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The methylCC user's guide
In methylCC: Estimate the cell composition of whole blood in DNA methylation samples
require(knitr)
opts_chunk$set(error=FALSE, message=FALSE, warning=FALSE)
BiocStyle::markdown()
Introduction
There are several approaches available to adjust for differents in the
relative proportion of cell types in whole blood measured from
DNA methylation (DNAm). For example, reference-based approaches
require the use of reference data sets made up of purified cell types to
identify cell type-specific DNAm signatures. These cell type-specific DNAm
signatures are used to estimate the relative proportions of cell types
directly, but these reference data sets are laborious and expensive to
collect. Furthermore, these reference data sets will need to be
continuously collected over time as new platform technologies emerge
measuring DNAm because the observed methylation levels for the same CpGs
in the same sample vary depending the platform technology.
In contrast, there are reference-free approaches,
which are based on methods related to surrogate variable analysis or
linear mixed models. These approaches do not provide
estimates of the relative proportions of cell types, but rather these
methods just remove the variability induced from the differences in
relative cell type proportions in whole blood samples.
Here, we present a statistical model that estimates the cell composition
of whole blood samples measured from DNAm. The method can be applied
to microarray or sequencing data (for example whole-genome bisulfite
sequencing data, WGBS, reduced representation bisulfite sequencing
data, RRBS). Our method is based on the
idea of identifying informative genomic regions that are clearly
methylated or unmethylated for each cell type, which permits
estimation in multiple platform technologies as cell types preserve
their methylation state in regions independent of platform despite
observed measurements being platform dependent.
Getting Started
Load the methylCC R package and other packages that we'll need
later on.
library(FlowSorted.Blood.450k)
library(methylCC)
library(minfi)
library(tidyr)
library(dplyr)
library(ggplot2)
Data
Whole Blood Illumina 450k Microarray Data Example
# Phenotypic information about samples
head(pData(FlowSorted.Blood.450k))
# RGChannelSet
rgset <- FlowSorted.Blood.450k[,
pData(FlowSorted.Blood.450k)$CellTypeLong %in% "Whole blood"]
Using the estimatecc() function
Input for estimatecc()
The estimatecc() function must have
one object as input:
- an
object such as an RGChannelSet from
the R package minfi or a BSseq object
from the R package bsseq. This object should
contain observed DNAm levels at CpGs (rows)
in a set of $N$ whole blood samples (columns).
Running estimatecc()
In this example, we are interested in estimating the cell
composition of the whole blood samples listed in the
FlowSorted.Blood.450k R/Bioconductor package.
To run the methylcC::estimatecc() function,
just provide the RGChannelSet. This will
create an estimatecc object. We
will call the object est.
set.seed(12345)
est <- estimatecc(object = rgset)
est
To see the cell composition estimates, use the
cell_counts() function.
cell_counts(est)
Compare to minfi::estimateCellCounts()
We can also use the estimateCellCounts() from R/Bioconductor package
minfi
to estimate the cell composition for each of the whole blood samples.
sampleNames(rgset) <- paste0("Sample", 1:6)
est_minfi <- minfi::estimateCellCounts(rgset)
est_minfi
Then, we can compare the estimates to methylCC::estimatecc().
df_minfi = gather(cbind("samples" = rownames(cell_counts(est)),
as.data.frame(est_minfi)),
celltype, est, -samples)
df_methylCC = gather(cbind("samples" = rownames(cell_counts(est)),
cell_counts(est)),
celltype, est, -samples)
dfcombined <- full_join(df_minfi, df_methylCC,
by = c("samples", "celltype"))
ggplot(dfcombined, aes(x=est.x, y = est.y, color = celltype)) +
geom_point() + xlim(0,1) + ylim(0,1) +
geom_abline(intercept = 0, slope = 1) +
xlab("Using minfi::estimateCellCounts()") +
ylab("Using methylCC::estimatecc()") +
labs(title = "Comparing cell composition estimates")
We see the estimates closely match for the six cell types.
