrichment analysis using the
ranged object as input.
NOTE ON UPDATES IN SEPTEMBER 2020: We have added new functionality to the
gene set testing functions to allow the user to limit the input CpGs to specific
genomic features of interest using the genomic.features
argument. This is
based on the annotation information in the manifest files for the 450K and EPIC
arrays. Possible values are "“ALL”, “TSS200”, “TSS1500”, “Body”, “1stExon”,
“3’UTR”, “5’UTR” and “ExonBnd” (only for EPIC), and any combination can be
specified. In order to include the significant genes that overlap with the gene
set of interest, the sig.genes
parameter can be set to TRUE
. This adds an
additional column to the results dataframe.
To illustrate how to use gometh
, consider the results from the differential
methylation analysis with RUVm.
top <- topRUV(rfit4, number = Inf, p.BH = 1)
table(top$p.BH_X1.1 < 0.01)
##
## FALSE TRUE
## 424168 61344
At a 1% false discovery rate cut-off, there are more than 60,000 CpG sites differentially methylated. These CpGs are annotated to almost 10,000 genes, which means that a gene ontology analysis is unlikely to be relevant or reveal anything biologically interesting. One option for selecting CpGs in this context is to apply not only a false discovery rate cut-off, but also a \(\Delta\beta\) cut-off. However, for this dataset, taking a relatively large \(\Delta\beta\) cut-off of 0.25 still leaves more than 30000 CpGs differentially methylated, which can be annotated to more than 6000 genes.
beta <- getBeta(mSet)
# make sure that order of beta values matches orer after analysis
beta <- beta[match(rownames(top),rownames(beta)),]
beta_norm <- rowMeans(beta[,grp==0])
beta_can <- rowMeans(beta[,grp==1])
Delta_beta <- beta_can - beta_norm
sigDM <- top$p.BH_X1.1 < 0.01 & abs(Delta_beta) > 0.25
table(sigDM)
## sigDM
## FALSE TRUE
## 451760 33748
Instead, we take the top 10000 CpG sites as input to gometh
which can be
annotated to around 2500 genes.
topCpGs<-topRUV(rfit4,number=10000)
sigCpGs <- rownames(topCpGs)
sigCpGs[1:10]
## [1] "cg07155336" "cg06463958" "cg00024472" "cg02040433" "cg13355248"
## [6] "cg02467990" "cg00817367" "cg11396157" "cg16306898" "cg03735888"
# Check number of genes that significant CpGs are annotated to
check <- getMappedEntrezIDs(sig.cpg = sigCpGs)
## All input CpGs are used for testing.
length(check$sig.eg)
## [1] 2490
Thegometh
function takes as input a character vector of CpG names, and
optionally, a character vector of all CpG sites tested. This is important to
include if filtering of the CpGs has been performed prior to differential
methylation analysis. If the all.cpg
argument is omitted, all the CpGs on the
array are used as background. To change the array type, the array.type
argument can be specified as either “450K” or “EPIC”. The default is “450K”.
If the plot.bias
argument is TRUE
, a figure showing the relationship
between the probability of differential methylation and the number of probes per
gene will be displayed.
For testing of GO terms, the collection
argument takes the value
“GO”, which is the default setting. For KEGG pathway analysis, set
collection
to “KEGG”. The function topGSA
shows the top enriched GO
categories. The gsameth
function is called for GO and KEGG pathway analysis
with the appropriate inputs.
For GO testing on our example dataset:
library(IlluminaHumanMethylation450kanno.ilmn12.hg19)
gst <- gometh(sig.cpg=sigCpGs, all.cpg=rownames(top), collection="GO",
plot.bias=TRUE)
