TRESS 1.4.0
The post-transcriptional epigenetic modification on mRNA is an emerging field to study the gene regulatory mechanism and their association with diseases. Recently developed high-throughput sequencing technology named Methylated RNA Immunoprecipitation Sequencing (MeRIP-seq) enables one to profile mRNA epigenetic modification transcriptome-wide.
In MeRIP-seq, mRNA is first fragmented into approximately 100-nucleotide-long oligonucleotides, and then immunoprecipitated by an anti-m\(^6\)A affinity purified antibody. In addition to the immunoprecipitated (IP) samples, libraries are also prepared for input control fragments to measure the corresponding reference mRNA abundance. This process is an RNA-seq experiment. After sequencing, the reads from both the IP and the input samples are aligned to the reference genome. Due to the enrichment from IP process, transcriptomic regions with m\(^6\)A will have more reads clustered and have peak-like shapes when visualizing the read counts along the genome. Therefore, people often refer the m\(^6\)A regions as “peaks”, which is a term usually used in ChIP-seq to represent the protein binding sites. Figure 1 shows some example peaks on the Fat2 gene from a dataset to study m\(^6\)A dynamics during mouse brain development, where m\(^6\)A in cerebellums from 2-week old mice are profiled with two biological replicates.
Two major tasks in the analysis of MeRIP-seq data are to identify transcriptome-wide m\(^6\)A methylation (namely “peak calling”), and differential m6A methylation.
For the first problem, TRESS builds a two-step procedure to identify transcriptome wide m\(^6\)A regions. In the first step, it quickly scans the whole transcriptome and losely identify candidate regions using an ad hoc algorithm. In the second step, it models read counts from candidate regions using an empirical hierarchical negative binomial model to accounts for all-sources variations. It also imposes a prior on the dispersion of methylation, which induces a shrinkage variance estimate by borrowing information from all candidate regions. Wald test is constructed to detect significant m\(^6\)A regions from the candidates. For the second problem, TRESS constructs a general linear framework based on hierarchical negative binomial model, to connect methylation level of each region with factors of interest. This characteristic makes TRESS applicable not only for two-group comparisons, but also in studies with complex design.
From GitHub:
install.packages("devtools") # if you have not installed "devtools" package
library(devtools)
install_github("https://github.com/ZhenxingGuo0015/TRESS",
build_vignettes = TRUE)
From Bioconductor:
if (!requireNamespace("BiocManager", quietly = TRUE))
install.packages("BiocManager")
# The following initializes usage of Bioc devel
BiocManager::install(version='devel')
BiocManager::install("TRESS")
To view the package vignette in HTML format, run the following lines in R
library(TRESS)
vignette("TRESS")
TRESS requires paired
input control and IP BAM files for each replicate of all samples:
“input1.bam & ip1.bam”, “input2.bam & ip2.bam”, …. in order to call peaks from all replicates.
The BAM files contain mapped reads sequenced from
respective samples and are the output of sequence alignment tools
like Bowtie2
.
For illustration purpose, we include four example BAM files and one corresponding genome annotation file in our publicly available data package datasetTRES
on github,
which can be installed with
install_github("https://github.com/ZhenxingGuo0015/datasetTRES")
The BAM files contain sequencing reads (only on chromosome 19) from two input & IP mouse brain cerebellum samples.
In addition to BAM files, TRESS also needs a path to
an annotation file in order to obtain transcriptome-wide bins,
bin-level read counts and annotation of each peak.
The annotation file is actually is a TXDB and is saved in
format of *.sqlite
, which is easily created using R function
makeTxDbFromUCSC()
from Bioconductor package GenomicFeatures
:
## Directly use "makeTxDbFromUCSC" function to create one
library(GenomicFeatures)
txdb = makeTxDbFromUCSC("mm9", "knownGene")
# saveDb(txdb, file = paste0("YourPATH", "/", "YourGenome.sqlite")
## or load a TxDb annotation package like
# library(TxDb.Mmusculus.UCSC.mm9.knownGene)
# txdb <- TxDb.Mmusculus.UCSC.mm9.knownGene
# saveDb(txdb, file = paste0("YourPATH", "/", "mm9_knownGene.sqlite")
Model fitting:
Similar to peak calling, differential peak calling in TRESS
also needs BAM files and corresponding genome annotation
file saved in *.sqlite
format.
However, to compare methylation level
across different conditions, paired input & IP BAM files
for samples of all conditions are required.
