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inst/doc/apeglm.R
In apeglm: Approximate posterior estimation for GLM coefficients
## ----setup, echo=FALSE, results="hide"----------------------------------------
knitr::opts_chunk$set(tidy=FALSE, cache=FALSE,
dev="png",
message=FALSE, error=FALSE, warning=TRUE)
## ----eval=FALSE---------------------------------------------------------------
# res <- lfcShrink(dds, coef=2, type="apeglm")
## -----------------------------------------------------------------------------
library(airway)
data(airway)
head(assay(airway))
## -----------------------------------------------------------------------------
keep <- head(which(rowSums(assay(airway)) > 0), 5000)
airway <- airway[keep,]
## -----------------------------------------------------------------------------
library(DESeq2)
dds <- DESeqDataSet(airway, ~cell + dex)
dds$dex <- relevel(dds$dex, "untrt")
dds <- DESeq(dds)
res <- results(dds)
## -----------------------------------------------------------------------------
x <- model.matrix(design(dds), colData(dds))
param <- dispersions(dds)
mle <- log(2) * cbind(res$log2FoldChange, res$lfcSE)
offset <- matrix(log(sizeFactors(dds)),
ncol=ncol(dds),
nrow=nrow(dds),byrow=TRUE)
## -----------------------------------------------------------------------------
library(apeglm)
system.time({
fit <- apeglm(Y=airway, x=x, log.lik=logLikNB, param=param, coef=ncol(x),
threshold=log(2) * 1, mle=mle, offset=offset)
})
str(fit$prior.control)
## -----------------------------------------------------------------------------
system.time({
fitR <- apeglm(Y=assay(airway), x=x, log.lik=NULL, param=param, coef=ncol(x),
threshold=log(2) * 1, mle=mle, offset=offset, method="nbinomR")
})
## -----------------------------------------------------------------------------
system.time({
fitCR <- apeglm(Y=assay(airway), x=x, log.lik=NULL, param=param, coef=ncol(x),
threshold=log(2) * 1, mle=mle, offset=offset, method="nbinomCR")
})
## -----------------------------------------------------------------------------
system.time({
fitC <- apeglm(Y=assay(airway), x=x, log.lik=NULL, param=param, coef=ncol(x),
threshold=log(2) * 1, mle=mle, offset=offset, method="nbinomC")
})
## -----------------------------------------------------------------------------
class(fit$ranges)
mcols(fit$ranges, use.names=TRUE)
## -----------------------------------------------------------------------------
system.time({
res.shr <- lfcShrink(dds, coef=5, type="normal")
})
DESeq2.lfc <- res.shr$log2FoldChange
apeglm.lfc <- log2(exp(1)) * fit$map[,5]
## ----apevsdeseq---------------------------------------------------------------
plot(DESeq2.lfc, apeglm.lfc)
abline(0,1)
## ----maplots, fig.width=9, fig.height=3.5-------------------------------------
par(mfrow=c(1,3))
lims <- c(-8,8)
hline <- function() abline(h=c(-4:4 * 2),col=rgb(0,0,0,.2))
xlab <- "mean of normalized counts"
plot(res$baseMean, res$log2FoldChange, log="x",
ylim=lims, main="MLE", xlab=xlab)
hline()
plot(res$baseMean, DESeq2.lfc, log="x",
ylim=lims, main="DESeq2", xlab=xlab)
hline()
plot(res$baseMean, apeglm.lfc, log="x",
ylim=lims, main="apeglm", xlab=xlab)
hline()
## ----pvalcomp, fig.width=8, fig.height=4--------------------------------------
par(mfrow=c(1,2),mar=c(5,5,1,1))
plot(res$pvalue, fit$fsr, col="blue",
xlab="DESeq2 pvalue", ylab="apeglm local FSR",
xlim=c(0,1), ylim=c(0,.5))
abline(0,1)
plot(-log10(res$pvalue), -log10(fit$fsr),
xlab="-log10 DESeq2 pvalue", ylab="-log10 apeglm local FSR",
col="blue")
abline(0,1)