## All input CpGs are used for testing.
topGSA(gst, n=10)
## ONTOLOGY TERM N DE
## GO:0048731 BP system development 4281 912
## GO:0007399 BP nervous system development 2383 608
## GO:0007275 BP multicellular organism development 4736 965
## GO:0048699 BP generation of neurons 1412 404
## GO:0031226 CC intrinsic component of plasma membrane 1709 401
## GO:0048856 BP anatomical structure development 5693 1088
## GO:0030182 BP neuron differentiation 1344 384
## GO:0022008 BP neurogenesis 1618 439
## GO:0005887 CC integral component of plasma membrane 1628 379
## GO:0030154 BP cell differentiation 4099 828
## P.DE FDR
## GO:0048731 1.979868e-33 4.513901e-29
## GO:0007399 4.817503e-33 5.491713e-29
## GO:0007275 1.882762e-29 1.430837e-25
## GO:0048699 5.321102e-28 3.032895e-24
## GO:0031226 2.331823e-27 1.063265e-23
## GO:0048856 4.586134e-27 1.742655e-23
## GO:0030182 3.174113e-26 1.033808e-22
## GO:0022008 4.106090e-26 1.170184e-22
## GO:0005887 1.081352e-25 2.739304e-22
## GO:0030154 1.344722e-24 3.065833e-21
Testing all GO categories (>20,000) can be a little slow. To demonstrate
the genomic.features
parameter, let us rather focus on KEGG pathways
(~330 pathways).
gst.kegg <- gometh(sig.cpg=sigCpGs, all.cpg=rownames(top), collection="KEGG")
## All input CpGs are used for testing.
topGSA(gst.kegg, n=10)
## Description N DE P.DE
## path:hsa04020 Calcium signaling pathway 238 75 1.257631e-08
## path:hsa04080 Neuroactive ligand-receptor interaction 356 80 2.464845e-08
## path:hsa04514 Cell adhesion molecules 142 43 4.928605e-05
## path:hsa04970 Salivary secretion 92 27 1.097279e-04
## path:hsa04950 Maturity onset diabetes of the young 26 12 2.853606e-04
## path:hsa04024 cAMP signaling pathway 221 55 2.972890e-04
## path:hsa04151 PI3K-Akt signaling pathway 341 77 1.059776e-03
## path:hsa04911 Insulin secretion 86 27 1.304738e-03
## path:hsa04974 Protein digestion and absorption 102 27 1.476606e-03
## path:hsa05217 Basal cell carcinoma 63 22 1.543190e-03
## FDR
## path:hsa04020 4.276506e-06
## path:hsa04080 4.276506e-06
## path:hsa04514 5.700753e-03
## path:hsa04970 9.518898e-03
## path:hsa04950 1.719321e-02
## path:hsa04024 1.719321e-02
## path:hsa04151 5.187853e-02
## path:hsa04911 5.187853e-02
## path:hsa04974 5.187853e-02
## path:hsa05217 5.187853e-02
We can limit the input CpGs to those in the promoter regions of genes:
gst.kegg.prom <- gometh(sig.cpg=sigCpGs, all.cpg=rownames(top),
collection="KEGG", genomic.features = c("TSS200",
"TSS1500",
"1stExon"))
topGSA(gst.kegg.prom, n=10)
## Description N DE P.DE
## path:hsa04080 Neuroactive ligand-receptor interaction 356 56 1.031570e-08
## path:hsa04020 Calcium signaling pathway 238 45 4.674679e-06
## path:hsa04911 Insulin secretion 86 19 5.064084e-04
## path:hsa04024 cAMP signaling pathway 221 35 5.485723e-04
## path:hsa04514 Cell adhesion molecules 142 26 6.431218e-04
## path:hsa05032 Morphine addiction 91 20 9.769435e-04
## path:hsa05217 Basal cell carcinoma 63 15 1.543506e-03
## path:hsa04916 Melanogenesis 101 20 1.616541e-03
## path:hsa04727 GABAergic synapse 89 18 2.024536e-03
## path:hsa04970 Salivary secretion 92 16 2.320973e-03
## FDR
## path:hsa04080 3.579547e-06
## path:hsa04020 8.110569e-04
## path:hsa04911 4.463265e-02
## path:hsa04024 4.463265e-02
## path:hsa04514 4.463265e-02
## path:hsa05032 5.649990e-02
## path:hsa05217 7.011749e-02
## path:hsa04916 7.011749e-02
## path:hsa04727 7.805711e-02
## path:hsa04970 8.053775e-02
We can see if the results are different if we only include CpGs in gene bodies:
gst.kegg.body <- gometh(sig.cpg=sigCpGs, all.cpg=rownames(top),
collection="KEGG", genomic.features = c("Body"))
topGSA(gst.kegg.body, n=10)
## Description N DE
## path:hsa04974 Protein digestion and absorption 102 19
## path:hsa04514 Cell adhesion molecules 142 26
## path:hsa04512 ECM-receptor interaction 88 19
## path:hsa04020 Calcium signaling pathway 238 38
## path:hsa04640 Hematopoietic cell lineage 92 14
## path:hsa04950 Maturity onset diabetes of the young 26 7
## path:hsa04151 PI3K-Akt signaling pathway 341 44
## path:hsa04550 Signaling pathways regulating pluripotency of stem cells 141 24
## path:hsa05032 Morphine addiction 91 18
## path:hsa00561 Glycerolipid metabolism 60 10
## P.DE FDR
## path:hsa04974 0.0004224149 0.08281045
## path:hsa04514 0.0007314712 0.08281045
## path:hsa04512 0.0008047766 0.08281045
## path:hsa04020 0.0009545873 0.08281045
## path:hsa04640 0.0018246076 0.12662777
## path:hsa04950 0.0056866952 0.32888054
## path:hsa04151 0.0076816876 0.33636448
## path:hsa04550 0.0077548007 0.33636448
## path:hsa05032 0.0104702424 0.40368601
## path:hsa00561 0.0120172500 0.41699858
The KEGG pathways are quite different when limiting CpGs to those in gene bodies
versus CpGs in promoters. To include the significant genes that overlap with
each gene set, set the sig.genes
parameter to TRUE.
gst.kegg.body <- gometh(sig.cpg=sigCpGs, all.cpg=rownames(top),
collection="KEGG", genomic.features = c("Body"),
sig.genes = TRUE)
topGSA(gst.kegg.body, n=5)
## Description N DE P.DE FDR
## path:hsa04974 Protein digestion and absorption 102 19 0.0004224149 0.08281045
## path:hsa04514 Cell adhesion molecules 142 26 0.0007314712 0.08281045
## path:hsa04512 ECM-receptor interaction 88 19 0.0008047766 0.08281045
## path:hsa04020 Calcium signaling pathway 238 38 0.0009545873 0.08281045
## path:hsa04640 Hematopoietic cell lineage 92 14 0.0018246076 0.12662777
## SigGenesInSet
## path:hsa04974 COL1A2,COL4A1,COL4A2,COL4A3,COL5A1,COL5A2,COL6A3,COL11A2,COL15A1,CPA2,COL26A1,COL22A1,ELN,COL24A1,KCNQ1,ATP1B2,SLC8A2,COL18A1,COL27A1,COL23A1
## path:hsa04514 CDH2,CDH4,CNTNAP2,ICOS,HLA-DQA2,HLA-DQB1,HLA-F,HLA-G,ITGA4,ITGAM,MAG,NCAM1,CLDN11,CLDN18,PDCD1,PTPRM,JAM2,SDC2,JAM3,NTNG2,ITGA8,CLDN1,CD8A,NRXN1,NRXN2,CD34
## path:hsa04512 COL1A2,COL4A1,COL4A2,COL4A3,COL6A3,COMP,LAMA1,FREM2,ITGA4,ITGB4,ITGB5,AGRN,LAMA2,LAMA4,GP6,RELN,TNXB,FRAS1,ITGA8,CD36
## path:hsa04020 ADCY1,ADRA1B,ADCY4,ERBB4,FGF3,FGFR2,P2RX2,FLT1,FLT4,GDNF,GRIN2A,GRIN2D,GRM5,HTR2A,ITPKB,ITPR2,ATP2A1,ATP2B2,NTRK1,NTRK2,NTRK3,PDE1A,PDGFB,PLCG2,PRKCB,RYR1,RYR2,RYR3,SLC8A2,CACNA1B,CACNA1D,PDGFD,CAMK4,CAMK2B,CACNA1I,CACNA1H,PLCZ1,CD38,FGF19
## path:hsa04640 CR1,CR1L,CR2,EPO,FLT3,HLA-DQA2,HLA-DQB1,ITGA4,ITGAM,CD1D,CD8A,CD34,CD36,CD38
For a more generalised version of gene set testing in methylation data
where the user can specify the gene set to be tested, the function gsameth
can
be used. To display the top 20 pathways, topGSA
can be called. gsameth
can
take a single gene set, or a list of gene sets. The gene identifiers in the
gene set must be Entrez Gene IDs. To demonstrate
gsameth
, we download and use the Hallmark gene set.
