Nothing
R/preprocessENmix.R
In ENmix: Quality control and analysis tools for Illumina DNA methylation BeadChip
Defines functions
preprocessENmix
estBG
huber_mu
huber_mus
enmix
enmix_adj
firstpeak
new_cm
EM_estimate
loglik.x
log.erfc
Documented in
preprocessENmix
log.erfc <- function(x){
log(2)+pnorm(x*sqrt(2),lower.tail=FALSE,log.p=TRUE)
}
loglik.x <- function(x,background,lambda,mu2,sigma2,p1,p2,mu,sigma){
if (background){
temp.1 <- lambda*(2*mu+lambda*sigma^2-2*x)/2+log.erfc((mu+lambda*
sigma^2-x)/(sqrt(2)*sigma))
temp.2 <- dnorm(x,mu+mu2,sqrt(sigma^2+sigma2^2),log=TRUE)
return(sum(ifelse(temp.1>temp.2,temp.1+log(p1*lambda/2+p2*exp(temp.2-
temp.1)),temp.2+log(p1*lambda/2*exp(temp.1-temp.2)+p2))))
}
else{
temp.1 <- dexp(x,lambda,log=TRUE)
temp.2 <- dnorm(x,mu2,sigma2,log=TRUE)
return(sum(ifelse(temp.1>temp.2,temp.1+log(p1+p2*exp(temp.2-temp.1)),
temp.2+log(p1*exp(temp.1-temp.2)+p2))))
}
}
EM_estimate <-
function(x,start=c(max(density(x)$y),mean(range(x)),diff(range(x))/6,0.5),
epsilon=c(0.0001,0.001,0.001,0.001)){
lambda <- start[1]
mu <- start[2]
sigma.sq <- start[3]^2
p1 <- start[4]
n <- length(x)
diff <- TRUE
while (diff){
z <- p1/(p1+(1-p1)*exp(dnorm(x,mu,sqrt(sigma.sq),log=TRUE)-dexp(x,
lambda,log=TRUE)))
lambda.new <- sum(z)/sum(x*z)
mu.new <- sum((1-z)*x)/sum(1-z)
sigma.sq.new <- sum(((x-mu.new)^2)*(1-z))/sum(1-z)
p1.new <- sum(z)/n
diff <- !(all(c(abs(lambda.new-lambda),abs(mu.new-mu),
abs(sigma.sq.new-sigma.sq),abs(p1.new-p1))<epsilon))
lambda <- lambda.new; mu <- mu.new; sigma.sq <- sigma.sq.new; p1 <- p1.new
}
list(lambda,mu,sqrt(sigma.sq),p1)
}
new_cm <-
function(lambda,mu2,sigma2,p1,p2,mu,sigma,s){
a <- mu+lambda*sigma^2
C <- (sigma2^2*(s-mu)+sigma^2*mu2)/(sigma2^2+sigma^2)
D <- sigma2*sigma/sqrt(sigma2^2+sigma^2)
temp_1 <- p1*lambda*exp(lambda^2*sigma^2/2-lambda*(s-mu))*(pnorm(s,a,sigma)-
pnorm(0,a,sigma))
temp_2 <- p2*dnorm(s,mu2+mu,sqrt(sigma2^2+sigma^2))/(1-pnorm(0,mu2,sigma2))
num_1 <- temp_1
num_2 <- temp_2*(pnorm(s,C,D)-pnorm(0,C,D))
denom_1 <- temp_1*(s-a+sigma*(dnorm((s-a)/sigma)-dnorm(a/sigma))/(
pnorm(s,a,sigma)-pnorm(0,a,sigma)))
denom_2 <- temp_2*(C*(pnorm(s,C,D)-pnorm(0,C,D))+D*(exp(-C^2/(2*D^2))
-exp(-(s-C)^2/(2*D^2)))/sqrt(2*pi))
(denom_1+denom_2)/(num_1+num_2)
}
firstpeak <- function(x,y,sn,dat)
{
n <- length(y)
##sn to avoid using small peak position
nn <- sn*2+1
v <- matrix(NA,ncol=nn,nrow=n-nn+1)
for(i in 1:nn){v[,i]=y[i:(n-nn+i)]}
ix <- sn+which(apply(v<v[,(sn+1)],1,sum) == (nn-1))
if(length(ix)>0){mu=x[ix[1]]}
if(length(ix) == 0 | sum(dat<mu)/length(dat)>=0.15)
{
dat <- dat[dat<quantile(dat,p=0.10)]
temp <- density(dat)
flag <- temp$x>=min(dat) & temp$x<=max(dat)
temp$x <- temp$x[flag];temp$y=temp$y[flag]
mu <- temp$x[which.max(temp$y)]
}
mu
}
enmix_adj <- function(meth_i=NULL,bg_i=NULL,bgParaEst)
{
if(sum(is.na(meth_i))>0)
{stop("ENmix background correction does not allow missing value")}
meth_i[meth_i <= 0]=1
mu <- bg_i$mu[1]
sigma <- bg_i$sigma[1]
if(bgParaEst == "est" | bgParaEst == "neg" | bgParaEst == "oob")
{
x <- (meth_i[meth_i>=mu]-mu)
temp <- EM_estimate(x)
lambda <- temp[[1]]
mu2 <- temp[[2]]
sigma2<-ifelse(temp[[3]] <= sigma, 0.1, sqrt(temp[[3]]^2-sigma^2))
p1 <- (sum(meth_i<mu)+temp[[4]]*length(x))/length(meth_i)
p2 <- 1-p1
meth_adj <- new_cm(lambda,mu2,sigma2,p1,p2,mu,sigma,meth_i)
meth_adj[meth_adj <= 0]=0.01 #restrict to positive values, only a few
}else if (bgParaEst == "subtract_neg" | bgParaEst == "subtract_estBG"
| bgParaEst == "subtract_q5neg" | bgParaEst == "subtract_oob"){
meth_adj=meth_i-mu
meth_adj[meth_adj <= 0]=0.01 #restrict to positive values
}
meth_adj
}
enmix <- function(meth,bg,bgParaEst,nCores)
{
colnm <- colnames(meth)
meth.o <- foreach(i=1:ncol(meth),.combine=cbind,.export=c("EM_estimate",
"new_cm","enmix_adj")) %dopar% {
i=i;enmix_adj(meth[,i],bg[i,],bgParaEst)}