## ----pvalcomp2----------------------------------------------------------------
plot(res$padj, fit$svalue, col="blue",
xlab="DESeq2 padj", ylab="apeglm svalue",
xlim=c(0,.2), ylim=c(0,.02))
## ----maplotthresh-------------------------------------------------------------
s.val <- svalue(fit$thresh)
cols <- ifelse(s.val < .01, "red", "black")
keep <- res$baseMean > 10 # filter for plot
plot(res$baseMean[keep],
log2(exp(1)) * fit$map[keep,5],
log="x", col=cols[keep],
xlab=xlab, ylab="LFC")
abline(h=c(-1,0,1), col=rgb(1,0,0,.5), lwd=2)
## -----------------------------------------------------------------------------
library(emdbook)
n <- 20
f <- factor(rep(1:2,each=n))
mu <- ifelse(res$baseMean > 50, res$baseMean, 50)
set.seed(1)
cts <- matrix(rnbinom(nrow(dds)*2*n,
mu=mu,
size=1/dispersions(dds)),
ncol=2*n)
theta <- runif(nrow(cts),1,1000)
prob <- rnorm(nrow(cts),.5,.05) # close to 0.5
ase.cts <- matrix(rbetabinom(prod(dim(cts)), prob=prob,
size=cts, theta=rep(theta,ncol(cts))),
nrow=nrow(cts))
idx <- 1:10
idx2 <- which(f == 2)
theta[idx] <- 1000
prob[idx] <- 0.75
# the spiked in genes have an allelic ratio of 0.75
ase.cts[idx,idx2] <- matrix(rbetabinom(length(idx)*length(idx2), prob=prob[idx],
size=cts[idx,idx2], theta=theta[idx]),
nrow=length(idx))
## -----------------------------------------------------------------------------
betabinom.log.lik <- function(y, x, beta, param, offset) {
xbeta <- x %*% beta
p.hat <- (1+exp(-xbeta))^-1
dbetabinom(y, prob=p.hat, size=param[-1], theta=param[1], log=TRUE)
}
## -----------------------------------------------------------------------------
theta.hat <- 100 # rough initial estimate of dispersion
x <- model.matrix(~f)
niter <- 3
system.time({
for (i in 1:niter) {
param <- cbind(theta.hat, cts)
fit.mle <- apeglm(Y=ase.cts, x=x, log.lik=NULL, param=param,
no.shrink=TRUE, log.link=FALSE, method="betabinCR")
theta.hat <- bbEstDisp(success=ase.cts, size=cts,
x=x, beta=fit.mle$map,
minDisp=.01, maxDisp=5000)
}
})
## ----mlemaplot----------------------------------------------------------------
coef <- 2
xlab <- "mean of normalized counts"
plot(res$baseMean, fit.mle$map[,coef], log="x", xlab=xlab, ylab="log odds")
points(res$baseMean[idx], fit.mle$map[idx,coef], col="dodgerblue", cex=3)
## -----------------------------------------------------------------------------
mle <- cbind(fit.mle$map[,coef], fit.mle$sd[,coef])
param <- cbind(theta.hat, cts)
system.time({
fit2 <- apeglm(Y=ase.cts, x=x, log.lik=NULL, param=param,
coef=coef, mle=mle, threshold=0.5,
log.link=FALSE, method="betabinCR")
})
## ----asemaplot, fig.width=8, fig.height=4-------------------------------------
par(mfrow=c(1,2))
ylim <- c(-1,1.5)
s.val <- svalue(fit2$thresh) # small-or-false-sign value
plot(res$baseMean, fit.mle$map[,coef], main="MLE",
log="x", xlab=xlab, ylab="log odds", ylim=ylim)
points(res$baseMean[idx], fit.mle$map[idx,coef], col="dodgerblue", cex=3)
abline(h=0,col=rgb(1,0,0,.5))
cols <- ifelse(s.val < .01, "red", "black")
plot(res$baseMean, fit2$map[,coef], main="apeglm",
log="x", xlab=xlab, ylab="log odds", col=cols, ylim=ylim)
points(res$baseMean[idx], fit2$map[idx,coef], col="dodgerblue", cex=3)
abline(h=0,col=rgb(1,0,0,.5))
## -----------------------------------------------------------------------------
logit <- function(x) log(x/(1-x))
logit(.75)
table(abs(logit(prob[s.val < .01])) > .5)
## -----------------------------------------------------------------------------
sessionInfo()
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apeglm documentation built on Nov. 8, 2020, 5:55 p.m.