hallmark <- readRDS(url("http://bioinf.wehi.edu.au/MSigDB/v7.1/Hs.h.all.v7.1.entrez.rds"))
gsa <- gsameth(sig.cpg=sigCpGs, all.cpg=rownames(top), collection=hallmark)
## All input CpGs are used for testing.
topGSA(gsa, n=10)
## N DE P.DE FDR
## HALLMARK_EPITHELIAL_MESENCHYMAL_TRANSITION 199 62 1.502342e-07 7.511709e-06
## HALLMARK_KRAS_SIGNALING_DN 200 47 1.590338e-04 3.975845e-03
## HALLMARK_PANCREAS_BETA_CELLS 40 14 7.578790e-04 1.263132e-02
## HALLMARK_MYOGENESIS 200 46 1.786052e-02 2.232565e-01
## HALLMARK_APICAL_JUNCTION 199 43 3.214465e-02 3.158505e-01
## HALLMARK_SPERMATOGENESIS 135 25 3.790206e-02 3.158505e-01
## HALLMARK_UV_RESPONSE_DN 144 36 9.696963e-02 6.194453e-01
## HALLMARK_HEDGEHOG_SIGNALING 36 11 9.911125e-02 6.194453e-01
## HALLMARK_KRAS_SIGNALING_UP 198 34 1.258178e-01 6.989880e-01
## HALLMARK_NOTCH_SIGNALING 32 9 1.416309e-01 7.081546e-01
Note that if it is of interest to obtain the Entrez Gene IDs that the
significant CpGs are mapped to, the getMappedEntrezIDs
function can be called.
We have extended gometh
and gsameth
to perform gene set testing following
a region analysis. The region gene set testing function analogues are goregion
and gsaregion
. Instead of inputting significant CpGs, a ranged object as
typically outputted from region finding software is used. The CpGs overlapping
the significant differentially methylated regions (DMRs) are extracted and the
same statistical framework in gometh
and gsameth
is applied to test for
enrichment of gene sets. We find that genes that have more CpGs measuring
methylation are more likely to be called as differentially methylated regions,
and hence it is important to take into account this bias when performing gene
set testing.
To demonstrate goregion
and gsaregion
we will perform a region analysis
on the cancer dataset using the DMRcate package.
library(DMRcate)
## Warning: replacing previous import 'matrixStats::rowMedians' by
## 'Biobase::rowMedians' when loading 'DSS'
## Warning: replacing previous import 'matrixStats::anyMissing' by
## 'Biobase::anyMissing' when loading 'DSS'
First, the matrix of M-values is annotated with the relevant annotation information about the probes such as their genomic position, gene annotation, etc. By default, this is done using the ilmn12.hg19 annotation. The limma pipeline is then used for differential methylation analysis to calculate moderated t-statistics.
myAnnotation <- cpg.annotate(object = M, datatype = "array", what = "M",
arraytype = c("450K"),
analysis.type = "differential", design = design,
coef = 4)
## Your contrast returned 23435 individually significant probes. We recommend the default setting of pcutoff in dmrcate().
Next we can use the dmrcate
function to combine the CpGs to identify
differentially methylated regions. We can use the extractRanges
function to
extract a GRanges
object with the genomic location and the relevant
statistics associated with each DMR. This object can then be used as input
to goregion
and gsaregion
.