SessionInfo
sessionInfo()
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methylCC documentation built on Nov. 8, 2020, 7:35 p.m.
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require(knitr) opts_chunk$set(error=FALSE, message=FALSE, warning=FALSE)
BiocStyle::markdown()
Introduction
There are several approaches available to adjust for differents in the relative proportion of cell types in whole blood measured from DNA methylation (DNAm). For example, reference-based approaches require the use of reference data sets made up of purified cell types to identify cell type-specific DNAm signatures. These cell type-specific DNAm signatures are used to estimate the relative proportions of cell types directly, but these reference data sets are laborious and expensive to collect. Furthermore, these reference data sets will need to be continuously collected over time as new platform technologies emerge measuring DNAm because the observed methylation levels for the same CpGs in the same sample vary depending the platform technology.
In contrast, there are reference-free approaches, which are based on methods related to surrogate variable analysis or linear mixed models. These approaches do not provide estimates of the relative proportions of cell types, but rather these methods just remove the variability induced from the differences in relative cell type proportions in whole blood samples.
Here, we present a statistical model that estimates the cell composition of whole blood samples measured from DNAm. The method can be applied to microarray or sequencing data (for example whole-genome bisulfite sequencing data, WGBS, reduced representation bisulfite sequencing data, RRBS). Our method is based on the idea of identifying informative genomic regions that are clearly methylated or unmethylated for each cell type, which permits estimation in multiple platform technologies as cell types preserve their methylation state in regions independent of platform despite observed measurements being platform dependent.
Getting Started
Load the methylCC R package and other packages that we'll need
later on.
library(FlowSorted.Blood.450k) library(methylCC) library(minfi) library(tidyr) library(dplyr) library(ggplot2)
Data
Whole Blood Illumina 450k Microarray Data Example
# Phenotypic information about samples head(pData(FlowSorted.Blood.450k)) # RGChannelSet rgset <- FlowSorted.Blood.450k[, pData(FlowSorted.Blood.450k)$CellTypeLong %in% "Whole blood"]
Using the estimatecc() function
Input for estimatecc()
The estimatecc() function must have
one object as input:
- an
objectsuch as anRGChannelSetfrom the R packageminfior aBSseqobject from the R packagebsseq. This object should contain observed DNAm levels at CpGs (rows) in a set of $N$ whole blood samples (columns).
Running estimatecc()
In this example, we are interested in estimating the cell
composition of the whole blood samples listed in the
FlowSorted.Blood.450k R/Bioconductor package.
To run the methylcC::estimatecc() function,
just provide the RGChannelSet. This will
create an estimatecc object. We
will call the object est.
set.seed(12345) est <- estimatecc(object = rgset) est
To see the cell composition estimates, use the
cell_counts() function.
cell_counts(est)
Compare to minfi::estimateCellCounts()
We can also use the estimateCellCounts() from R/Bioconductor package
minfi
to estimate the cell composition for each of the whole blood samples.
sampleNames(rgset) <- paste0("Sample", 1:6) est_minfi <- minfi::estimateCellCounts(rgset) est_minfi
Then, we can compare the estimates to methylCC::estimatecc().
df_minfi = gather(cbind("samples" = rownames(cell_counts(est)), as.data.frame(est_minfi)), celltype, est, -samples) df_methylCC = gather(cbind("samples" = rownames(cell_counts(est)), cell_counts(est)), celltype, est, -samples) dfcombined <- full_join(df_minfi, df_methylCC, by = c("samples", "celltype")) ggplot(dfcombined, aes(x=est.x, y = est.y, color = celltype)) + geom_point() + xlim(0,1) + ylim(0,1) + geom_abline(intercept = 0, slope = 1) + xlab("Using minfi::estimateCellCounts()") + ylab("Using methylCC::estimatecc()") + labs(title = "Comparing cell composition estimates")
We see the estimates closely match for the six cell types.
SessionInfo
sessionInfo()
Try the methylCC 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.
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