if(is.matrix(meth.o)){if(sum(is.na(meth.o))>0){stop("Computation ran out
of memory, try to set nCores with a smaller value")}}else{
stop("Computation ran out of memory, try to set nCores with a smaller
value")}
colnames(meth.o)=colnm
gc(); meth.o
}
#copy from MASS package
huber<-function (y, k = 1.5, tol = 1e-06)
{
y <- y[!is.na(y)]
n <- length(y)
mu <- median(y)
s <- mad(y)
if (s == 0)
stop("cannot estimate scale: MAD is zero for this sample")
repeat {
yy <- pmin(pmax(mu - k * s, y), mu + k * s)
mu1 <- sum(yy)/n
if (abs(mu - mu1) < tol * s)
break
mu <- mu1
}
list(mu = mu, s = s)
}
huber_mus <- function(x){ests <- try(huber(x)); if(class(ests)[1]=="try-error"){
cat("Warning:Check negtive control data, or do quality control before ENmix\n");
c(mu=median(x,na.rm=TRUE),s=sd(x,na.rm=TRUE))
}else{c(mu=ests$mu,s=ests$s)}}
huber_mu <- function(x){ests <- try(huber(x));if(class(ests)[1]=="try-error"){
cat("Warning: Check NORM control data, or do quality control before ENmix\n");
median(x,na.rm=TRUE)
}else{ests$mu}}
estBG <- function(meth_i)
{
meth_i[meth_i<=0]=1e-06
temp <- density(meth_i)
temp <- density(meth_i[meth_i<temp$x[which.max(temp$y)]])
flag <- temp$x>=min(meth_i) & temp$x<=max(meth_i)
temp$x <- temp$x[flag];temp$y=temp$y[flag]
mu <- temp$x[which.max(temp$y)]
##first mode
if((sum(meth_i<mu)/length(meth_i))>=0.15){mu=firstpeak(temp$x,temp$y,
sn=5,meth_i)}
perc <- sum(meth_i<mu)/length(meth_i)
sigma <- sqrt(sum((meth_i[meth_i<mu]-mu)^2)/sum(meth_i<mu))
c(mu,sigma,perc)
}
##background correction
preprocessENmix <- function(rgSet, bgParaEst="oob", dyeCorr="RELIC",
QCinfo=NULL, exQCsample=TRUE,
exQCcpg=TRUE, exSample=NULL, exCpG=NULL, nCores=2)
{
if(is(rgSet, "rgDataSet")){
if(!is.null(QCinfo)){exSample=unique(c(QCinfo$badsample, exSample))}
exSample=exSample[exSample %in% colnames(rgSet)]
if(length(exSample)>0){
rgSet=rgSet[,!(colnames(rgSet) %in% exSample)]
cat(length(exSample), " samples were excluded before ENmix correction\n")
}
mdat <- getmeth(rgSet)
}else if(is(rgSet, "RGChannelSet")){
if(!is.null(QCinfo)){exSample=unique(c(QCinfo$badsample, exSample))}
exSample=exSample[exSample %in% colnames(rgSet)]
if(length(exSample)>0){
rgSet=rgSet[,!(colnames(rgSet) %in% exSample)]
cat(length(exSample), " samples were excluded before ENmix correction\n")
}
mdat <- preprocessRaw(rgSet)
}else if(is(rgSet, "methDataSet") | is(rgSet, "MethylSet")){
if(!is.null(QCinfo) & exQCsample){exSample=unique(c(QCinfo$badsample,
exSample))}
exSample=exSample[exSample %in% colnames(rgSet)]
if(length(exSample)>0){
rgSet=rgSet[,!(colnames(rgSet) %in% exSample)]
cat(length(exSample), " samples were excluded before ENmix correction\n")
}
mdat=rgSet; bgParaEst="est";
if(!(dyeCorr=="none")){cat("Warning: Input data need to be a rgDataSet or
RGChannelSet to perform dye-bias correction\n");
cat("Warning: dye-bias correction will not be performed\n")}
dyeCorr="none"
}else{stop("Error: object needs to be of class 'RGChannelSet' or
'MethylSet'")}
if(nCores>detectCores()){
nCores=detectCores();
cat("Only ",detectCores(), " cores avialable, nCores was reset to ",
detectCores(),"\n")
}
if(!is.null(QCinfo) & exQCcpg) {exCpG=unique(c(exCpG, QCinfo$badCpG))}
exCpG=exCpG[exCpG %in% rownames(mdat)]
if(length(exCpG)>0){
mdat=mdat[!(rownames(mdat) %in% exCpG),]
cat(length(exCpG), " CpGs were excluded before ENmix correction\n")
}
rm(QCinfo)
if(is(mdat, "methDataSet")){
probe_type=rowData(mdat)$Infinium_Design_Type
col=rowData(mdat)$Color_Channel
probe_type[probe_type %in% c("I","snpI") & col=="Grn"]="IGrn"
probe_type[probe_type %in% c("I","snpI") & col=="Red"]="IRed"
probe_type[probe_type %in% c("snpII")]="II"
}else if(is(mdat, "MethylSet")){
probe_type <- getProbeType(mdat, withColor=TRUE)}
cat("Analysis is running, please wait...!\n")
##estimate background parameters
if(bgParaEst == "neg" | bgParaEst == "subtract_neg")