DMRs <- dmrcate(myAnnotation, lambda=1000, C=2)
## Fitting chr1...
## Fitting chr2...
## Fitting chr3...
## Fitting chr4...
## Fitting chr5...
## Fitting chr6...
## Fitting chr7...
## Fitting chr8...
## Fitting chr9...
## Fitting chr10...
## Fitting chr11...
## Fitting chr12...
## Fitting chr13...
## Fitting chr14...
## Fitting chr15...
## Fitting chr16...
## Fitting chr17...
## Fitting chr18...
## Fitting chr19...
## Fitting chr20...
## Fitting chr21...
## Fitting chr22...
## Fitting chrX...
## Fitting chrY...
## Demarcating regions...
## Done!
results.ranges <- extractRanges(DMRs)
## snapshotDate(): 2022-04-19
## see ?DMRcatedata and browseVignettes('DMRcatedata') for documentation
## loading from cache
results.ranges
## GRanges object with 2578 ranges and 8 metadata columns:
## seqnames ranges strand | no.cpgs min_smoothed_fdr
## <Rle> <IRanges> <Rle> | <integer> <numeric>
## [1] chr6 133561224-133564066 * | 50 0.00000e+00
## [2] chr6 33130696-33139083 * | 81 8.99544e-116
## [3] chr13 78491982-78494462 * | 50 0.00000e+00
## [4] chr16 51183363-51188129 * | 39 1.93611e-226
## [5] chr3 62353312-62360893 * | 40 2.69265e-141
## ... ... ... ... . ... ...
## [2574] chr2 20865651-20866414 * | 12 6.43715e-53
## [2575] chr7 4175030-4175200 * | 2 1.53976e-25
## [2576] chr1 91300559-91301204 * | 2 5.26415e-27
## [2577] chr6 29855636-29856682 * | 28 9.01591e-47
## [2578] chr8 76319838-76319964 * | 2 6.60221e-26
## Stouffer HMFDR Fisher maxdiff meandiff
## <numeric> <numeric> <numeric> <numeric> <numeric>
## [1] 3.15705e-25 0.0410900 4.02486e-20 0.653903 0.362511
## [2] 4.60005e-27 0.0725663 1.48443e-18 -0.383081 -0.199979
## [3] 2.67205e-23 0.0466604 3.67335e-18 0.548184 0.323927
## [4] 2.84509e-23 0.0444541 3.74830e-17 0.565576 0.315255
## [5] 3.41752e-23 0.0448639 7.31253e-17 0.567152 0.285499
## ... ... ... ... ... ...
## [2574] 0.601862 0.139908 0.432221 0.38739914 0.06109482
## [2575] 0.560317 0.292250 0.441000 -0.20036591 -0.09735211
## [2576] 0.856410 0.487978 0.681486 0.08841506 0.04428119
## [2577] 0.966982 0.171206 0.739728 0.28665553 0.04184157
## [2578] 0.733543 0.669802 0.808451 -0.00970045 -0.00873155
## overlapping.genes
## <character>
## [1] EYA4
## [2] COL11A2
## [3] RNF219-AS1, EDNRB
## [4] AC009166.5, SALL1
## [5] PTPRG-AS1, FEZF2
## ... ...
## [2574] <NA>
## [2575] SDK1
## [2576] RP4-665J23.1
## [2577] HLA-H, HCG4P7
## [2578] <NA>
## -------
## seqinfo: 23 sequences from an unspecified genome; no seqlengths
We can visualise the top DMR using the DMR.plot
function:
cols <- c(2,4)[group]
names(cols) <-group
beta <- getBeta(mSet)
par(mfrow=c(1,1))
DMR.plot(ranges=results.ranges, dmr=2, CpGs=beta, phen.col=cols,
what="Beta", arraytype="450K", genome="hg19")
## snapshotDate(): 2022-04-19
## see ?DMRcatedata and browseVignettes('DMRcatedata') for documentation
## loading from cache
## require("Gviz")
## Warning in updateObjectFromSlots(object, ..., verbose = verbose): dropping
## slot(s) 'columns' from object = 'GeneRegionTrack'
Now that we have performed our region analysis, we can use goregion
and
gsaregion
to perform gene set testing. Setting plot.bias
to TRUE, we can
see strong probe number bias in the data. This can be interpretted that a
gene is more likely to have a DMR called if it has more CpGs measuring
methylation.