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## ----setup, echo=FALSE, results="hide"----------------------------------------
knitr::opts_chunk$set(tidy=FALSE, cache=FALSE,
dev="png",
message=FALSE, error=FALSE, warning=TRUE)
## ----eval=FALSE---------------------------------------------------------------
# res <- lfcShrink(dds, coef=2, type="apeglm")
## -----------------------------------------------------------------------------
library(airway)
data(airway)
head(assay(airway))
## -----------------------------------------------------------------------------
keep <- head(which(rowSums(assay(airway)) > 0), 5000)
airway <- airway[keep,]
## -----------------------------------------------------------------------------
library(DESeq2)
dds <- DESeqDataSet(airway, ~cell + dex)
dds$dex <- relevel(dds$dex, "untrt")
dds <- DESeq(dds)
res <- results(dds)
## -----------------------------------------------------------------------------
x <- model.matrix(design(dds), colData(dds))
param <- dispersions(dds)
mle <- log(2) * cbind(res$log2FoldChange, res$lfcSE)
offset <- matrix(log(sizeFactors(dds)),
ncol=ncol(dds),
nrow=nrow(dds),byrow=TRUE)
## -----------------------------------------------------------------------------
library(apeglm)
system.time({
fit <- apeglm(Y=airway, x=x, log.lik=logLikNB, param=param, coef=ncol(x),
threshold=log(2) * 1, mle=mle, offset=offset)
})
str(fit$prior.control)
## -----------------------------------------------------------------------------
system.time({
fitR <- apeglm(Y=assay(airway), x=x, log.lik=NULL, param=param, coef=ncol(x),
threshold=log(2) * 1, mle=mle, offset=offset, method="nbinomR")
})
## -----------------------------------------------------------------------------
system.time({
fitCR <- apeglm(Y=assay(airway), x=x, log.lik=NULL, param=param, coef=ncol(x),
threshold=log(2) * 1, mle=mle, offset=offset, method="nbinomCR")
})
## -----------------------------------------------------------------------------
system.time({
fitC <- apeglm(Y=assay(airway), x=x, log.lik=NULL, param=param, coef=ncol(x),
threshold=log(2) * 1, mle=mle, offset=offset, method="nbinomC")
})
## -----------------------------------------------------------------------------
class(fit$ranges)
mcols(fit$ranges, use.names=TRUE)
## -----------------------------------------------------------------------------
system.time({
res.shr <- lfcShrink(dds, coef=5, type="normal")
})
DESeq2.lfc <- res.shr$log2FoldChange
apeglm.lfc <- log2(exp(1)) * fit$map[,5]
## ----apevsdeseq---------------------------------------------------------------
plot(DESeq2.lfc, apeglm.lfc)
abline(0,1)
## ----maplots, fig.width=9, fig.height=3.5-------------------------------------
par(mfrow=c(1,3))
lims <- c(-8,8)
hline <- function() abline(h=c(-4:4 * 2),col=rgb(0,0,0,.2))
xlab <- "mean of normalized counts"
plot(res$baseMean, res$log2FoldChange, log="x",
ylim=lims, main="MLE", xlab=xlab)
hline()
plot(res$baseMean, DESeq2.lfc, log="x",
ylim=lims, main="DESeq2", xlab=xlab)
hline()
plot(res$baseMean, apeglm.lfc, log="x",
ylim=lims, main="apeglm", xlab=xlab)
hline()
## ----pvalcomp, fig.width=8, fig.height=4--------------------------------------
par(mfrow=c(1,2),mar=c(5,5,1,1))
plot(res$pvalue, fit$fsr, col="blue",
xlab="DESeq2 pvalue", ylab="apeglm local FSR",
xlim=c(0,1), ylim=c(0,.5))
abline(0,1)
plot(-log10(res$pvalue), -log10(fit$fsr),
xlab="-log10 DESeq2 pvalue", ylab="-log10 apeglm local FSR",
col="blue")
abline(0,1)
## ----pvalcomp2----------------------------------------------------------------
plot(res$padj, fit$svalue, col="blue",