{
if(is(rgSet,"rgDataSet")){
ctrls <- getCGinfo(rgSet,type="ctrl")
}else if(is(rgSet,"RGChannelSet")){
ctrls <- getProbeInfo(rgSet,type="Control")}
ctrls <- ctrls[ctrls$Address %in% rownames(rgSet),]
ctrl_address <- as.vector(ctrls$Address[ctrls$Type %in% "NEGATIVE"])
ctrl_r <- assays(rgSet)$Red[ctrl_address,]
ctrl_g <- assays(rgSet)$Green[ctrl_address,]
ctrl_r[ctrl_r<=0]=1e-06;ctrl_g[ctrl_g<=0]=1e-06
temp <- apply(ctrl_r,2,huber_mus)
mu <- temp["mu",];sigma <- temp["s",]
bgRI <- as.data.frame(cbind(mu,sigma))
temp <- apply(ctrl_g,2,huber_mus);
mu <- temp["mu",];sigma <- temp["s",]
bgGI <- as.data.frame(cbind(mu,sigma))
bgRII <- bgRI;bgGII <- bgGI
}else if (bgParaEst == "oob" | bgParaEst == "subtract_oob")
{
if(is(rgSet,"rgDataSet")){
I_probe <- getCGinfo(rgSet,type="I")
I_probe=I_probe[I_probe$Color_Channel=="Red",]
}else if(is(rgSet,"RGChannelSet")){
I_probe <- getProbeInfo(rgSet, type="I-Red")}
I_green_bg_M <- assays(rgSet)$Green[I_probe$AddressB,]
I_green_bg_U <- assays(rgSet)$Green[I_probe$AddressA,]
ctrl_g <- rbind(I_green_bg_M,I_green_bg_U)
if(is(rgSet,"rgDataSet")){
I_probe <- getCGinfo(rgSet,type="I")
I_probe=I_probe[I_probe$Color_Channel=="Grn",]
}else if(is(rgSet,"RGChannelSet")){
I_probe <- getProbeInfo(rgSet, type="I-Green")}
I_red_bg_M <- assays(rgSet)$Red[I_probe$AddressB,]
I_red_bg_U <- assays(rgSet)$Red[I_probe$AddressA,]
ctrl_r <- rbind(I_red_bg_M,I_red_bg_U)
ctrl_r[ctrl_r<=0]=1e-06;ctrl_g[ctrl_g<=0]=1e-06
temp <- apply(ctrl_r,2,huber_mus)
mu <- temp["mu",];sigma=temp["s",]
bgRI <- as.data.frame(cbind(mu,sigma))
temp <- apply(ctrl_g,2,huber_mus);
mu <- temp["mu",];sigma=temp["s",]
bgGI <- as.data.frame(cbind(mu,sigma))
bgRII <- bgRI;bgGII=bgGI
rm(list=c("I_green_bg_M","I_green_bg_U","ctrl_g","I_red_bg_M","I_red_bg_U",
"ctrl_r"))
}else if (bgParaEst == "subtract_q5neg"){
if(is(rgSet,"rgDataSet")){
ctrls <- getCGinfo(rgSet,type="ctrl")
}else if(is(rgSet,"RGChannelSet")){
ctrls <- getProbeInfo(rgSet,type="Control")}
ctrls <- ctrls[ctrls$Address %in% rownames(rgSet),]
ctrl_address <- as.vector(ctrls$Address[ctrls$Type %in% "NEGATIVE"])
ctrl_r <- assays(rgSet)$Red[ctrl_address,]
ctrl_g <- assays(rgSet)$Green[ctrl_address,]
ctrl_r[ctrl_r<=0]=1e-06;ctrl_g[ctrl_g<=0]=1e-06 ## may not need this
mu <- apply(ctrl_r,2,function(x) quantile(x,probs=0.05,na.rm=TRUE));
sigma <- apply(ctrl_r,2,function(x)sd(x,na.rm=TRUE));
bgRI <- as.data.frame(cbind(mu,sigma))
mu <- apply(ctrl_g,2,function(x) quantile(x,probs=0.05,na.rm=TRUE));
sigma <- apply(ctrl_g,2,function(x)sd(x,na.rm=TRUE));
bgGI <- as.data.frame(cbind(mu,sigma))
bgRII <- bgRI;bgGII=bgGI
}else if(bgParaEst == "est" | bgParaEst == "subtract_estBG"){
mdat_subset <- mdat[probe_type == "IRed",]
m_I_red <- rbind(assays(mdat_subset)$Meth,assays(mdat_subset)$Unmeth)
mdat_subset <- mdat[probe_type == "IGrn",]
m_I_grn <- rbind(assays(mdat_subset)$Meth,assays(mdat_subset)$Unmeth)
mdat_subset <- mdat[probe_type == "II",]
mII <- rbind(assays(mdat_subset)$Meth,assays(mdat_subset)$Unmeth)
rm(mdat_subset)
bgRI <- as.data.frame(t(apply(m_I_red,2,estBG)));names(bgRI) <- c("mu",
"sigma","perc")
bgGI <- as.data.frame(t(apply(m_I_grn,2,estBG)));names(bgGI) <- c("mu",
"sigma","perc")
bgII <- as.data.frame(t(apply(mII,2,estBG)));names(bgII) <- c("mu",
"sigma","perc")
##empirically adjusting the estimates
pp <- apply(cbind(bgRI$perc,bgGI$perc,bgII$perc),1,max)-
apply(cbind(bgRI$perc,bgGI$perc,bgII$perc),1,min)
avgp <- apply(cbind(bgRI$perc,bgGI$perc,bgII$perc),1,mean)
for(i in 1:nrow(bgGI)){if(pp[i]>=0.04){
bgRI$mu[i] <- quantile(m_I_red[,i],probs=avgp[i])
bgGI$mu[i] <- quantile(m_I_grn[,i],probs=avgp[i])
bgII$mu[i] <- quantile(mII[,i],probs=avgp[i])
bgRI$perc[i] <- avgp[i];bgGI$perc[i]=avgp[i];bgII$perc[i]=avgp[i]
}}
bgRI <- bgRI[,c("mu","sigma")]
bgGI <- bgGI[,c("mu","sigma")]