gst.region <- goregion(results.ranges, all.cpg=rownames(M),
collection="GO", array.type="450K", plot.bias=TRUE)
## All input CpGs are used for testing.
topGSA(gst.region, n=10)
## ONTOLOGY
## GO:0007399 BP
## GO:0003700 MF
## GO:0048731 BP
## GO:0000981 MF
## GO:0007275 BP
## GO:0048699 BP
## GO:0030182 BP
## GO:0000977 MF
## GO:0048856 BP
## GO:0022008 BP
## TERM
## GO:0007399 nervous system development
## GO:0003700 DNA-binding transcription factor activity
## GO:0048731 system development
## GO:0000981 DNA-binding transcription factor activity, RNA polymerase II-specific
## GO:0007275 multicellular organism development
## GO:0048699 generation of neurons
## GO:0030182 neuron differentiation
## GO:0000977 RNA polymerase II transcription regulatory region sequence-specific DNA binding
## GO:0048856 anatomical structure development
## GO:0022008 neurogenesis
## N DE P.DE FDR
## GO:0007399 2383 508 3.183790e-36 7.258723e-32
## GO:0003700 1369 302 3.303717e-32 2.522644e-28
## GO:0048731 4281 728 3.319414e-32 2.522644e-28
## GO:0000981 1324 294 2.886103e-31 1.645007e-27
## GO:0007275 4736 771 2.282007e-29 1.040549e-25
## GO:0048699 1412 338 4.599552e-29 1.747753e-25
## GO:0030182 1344 326 7.174197e-29 2.336636e-25
## GO:0000977 1374 292 6.935226e-28 1.976453e-24
## GO:0048856 5693 865 1.686953e-27 4.273426e-24
## GO:0022008 1618 365 4.035680e-27 9.200948e-24
We can also test for enrichment of KEGG pathways:
gst.region.kegg <- goregion(results.ranges, all.cpg=rownames(M),
collection="KEGG", array.type="450K")
## All input CpGs are used for testing.
topGSA(gst.region.kegg, n=10)
## Description N DE P.DE
## path:hsa04080 Neuroactive ligand-receptor interaction 356 81 8.993529e-15
## path:hsa04020 Calcium signaling pathway 238 60 1.860050e-07
## path:hsa04514 Cell adhesion molecules 142 38 7.723759e-06
## path:hsa04950 Maturity onset diabetes of the young 26 12 2.112279e-05
## path:hsa04024 cAMP signaling pathway 221 46 1.682694e-04
## path:hsa04713 Circadian entrainment 97 27 4.679485e-04
## path:hsa04970 Salivary secretion 92 21 5.532730e-04
## path:hsa04742 Taste transduction 85 17 1.420660e-03
## path:hsa04725 Cholinergic synapse 112 28 1.904958e-03
## path:hsa04911 Insulin secretion 86 22 2.170932e-03
## FDR
## path:hsa04080 3.120755e-12
## path:hsa04020 3.227187e-05
## path:hsa04514 8.933814e-04
## path:hsa04950 1.832402e-03
## path:hsa04024 1.167789e-02
## path:hsa04713 2.706302e-02
## path:hsa04970 2.742653e-02
## path:hsa04742 6.162111e-02
## path:hsa04725 6.963479e-02
## path:hsa04911 6.963479e-02
What is interesting is that although very similar pathways are highly ranked compared to the CpG level analysis, gene set testing on the regions is more powerful i.e. the p-values are more significant. In experiments where there are tens of thousands of significant CpGs from a CpG level analysis, we recommend that a good quality region analysis can be a more powerful approach for gene set enrichment analysis.