xlab="DESeq2 padj", ylab="apeglm svalue",
xlim=c(0,.2), ylim=c(0,.02))
## ----maplotthresh-------------------------------------------------------------
s.val <- svalue(fit$thresh)
cols <- ifelse(s.val < .01, "red", "black")
keep <- res$baseMean > 10 # filter for plot
plot(res$baseMean[keep],
log2(exp(1)) * fit$map[keep,5],
log="x", col=cols[keep],
xlab=xlab, ylab="LFC")
abline(h=c(-1,0,1), col=rgb(1,0,0,.5), lwd=2)
## -----------------------------------------------------------------------------
library(emdbook)
n <- 20
f <- factor(rep(1:2,each=n))
mu <- ifelse(res$baseMean > 50, res$baseMean, 50)
set.seed(1)
cts <- matrix(rnbinom(nrow(dds)*2*n,
mu=mu,
size=1/dispersions(dds)),
ncol=2*n)
theta <- runif(nrow(cts),1,1000)
prob <- rnorm(nrow(cts),.5,.05) # close to 0.5
ase.cts <- matrix(rbetabinom(prod(dim(cts)), prob=prob,
size=cts, theta=rep(theta,ncol(cts))),
nrow=nrow(cts))
idx <- 1:10
idx2 <- which(f == 2)
theta[idx] <- 1000
prob[idx] <- 0.75
# the spiked in genes have an allelic ratio of 0.75
ase.cts[idx,idx2] <- matrix(rbetabinom(length(idx)*length(idx2), prob=prob[idx],
size=cts[idx,idx2], theta=theta[idx]),
nrow=length(idx))
## -----------------------------------------------------------------------------
betabinom.log.lik <- function(y, x, beta, param, offset) {
xbeta <- x %*% beta
p.hat <- (1+exp(-xbeta))^-1
dbetabinom(y, prob=p.hat, size=param[-1], theta=param[1], log=TRUE)
}
## -----------------------------------------------------------------------------
theta.hat <- 100 # rough initial estimate of dispersion
x <- model.matrix(~f)
niter <- 3
system.time({
for (i in 1:niter) {
param <- cbind(theta.hat, cts)
fit.mle <- apeglm(Y=ase.cts, x=x, log.lik=NULL, param=param,
no.shrink=TRUE, log.link=FALSE, method="betabinCR")
theta.hat <- bbEstDisp(success=ase.cts, size=cts,
x=x, beta=fit.mle$map,
minDisp=.01, maxDisp=5000)
}
})
## ----mlemaplot----------------------------------------------------------------
coef <- 2
xlab <- "mean of normalized counts"
plot(res$baseMean, fit.mle$map[,coef], log="x", xlab=xlab, ylab="log odds")
points(res$baseMean[idx], fit.mle$map[idx,coef], col="dodgerblue", cex=3)
## -----------------------------------------------------------------------------
mle <- cbind(fit.mle$map[,coef], fit.mle$sd[,coef])
param <- cbind(theta.hat, cts)
system.time({
fit2 <- apeglm(Y=ase.cts, x=x, log.lik=NULL, param=param,
coef=coef, mle=mle, threshold=0.5,
log.link=FALSE, method="betabinCR")
})
## ----asemaplot, fig.width=8, fig.height=4-------------------------------------
par(mfrow=c(1,2))
ylim <- c(-1,1.5)
s.val <- svalue(fit2$thresh) # small-or-false-sign value
plot(res$baseMean, fit.mle$map[,coef], main="MLE",
log="x", xlab=xlab, ylab="log odds", ylim=ylim)
points(res$baseMean[idx], fit.mle$map[idx,coef], col="dodgerblue", cex=3)
abline(h=0,col=rgb(1,0,0,.5))
cols <- ifelse(s.val < .01, "red", "black")
plot(res$baseMean, fit2$map[,coef], main="apeglm",
log="x", xlab=xlab, ylab="log odds", col=cols, ylim=ylim)
points(res$baseMean[idx], fit2$map[idx,coef], col="dodgerblue", cex=3)
abline(h=0,col=rgb(1,0,0,.5))
## -----------------------------------------------------------------------------
logit <- function(x) log(x/(1-x))
logit(.75)
table(abs(logit(prob[s.val < .01])) > .5)
## -----------------------------------------------------------------------------
sessionInfo()
Try the apeglm package in your browser
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We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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