bgII <- bgII[,c("mu","sigma")]
A1=sum(bgII$mu)*2/(sum(bgRI$mu)+sum(bgGI$mu))
A2=sum(bgII$sigma)*2/(sum(bgRI$sigma)+sum(bgGI$sigma))
bgGII=bgGI;bgGII$mu=bgGII$mu*A1;bgGII$sigma=bgGII$sigma*A2
bgRII=bgRI;bgRII$mu=bgRII$mu*A1;bgRII$sigma=bgRII$sigma*A2
rm(list=c("m_I_red","m_I_grn","mII"))
}
c1 <- makeCluster(nCores)
registerDoParallel(c1)
if (dyeCorr == "mean"){
if(is(rgSet,"rgDataSet")){
ctrls <- getCGinfo(rgSet,type="ctrl")
}else if(is(rgSet,"RGChannelSet")){
ctrls <- getProbeInfo(rgSet,type="Control")}
ctrls <- ctrls[ctrls$Address %in% rownames(rgSet),]
ctrl_r <- assays(rgSet)$Red[ctrls$Address,]
ctrl_g <- assays(rgSet)$Green[ctrls$Address,]
CG.controls <- ctrls$Type %in% c("NORM_C", "NORM_G")
AT.controls <- ctrls$Type %in% c("NORM_A", "NORM_T")
cg_grn=ctrl_g[CG.controls,]
at_red=ctrl_r[AT.controls,]
cg_grn <- enmix(cg_grn,bgGI,bgParaEst,nCores)
at_red <- enmix(at_red,bgRI,bgParaEst,nCores)
Green.avg <- apply(cg_grn,2,huber_mu)
Red.avg <- apply(at_red,2,huber_mu)
ref <- mean(c(Red.avg,Green.avg))
Grn.factor <- ref/Green.avg
Red.factor <- ref/Red.avg
}else if(dyeCorr =="RELIC"){
if(is(rgSet,"rgDataSet")){
ctrls <- getCGinfo(rgSet,type="ctrl")
}else if(is(rgSet,"RGChannelSet")){
ctrls <- getProbeInfo(rgSet,type="Control")}
ctrls<-ctrls[ctrls$Address %in% rownames(rgSet),]
ctrl_r<-assays(rgSet)$Red[ctrls$Address,]
ctrl_g<-assays(rgSet)$Green[ctrls$Address,]
CG.controls<-ctrls$Type %in% c("NORM_C","NORM_G")
AT.controls<-ctrls$Type %in% c("NORM_A","NORM_T")
cg_grn<-ctrl_g[CG.controls,];rownames(cg_grn)=
ctrls$ExtendedType[CG.controls]
at_red<-ctrl_r[AT.controls,];rownames(at_red)=
ctrls$ExtendedType[AT.controls]
cg_grn <- enmix(cg_grn,bgGI,bgParaEst,nCores)
at_red <- enmix(at_red,bgRI,bgParaEst,nCores)
}
rm(rgSet)
methData <- assays(mdat)$Meth
N=ceiling(ncol(methData)/(nCores*10))
parts=rep(1:N,each = ceiling(ncol(methData)/N))[1:ncol(methData)]
for(i in 1:N){
id=which(parts==i)
methD=methData[,id]
methD[probe_type == "IGrn",] <- enmix(methD[probe_type == "IGrn",],
bgGI[id,], bgParaEst, nCores)
methD[probe_type == "IRed",] <- enmix(methD[probe_type == "IRed",],
bgRI[id,], bgParaEst, nCores)
methD[probe_type == "II",] <- enmix(methD[probe_type == "II",],
bgGII[id,], bgParaEst, nCores)
methData[,id]=methD;
}
if (dyeCorr == "mean"){
methData[probe_type == "IGrn",] <- sweep(methData[probe_type == "IGrn",],
2, FUN="*", Grn.factor)
methData[probe_type == "II",] <- sweep(methData[probe_type == "II",], 2,
FUN="*", Grn.factor)
methData[probe_type == "IRed",] <- sweep(methData[probe_type == "IRed",],
2, FUN="*", Red.factor)
}
assays(mdat)$Meth <- methData
rm(methData)
unmethData <- assays(mdat)$Unmeth
for(i in 1:N){
id=which(parts==i)
unmethD=unmethData[,id]
unmethD[probe_type == "IGrn",] <- enmix(unmethD[probe_type == "IGrn",],
bgGI[id,], bgParaEst, nCores)
unmethD[probe_type == "IRed",] <- enmix(unmethD[probe_type == "IRed",],
bgRI[id,], bgParaEst, nCores)
unmethD[probe_type == "II",] <- enmix(unmethD[probe_type == "II",],
bgRII[id,], bgParaEst, nCores)
unmethData[,id]=unmethD;
}
if (dyeCorr == "mean"){
unmethData[probe_type == "IGrn",] <- sweep(unmethData[probe_type ==
"IGrn",], 2, FUN="*", Grn.factor)
unmethData[probe_type == "IRed",] <- sweep(unmethData[probe_type ==
"IRed",], 2, FUN="*", Red.factor)
unmethData[probe_type == "II",] <- sweep(unmethData[probe_type ==
"II",], 2, FUN="*", Red.factor)
}
assays(mdat)$Unmeth <- unmethData
rm(unmethData)
stopCluster(c1)
if(dyeCorr =="RELIC"){mdat=relic(mdat,at_red,cg_grn)}
annotation=c(paste("Backgroud_corr: ENmix,",bgParaEst,sep=""),
paste("dyeBiasCorrection: ",dyeCorr,sep=""))
if(is(mdat, "methDataSet")){
metadata(mdat)$preprocessMethod=annotation
}else if(is(mdat, "MethylSet")){
mdat@preprocessMethod <- annotation
}
mdat
}
Try the ENmix package in your browser
Any scripts or data that you put into this service are public.