We can also perform gene set testing on the Hallmark gene sets using
gsaregion
:
gsa.region <- gsaregion(results.ranges, all.cpg=rownames(M),
collection=hallmark)
## All input CpGs are used for testing.
topGSA(gsa.region, n=10)
## N DE P.DE FDR
## HALLMARK_EPITHELIAL_MESENCHYMAL_TRANSITION 199 41 0.001365651 0.06828255
## HALLMARK_PANCREAS_BETA_CELLS 40 11 0.002820772 0.07051931
## HALLMARK_KRAS_SIGNALING_DN 200 33 0.005903935 0.09839891
## HALLMARK_SPERMATOGENESIS 135 22 0.012042512 0.15053140
## HALLMARK_APICAL_JUNCTION 199 34 0.043532458 0.43532458
## HALLMARK_MYOGENESIS 200 34 0.067379978 0.55590916
## HALLMARK_KRAS_SIGNALING_UP 198 28 0.077827283 0.55590916
## HALLMARK_ANGIOGENESIS 36 7 0.107818388 0.67386492
## HALLMARK_APICAL_SURFACE 44 7 0.287658034 1.00000000
## HALLMARK_INFLAMMATORY_RESPONSE 200 20 0.312780391 1.00000000
Note that the DMR analysis can be further refined by imposing a \(\Delta\beta\) value cut-off and changing various parameters. Please refer to the DMRcate package vignette for more details on how to do this.
sessionInfo()
R version 4.2.0 RC (2022-04-19 r82224) Platform: x86_64-pc-linux-gnu (64-bit) Running under: Ubuntu 20.04.4 LTS
Matrix products: default BLAS: /home/biocbuild/bbs-3.15-bioc/R/lib/libRblas.so LAPACK: /home/biocbuild/bbs-3.15-bioc/R/lib/libRlapack.so
locale:
[1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
[3] LC_TIME=en_GB LC_COLLATE=C
[5] LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8
[7] LC_PAPER=en_US.UTF-8 LC_NAME=C
[9] LC_ADDRESS=C LC_TELEPHONE=C
[11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
attached base packages:
[1] grid parallel stats4 stats graphics grDevices utils
[8] datasets methods base
other attached packages:
[1] Gviz_1.40.0
[2] DMRcatedata_2.13.0
[3] ExperimentHub_2.4.0
[4] AnnotationHub_3.4.0
[5] BiocFileCache_2.4.0
[6] dbplyr_2.1.1
[7] DMRcate_2.10.0
[8] edgeR_3.38.0
[9] tweeDEseqCountData_1.33.0
[10] minfiData_0.41.0
[11] IlluminaHumanMethylation450kmanifest_0.4.0
[12] limma_3.52.0
[13] missMethyl_1.30.0
[14] IlluminaHumanMethylationEPICanno.ilm10b4.hg19_0.6.0
[15] IlluminaHumanMethylation450kanno.ilmn12.hg19_0.6.1
[16] minfi_1.42.0
[17] bumphunter_1.38.0
[18] locfit_1.5-9.5
[19] iterators_1.0.14
[20] foreach_1.5.2
[21] Biostrings_2.64.0
[22] XVector_0.36.0
[23] SummarizedExperiment_1.26.0
[24] Biobase_2.56.0
[25] MatrixGenerics_1.8.0
[26] matrixStats_0.62.0
[27] GenomicRanges_1.48.0
[28] GenomeInfoDb_1.32.0
[29] IRanges_2.30.0
[30] S4Vectors_0.34.0
[31] BiocGenerics_0.42.0
[32] BiocStyle_2.24.0
loaded via a namespace (and not attached):
[1] utf8_1.2.2 R.utils_2.11.0
[3] tidyselect_1.1.2 RSQLite_2.2.12
[5] AnnotationDbi_1.58.0 htmlwidgets_1.5.4
[7] BiocParallel_1.30.0 munsell_0.5.0