ENmix documentation built on April 2, 2021, 6 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Defines functions preprocessENmix estBG huber_mu huber_mus enmix enmix_adj firstpeak new_cm EM_estimate loglik.x log.erfc
Documented in preprocessENmix
log.erfc <- function(x){
log(2)+pnorm(x*sqrt(2),lower.tail=FALSE,log.p=TRUE)
}
loglik.x <- function(x,background,lambda,mu2,sigma2,p1,p2,mu,sigma){
if (background){
temp.1 <- lambda*(2*mu+lambda*sigma^2-2*x)/2+log.erfc((mu+lambda*
sigma^2-x)/(sqrt(2)*sigma))
temp.2 <- dnorm(x,mu+mu2,sqrt(sigma^2+sigma2^2),log=TRUE)
return(sum(ifelse(temp.1>temp.2,temp.1+log(p1*lambda/2+p2*exp(temp.2-
temp.1)),temp.2+log(p1*lambda/2*exp(temp.1-temp.2)+p2))))
}
else{
temp.1 <- dexp(x,lambda,log=TRUE)
temp.2 <- dnorm(x,mu2,sigma2,log=TRUE)
return(sum(ifelse(temp.1>temp.2,temp.1+log(p1+p2*exp(temp.2-temp.1)),
temp.2+log(p1*exp(temp.1-temp.2)+p2))))
}
}
EM_estimate <-
function(x,start=c(max(density(x)$y),mean(range(x)),diff(range(x))/6,0.5),
epsilon=c(0.0001,0.001,0.001,0.001)){
lambda <- start[1]
mu <- start[2]
sigma.sq <- start[3]^2
p1 <- start[4]
n <- length(x)
diff <- TRUE
while (diff){
z <- p1/(p1+(1-p1)*exp(dnorm(x,mu,sqrt(sigma.sq),log=TRUE)-dexp(x,
lambda,log=TRUE)))
lambda.new <- sum(z)/sum(x*z)
mu.new <- sum((1-z)*x)/sum(1-z)
sigma.sq.new <- sum(((x-mu.new)^2)*(1-z))/sum(1-z)
p1.new <- sum(z)/n
diff <- !(all(c(abs(lambda.new-lambda),abs(mu.new-mu),
abs(sigma.sq.new-sigma.sq),abs(p1.new-p1))<epsilon))
lambda <- lambda.new; mu <- mu.new; sigma.sq <- sigma.sq.new; p1 <- p1.new
}
list(lambda,mu,sqrt(sigma.sq),p1)
}
new_cm <-
function(lambda,mu2,sigma2,p1,p2,mu,sigma,s){
a <- mu+lambda*sigma^2
C <- (sigma2^2*(s-mu)+sigma^2*mu2)/(sigma2^2+sigma^2)
D <- sigma2*sigma/sqrt(sigma2^2+sigma^2)
temp_1 <- p1*lambda*exp(lambda^2*sigma^2/2-lambda*(s-mu))*(pnorm(s,a,sigma)-
pnorm(0,a,sigma))
temp_2 <- p2*dnorm(s,mu2+mu,sqrt(sigma2^2+sigma^2))/(1-pnorm(0,mu2,sigma2))
num_1 <- temp_1
num_2 <- temp_2*(pnorm(s,C,D)-pnorm(0,C,D))
denom_1 <- temp_1*(s-a+sigma*(dnorm((s-a)/sigma)-dnorm(a/sigma))/(
pnorm(s,a,sigma)-pnorm(0,a,sigma)))
denom_2 <- temp_2*(C*(pnorm(s,C,D)-pnorm(0,C,D))+D*(exp(-C^2/(2*D^2))
-exp(-(s-C)^2/(2*D^2)))/sqrt(2*pi))
(denom_1+denom_2)/(num_1+num_2)
}
firstpeak <- function(x,y,sn,dat)
{
n <- length(y)
##sn to avoid using small peak position
nn <- sn*2+1
v <- matrix(NA,ncol=nn,nrow=n-nn+1)
for(i in 1:nn){v[,i]=y[i:(n-nn+i)]}
ix <- sn+which(apply(v<v[,(sn+1)],1,sum) == (nn-1))
if(length(ix)>0){mu=x[ix[1]]}
if(length(ix) == 0 | sum(dat<mu)/length(dat)>=0.15)
{
dat <- dat[dat<quantile(dat,p=0.10)]
temp <- density(dat)
flag <- temp$x>=min(dat) & temp$x<=max(dat)
temp$x <- temp$x[flag];temp$y=temp$y[flag]
mu <- temp$x[which.max(temp$y)]
}
mu
}
enmix_adj <- function(meth_i=NULL,bg_i=NULL,bgParaEst)
{
if(sum(is.na(meth_i))>0)
{stop("ENmix background correction does not allow missing value")}
meth_i[meth_i <= 0]=1
mu <- bg_i$mu[1]
sigma <- bg_i$sigma[1]
if(bgParaEst == "est" | bgParaEst == "neg" | bgParaEst == "oob")
{
x <- (meth_i[meth_i>=mu]-mu)
temp <- EM_estimate(x)
lambda <- temp[[1]]
mu2 <- temp[[2]]
sigma2<-ifelse(temp[[3]] <= sigma, 0.1, sqrt(temp[[3]]^2-sigma^2))
p1 <- (sum(meth_i<mu)+temp[[4]]*length(x))/length(meth_i)
p2 <- 1-p1
meth_adj <- new_cm(lambda,mu2,sigma2,p1,p2,mu,sigma,meth_i)
meth_adj[meth_adj <= 0]=0.01 #restrict to positive values, only a few
}else if (bgParaEst == "subtract_neg" | bgParaEst == "subtract_estBG"
| bgParaEst == "subtract_q5neg" | bgParaEst == "subtract_oob"){
meth_adj=meth_i-mu
meth_adj[meth_adj <= 0]=0.01 #restrict to positive values
}
meth_adj
}
enmix <- function(meth,bg,bgParaEst,nCores)
{
colnm <- colnames(meth)
meth.o <- foreach(i=1:ncol(meth),.combine=cbind,.export=c("EM_estimate",
"new_cm","enmix_adj")) %dopar% {
i=i;enmix_adj(meth[,i],bg[i,],bgParaEst)}
if(is.matrix(meth.o)){if(sum(is.na(meth.o))>0){stop("Computation ran out
of memory, try to set nCores with a smaller value")}}else{
stop("Computation ran out of memory, try to set nCores with a smaller
value")}
colnames(meth.o)=colnm
gc(); meth.o
}
#copy from MASS package
huber<-function (y, k = 1.5, tol = 1e-06)
{
y <- y[!is.na(y)]
n <- length(y)
mu <- median(y)
s <- mad(y)
if (s == 0)
stop("cannot estimate scale: MAD is zero for this sample")
repeat {
yy <- pmin(pmax(mu - k * s, y), mu + k * s)
mu1 <- sum(yy)/n
if (abs(mu - mu1) < tol * s)
break
mu <- mu1
}
list(mu = mu, s = s)
}
huber_mus <- function(x){ests <- try(huber(x)); if(class(ests)[1]=="try-error"){
cat("Warning:Check negtive control data, or do quality control before ENmix\n");
c(mu=median(x,na.rm=TRUE),s=sd(x,na.rm=TRUE))
}else{c(mu=ests$mu,s=ests$s)}}
huber_mu <- function(x){ests <- try(huber(x));if(class(ests)[1]=="try-error"){
cat("Warning: Check NORM control data, or do quality control before ENmix\n");
median(x,na.rm=TRUE)
}else{ests$mu}}
estBG <- function(meth_i)
{
meth_i[meth_i<=0]=1e-06
temp <- density(meth_i)
temp <- density(meth_i[meth_i<temp$x[which.max(temp$y)]])
flag <- temp$x>=min(meth_i) & temp$x<=max(meth_i)
temp$x <- temp$x[flag];temp$y=temp$y[flag]
mu <- temp$x[which.max(temp$y)]
##first mode
if((sum(meth_i<mu)/length(meth_i))>=0.15){mu=firstpeak(temp$x,temp$y,
sn=5,meth_i)}
perc <- sum(meth_i<mu)/length(meth_i)
sigma <- sqrt(sum((meth_i[meth_i<mu]-mu)^2)/sum(meth_i<mu))
c(mu,sigma,perc)
}
##background correction
preprocessENmix <- function(rgSet, bgParaEst="oob", dyeCorr="RELIC",
QCinfo=NULL, exQCsample=TRUE,
exQCcpg=TRUE, exSample=NULL, exCpG=NULL, nCores=2)
{
if(is(rgSet, "rgDataSet")){
if(!is.null(QCinfo)){exSample=unique(c(QCinfo$badsample, exSample))}
exSample=exSample[exSample %in% colnames(rgSet)]
if(length(exSample)>0){
rgSet=rgSet[,!(colnames(rgSet) %in% exSample)]
cat(length(exSample), " samples were excluded before ENmix correction\n")
}
mdat <- getmeth(rgSet)
}else if(is(rgSet, "RGChannelSet")){
if(!is.null(QCinfo)){exSample=unique(c(QCinfo$badsample, exSample))}
exSample=exSample[exSample %in% colnames(rgSet)]
if(length(exSample)>0){
rgSet=rgSet[,!(colnames(rgSet) %in% exSample)]
cat(length(exSample), " samples were excluded before ENmix correction\n")
}
mdat <- preprocessRaw(rgSet)
}else if(is(rgSet, "methDataSet") | is(rgSet, "MethylSet")){
if(!is.null(QCinfo) & exQCsample){exSample=unique(c(QCinfo$badsample,
exSample))}
exSample=exSample[exSample %in% colnames(rgSet)]
if(length(exSample)>0){
rgSet=rgSet[,!(colnames(rgSet) %in% exSample)]
cat(length(exSample), " samples were excluded before ENmix correction\n")
}
mdat=rgSet; bgParaEst="est";
if(!(dyeCorr=="none")){cat("Warning: Input data need to be a rgDataSet or
RGChannelSet to perform dye-bias correction\n");
cat("Warning: dye-bias correction will not be performed\n")}
dyeCorr="none"
}else{stop("Error: object needs to be of class 'RGChannelSet' or
'MethylSet'")}
if(nCores>detectCores()){
nCores=detectCores();
cat("Only ",detectCores(), " cores avialable, nCores was reset to ",
detectCores(),"\n")
}
if(!is.null(QCinfo) & exQCcpg) {exCpG=unique(c(exCpG, QCinfo$badCpG))}
exCpG=exCpG[exCpG %in% rownames(mdat)]
if(length(exCpG)>0){
mdat=mdat[!(rownames(mdat) %in% exCpG),]
cat(length(exCpG), " CpGs were excluded before ENmix correction\n")
}
rm(QCinfo)
if(is(mdat, "methDataSet")){
probe_type=rowData(mdat)$Infinium_Design_Type
col=rowData(mdat)$Color_Channel
probe_type[probe_type %in% c("I","snpI") & col=="Grn"]="IGrn"
probe_type[probe_type %in% c("I","snpI") & col=="Red"]="IRed"
probe_type[probe_type %in% c("snpII")]="II"
}else if(is(mdat, "MethylSet")){
probe_type <- getProbeType(mdat, withColor=TRUE)}
cat("Analysis is running, please wait...!\n")
##estimate background parameters
if(bgParaEst == "neg" | bgParaEst == "subtract_neg")