[9] codetools_0.2-18 preprocessCore_1.58.0
[11] statmod_1.4.36 withr_2.5.0
[13] colorspace_2.0-3 filelock_1.0.2
[15] highr_0.9 knitr_1.38
[17] rstudioapi_0.13 GenomeInfoDbData_1.2.8
[19] bit64_4.0.5 rhdf5_2.40.0
[21] vctrs_0.4.1 generics_0.1.2
[23] xfun_0.30 biovizBase_1.44.0
[25] R6_2.5.1 illuminaio_0.38.0
[27] AnnotationFilter_1.20.0 bitops_1.0-7
[29] rhdf5filters_1.8.0 cachem_1.0.6
[31] reshape_0.8.9 DelayedArray_0.22.0
[33] assertthat_0.2.1 promises_1.2.0.1
[35] bsseq_1.32.0 BiocIO_1.6.0
[37] scales_1.2.0 nnet_7.3-17
[39] gtable_0.3.0 ensembldb_2.20.0
[41] rlang_1.0.2 genefilter_1.78.0
[43] splines_4.2.0 lazyeval_0.2.2
[45] rtracklayer_1.56.0 DSS_2.44.0
[47] GEOquery_2.64.0 dichromat_2.0-0
[49] checkmate_2.1.0 BiocManager_1.30.17
[51] yaml_2.3.5 GenomicFeatures_1.48.0
[53] backports_1.4.1 httpuv_1.6.5
[55] Hmisc_4.7-0 tools_4.2.0
[57] bookdown_0.26 nor1mix_1.3-0
[59] ggplot2_3.3.5 ellipsis_0.3.2
[61] jquerylib_0.1.4 RColorBrewer_1.1-3
[63] siggenes_1.70.0 Rcpp_1.0.8.3
[65] plyr_1.8.7 base64enc_0.1-3
[67] sparseMatrixStats_1.8.0 progress_1.2.2
[69] zlibbioc_1.42.0 purrr_0.3.4
[71] RCurl_1.98-1.6 BiasedUrn_1.07
[73] prettyunits_1.1.1 rpart_4.1.16
[75] openssl_2.0.0 cluster_2.1.3
[77] magrittr_2.0.3 data.table_1.14.2
[79] magick_2.7.3 ProtGenerics_1.28.0
[81] mime_0.12 hms_1.1.1
[83] evaluate_0.15 xtable_1.8-4
[85] XML_3.99-0.9 jpeg_0.1-9
[87] readxl_1.4.0 mclust_5.4.9
[89] gridExtra_2.3 compiler_4.2.0
[91] biomaRt_2.52.0 tibble_3.1.6
[93] crayon_1.5.1 R.oo_1.24.0
[95] htmltools_0.5.2 later_1.3.0
[97] tzdb_0.3.0 Formula_1.2-4
[99] tidyr_1.2.0 DBI_1.1.2
[101] MASS_7.3-57 rappdirs_0.3.3
[103] Matrix_1.4-1 readr_2.1.2
[105] permute_0.9-7 cli_3.3.0
[107] R.methodsS3_1.8.1 quadprog_1.5-8
[109] pkgconfig_2.0.3 GenomicAlignments_1.32.0
[111] foreign_0.8-82 xml2_1.3.3
[113] annotate_1.74.0 bslib_0.3.1
[115] rngtools_1.5.2 multtest_2.52.0
[117] beanplot_1.3.1 ruv_0.9.7.1
[119] doRNG_1.8.2 scrime_1.3.5
[121] VariantAnnotation_1.42.0 stringr_1.4.0
[123] digest_0.6.29 cellranger_1.1.0
[125] rmarkdown_2.14 base64_2.0
[127] htmlTable_2.4.0 DelayedMatrixStats_1.18.0
[129] restfulr_0.0.13 curl_4.3.2
[131] shiny_1.7.1 gtools_3.9.2
[133] Rsamtools_2.12.0 rjson_0.2.21
[135] lifecycle_1.0.1 nlme_3.1-157
[137] jsonlite_1.8.0 Rhdf5lib_1.18.0
[139] askpass_1.1 BSgenome_1.64.0
[141] fansi_1.0.3 pillar_1.7.0
[143] lattice_0.20-45 KEGGREST_1.36.0
[145] fastmap_1.1.0 httr_1.4.2
[147] survival_3.3-1 GO.db_3.15.0
[149] interactiveDisplayBase_1.34.0 glue_1.6.2
[151] png_0.1-7 BiocVersion_3.15.2
[153] bit_4.0.4 stringi_1.7.6
[155] sass_0.4.1 HDF5Array_1.24.0
[157] blob_1.2.3 org.Hs.eg.db_3.15.0
[159] latticeExtra_0.6-29 memoise_2.0.1
[161] dplyr_1.0.8
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