{
if(is(rgSet,"rgDataSet")){
ctrls <- getCGinfo(rgSet,type="ctrl")
}else if(is(rgSet,"RGChannelSet")){
ctrls <- getProbeInfo(rgSet,type="Control")}
ctrls <- ctrls[ctrls$Address %in% rownames(rgSet),]
ctrl_address <- as.vector(ctrls$Address[ctrls$Type %in% "NEGATIVE"])
ctrl_r <- assays(rgSet)$Red[ctrl_address,]
ctrl_g <- assays(rgSet)$Green[ctrl_address,]
ctrl_r[ctrl_r<=0]=1e-06;ctrl_g[ctrl_g<=0]=1e-06
temp <- apply(ctrl_r,2,huber_mus)
mu <- temp["mu",];sigma <- temp["s",]
bgRI <- as.data.frame(cbind(mu,sigma))
temp <- apply(ctrl_g,2,huber_mus);
mu <- temp["mu",];sigma <- temp["s",]
bgGI <- as.data.frame(cbind(mu,sigma))
bgRII <- bgRI;bgGII <- bgGI
}else if (bgParaEst == "oob" | bgParaEst == "subtract_oob")
{
if(is(rgSet,"rgDataSet")){
I_probe <- getCGinfo(rgSet,type="I")
I_probe=I_probe[I_probe$Color_Channel=="Red",]
}else if(is(rgSet,"RGChannelSet")){
I_probe <- getProbeInfo(rgSet, type="I-Red")}
I_green_bg_M <- assays(rgSet)$Green[I_probe$AddressB,]
I_green_bg_U <- assays(rgSet)$Green[I_probe$AddressA,]
ctrl_g <- rbind(I_green_bg_M,I_green_bg_U)
if(is(rgSet,"rgDataSet")){
I_probe <- getCGinfo(rgSet,type="I")
I_probe=I_probe[I_probe$Color_Channel=="Grn",]
}else if(is(rgSet,"RGChannelSet")){
I_probe <- getProbeInfo(rgSet, type="I-Green")}
I_red_bg_M <- assays(rgSet)$Red[I_probe$AddressB,]
I_red_bg_U <- assays(rgSet)$Red[I_probe$AddressA,]
ctrl_r <- rbind(I_red_bg_M,I_red_bg_U)
ctrl_r[ctrl_r<=0]=1e-06;ctrl_g[ctrl_g<=0]=1e-06
temp <- apply(ctrl_r,2,huber_mus)
mu <- temp["mu",];sigma=temp["s",]
bgRI <- as.data.frame(cbind(mu,sigma))
temp <- apply(ctrl_g,2,huber_mus);
mu <- temp["mu",];sigma=temp["s",]
bgGI <- as.data.frame(cbind(mu,sigma))
bgRII <- bgRI;bgGII=bgGI
rm(list=c("I_green_bg_M","I_green_bg_U","ctrl_g","I_red_bg_M","I_red_bg_U",
"ctrl_r"))
}else if (bgParaEst == "subtract_q5neg"){
if(is(rgSet,"rgDataSet")){
ctrls <- getCGinfo(rgSet,type="ctrl")
}else if(is(rgSet,"RGChannelSet")){
ctrls <- getProbeInfo(rgSet,type="Control")}
ctrls <- ctrls[ctrls$Address %in% rownames(rgSet),]
ctrl_address <- as.vector(ctrls$Address[ctrls$Type %in% "NEGATIVE"])
ctrl_r <- assays(rgSet)$Red[ctrl_address,]
ctrl_g <- assays(rgSet)$Green[ctrl_address,]
ctrl_r[ctrl_r<=0]=1e-06;ctrl_g[ctrl_g<=0]=1e-06 ## may not need this
mu <- apply(ctrl_r,2,function(x) quantile(x,probs=0.05,na.rm=TRUE));
sigma <- apply(ctrl_r,2,function(x)sd(x,na.rm=TRUE));
bgRI <- as.data.frame(cbind(mu,sigma))
mu <- apply(ctrl_g,2,function(x) quantile(x,probs=0.05,na.rm=TRUE));
sigma <- apply(ctrl_g,2,function(x)sd(x,na.rm=TRUE));
bgGI <- as.data.frame(cbind(mu,sigma))
bgRII <- bgRI;bgGII=bgGI
}else if(bgParaEst == "est" | bgParaEst == "subtract_estBG"){
mdat_subset <- mdat[probe_type == "IRed",]
m_I_red <- rbind(assays(mdat_subset)$Meth,assays(mdat_subset)$Unmeth)
mdat_subset <- mdat[probe_type == "IGrn",]
m_I_grn <- rbind(assays(mdat_subset)$Meth,assays(mdat_subset)$Unmeth)
mdat_subset <- mdat[probe_type == "II",]
mII <- rbind(assays(mdat_subset)$Meth,assays(mdat_subset)$Unmeth)
rm(mdat_subset)
bgRI <- as.data.frame(t(apply(m_I_red,2,estBG)));names(bgRI) <- c("mu",
"sigma","perc")
bgGI <- as.data.frame(t(apply(m_I_grn,2,estBG)));names(bgGI) <- c("mu",
"sigma","perc")
bgII <- as.data.frame(t(apply(mII,2,estBG)));names(bgII) <- c("mu",
"sigma","perc")
##empirically adjusting the estimates
pp <- apply(cbind(bgRI$perc,bgGI$perc,bgII$perc),1,max)-
apply(cbind(bgRI$perc,bgGI$perc,bgII$perc),1,min)
avgp <- apply(cbind(bgRI$perc,bgGI$perc,bgII$perc),1,mean)
for(i in 1:nrow(bgGI)){if(pp[i]>=0.04){
bgRI$mu[i] <- quantile(m_I_red[,i],probs=avgp[i])
bgGI$mu[i] <- quantile(m_I_grn[,i],probs=avgp[i])
bgII$mu[i] <- quantile(mII[,i],probs=avgp[i])
bgRI$perc[i] <- avgp[i];bgGI$perc[i]=avgp[i];bgII$perc[i]=avgp[i]
}}
bgRI <- bgRI[,c("mu","sigma")]
bgGI <- bgGI[,c("mu","sigma")]
bgII <- bgII[,c("mu","sigma")]
A1=sum(bgII$mu)*2/(sum(bgRI$mu)+sum(bgGI$mu))
A2=sum(bgII$sigma)*2/(sum(bgRI$sigma)+sum(bgGI$sigma))
bgGII=bgGI;bgGII$mu=bgGII$mu*A1;bgGII$sigma=bgGII$sigma*A2
bgRII=bgRI;bgRII$mu=bgRII$mu*A1;bgRII$sigma=bgRII$sigma*A2
rm(list=c("m_I_red","m_I_grn","mII"))
}
c1 <- makeCluster(nCores)
registerDoParallel(c1)
if (dyeCorr == "mean"){
if(is(rgSet,"rgDataSet")){
ctrls <- getCGinfo(rgSet,type="ctrl")
}else if(is(rgSet,"RGChannelSet")){
ctrls <- getProbeInfo(rgSet,type="Control")}
ctrls <- ctrls[ctrls$Address %in% rownames(rgSet),]
ctrl_r <- assays(rgSet)$Red[ctrls$Address,]
ctrl_g <- assays(rgSet)$Green[ctrls$Address,]
CG.controls <- ctrls$Type %in% c("NORM_C", "NORM_G")
AT.controls <- ctrls$Type %in% c("NORM_A", "NORM_T")
cg_grn=ctrl_g[CG.controls,]
at_red=ctrl_r[AT.controls,]
cg_grn <- enmix(cg_grn,bgGI,bgParaEst,nCores)
at_red <- enmix(at_red,bgRI,bgParaEst,nCores)
Green.avg <- apply(cg_grn,2,huber_mu)
Red.avg <- apply(at_red,2,huber_mu)
ref <- mean(c(Red.avg,Green.avg))
Grn.factor <- ref/Green.avg
Red.factor <- ref/Red.avg
}else if(dyeCorr =="RELIC"){
if(is(rgSet,"rgDataSet")){
ctrls <- getCGinfo(rgSet,type="ctrl")
}else if(is(rgSet,"RGChannelSet")){
ctrls <- getProbeInfo(rgSet,type="Control")}
ctrls<-ctrls[ctrls$Address %in% rownames(rgSet),]
ctrl_r<-assays(rgSet)$Red[ctrls$Address,]
ctrl_g<-assays(rgSet)$Green[ctrls$Address,]
CG.controls<-ctrls$Type %in% c("NORM_C","NORM_G")
AT.controls<-ctrls$Type %in% c("NORM_A","NORM_T")
cg_grn<-ctrl_g[CG.controls,];rownames(cg_grn)=
ctrls$ExtendedType[CG.controls]
at_red<-ctrl_r[AT.controls,];rownames(at_red)=
ctrls$ExtendedType[AT.controls]
cg_grn <- enmix(cg_grn,bgGI,bgParaEst,nCores)
at_red <- enmix(at_red,bgRI,bgParaEst,nCores)
}
rm(rgSet)
methData <- assays(mdat)$Meth
N=ceiling(ncol(methData)/(nCores*10))
parts=rep(1:N,each = ceiling(ncol(methData)/N))[1:ncol(methData)]
for(i in 1:N){
id=which(parts==i)
methD=methData[,id]
methD[probe_type == "IGrn",] <- enmix(methD[probe_type == "IGrn",],
bgGI[id,], bgParaEst, nCores)
methD[probe_type == "IRed",] <- enmix(methD[probe_type == "IRed",],
bgRI[id,], bgParaEst, nCores)
methD[probe_type == "II",] <- enmix(methD[probe_type == "II",],
bgGII[id,], bgParaEst, nCores)
methData[,id]=methD;
}
if (dyeCorr == "mean"){
methData[probe_type == "IGrn",] <- sweep(methData[probe_type == "IGrn",],
2, FUN="*", Grn.factor)
methData[probe_type == "II",] <- sweep(methData[probe_type == "II",], 2,
FUN="*", Grn.factor)
methData[probe_type == "IRed",] <- sweep(methData[probe_type == "IRed",],
2, FUN="*", Red.factor)
}
assays(mdat)$Meth <- methData
rm(methData)
unmethData <- assays(mdat)$Unmeth
for(i in 1:N){
id=which(parts==i)
unmethD=unmethData[,id]
unmethD[probe_type == "IGrn",] <- enmix(unmethD[probe_type == "IGrn",],
bgGI[id,], bgParaEst, nCores)
unmethD[probe_type == "IRed",] <- enmix(unmethD[probe_type == "IRed",],
bgRI[id,], bgParaEst, nCores)
unmethD[probe_type == "II",] <- enmix(unmethD[probe_type == "II",],
bgRII[id,], bgParaEst, nCores)
unmethData[,id]=unmethD;
}
if (dyeCorr == "mean"){
unmethData[probe_type == "IGrn",] <- sweep(unmethData[probe_type ==
"IGrn",], 2, FUN="*", Grn.factor)
unmethData[probe_type == "IRed",] <- sweep(unmethData[probe_type ==
"IRed",], 2, FUN="*", Red.factor)
unmethData[probe_type == "II",] <- sweep(unmethData[probe_type ==
"II",], 2, FUN="*", Red.factor)
}
assays(mdat)$Unmeth <- unmethData
rm(unmethData)
stopCluster(c1)
if(dyeCorr =="RELIC"){mdat=relic(mdat,at_red,cg_grn)}
annotation=c(paste("Backgroud_corr: ENmix,",bgParaEst,sep=""),
paste("dyeBiasCorrection: ",dyeCorr,sep=""))
if(is(mdat, "methDataSet")){
metadata(mdat)$preprocessMethod=annotation
}else if(is(mdat, "MethylSet")){
mdat@preprocessMethod <- annotation
}
mdat
}
Try the ENmix package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.