Also, the input order of BAM files from
different conditions should be appropriately
listed in case that samples from different conditions
are mistakenly treated as one group.
As TRESS is designed for differential analysis under general experimental design, then sample attributes determined by all factors in study should also be provided to construct a design matrix. For this, TRESS requires a dataframe containing, for each factor, the attribute value of all samples (the order of sample should be exactly the same as BAM files taken by TRESS). A particular model determining which factor will be included into design matrix should also be provided.
Hypothesis testing: All aforementioned input requirements are for model fitting in TRESS. For hypothesis testing, TRESS requires a contrast of coefficients. The contrast should be in line with the name and order of all coefficients in the design matrix. It can be a vector for simple linear relationship detection or a matrix for composite relationship detection.
TRESS provides three example MeRIP-seq dataset.
The raw sequencing reads of all three data were downloaded
from GEO, and mapped using Bowtie2
to generate
corresponding BAM files.
With BAM files, we apply TRESS to obtain transcriptome
bins and candidate regions. A small subset of both bin-level
and region-level data are stored as examples in
TRESS for package illustration purpose.
The first example dataset Basal
comes from 7 basal
mouse brain samples (GEO accession number GSE113781).
The total number of bins and candidate regions for
original data are 1,620,977 and 13,017 respectively.
Due to space limit,
only data of randomly selected 1000 bins and
500 regions (bins and regions are not necessarily overlapped)
are saved. In particular,
for each bin and candidate region,
both the genomic coordinate and read counts
(across 7 paired input & ip replicates) are kept.
library(TRESS)
data("Basal")
Bins <- Basal$Bins$Bins
BinCounts <- Basal$Bins$Counts
dim(BinCounts)
## [1] 1000 14
Candidates <- Basal$Candidates$Regions
CandidatesCounts <- Basal$Candidates$Counts
sf <- Basal$Bins$sf
Check the coordinates of each bin and candidate region.
head(Bins, 3)
## chr start end width strand
## 1 chr1 3195951 3196000 50 -
## 2 chr1 3196001 3196050 50 -
## 3 chr1 3196051 3196100 50 -
head(Candidates, 3)
## chr start end strand summit
## 1 chr9 90099501 90099700 - 90099625
## 2 chr5 145620001 145620200 + 145620075
## 3 chr2 130408151 130408300 - 130408275
Check the read counts in each bin and candidate region.
dim(BinCounts)
## [1] 1000 14
head(BinCounts, 3)
## basal_Input_rep1 basal_IP_rep1 basal_Input_rep2 basal_IP_rep2
## [1,] 2 7 3 0
## [2,] 4 6 8 0
## [3,] 44 8 26 2
## basal_Input_rep3 basal_IP_rep3 basal_Input_rep4 basal_IP_rep4
## [1,] 4 2 2 2
## [2,] 10 2 4 2
## [3,] 22 2 26 12
## basal_Input_rep5 basal_IP_rep5 basal_Input_rep6 basal_IP_rep6
## [1,] 6 0 4 1
## [2,] 10 0 6 2
## [3,] 14 2 26 4
## basal_Input_rep7 basal_IP_rep7
## [1,] 1 0
## [2,] 6 2
## [3,] 13 6
dim(CandidatesCounts)
## [1] 500 14
head(CandidatesCounts,3)
## basal_Input_rep1 basal_IP_rep1 basal_Input_rep2 basal_IP_rep2
## 1 95 2206 92 1430
## 2 750 20841 797 12699
## 3 58 1857 78 1320
## basal_Input_rep3 basal_IP_rep3 basal_Input_rep4 basal_IP_rep4
## 1 150 1810 164 2380
## 2 1013 17832 956 23479
## 3 112 1449 161 2452
## basal_Input_rep5 basal_IP_rep5 basal_Input_rep6 basal_IP_rep6
## 1 122 1415 135 1559
## 2 963 15379 859 15951
## 3 111 1762 118 1625
## basal_Input_rep7 basal_IP_rep7
## 1 80 988
## 2 831 12311
## 3 111 1357
Check the library size factor of each sample in this data.
sf
## basal_Input_rep1 basal_IP_rep1 basal_Input_rep2 basal_IP_rep2
## 0.6807884 1.7213164 0.7472330 1.1091955
## basal_Input_rep3 basal_IP_rep3 basal_Input_rep4 basal_IP_rep4
## 0.7403452 1.3782818 1.0150407 2.2242626
## basal_Input_rep5 basal_IP_rep5 basal_Input_rep6 basal_IP_rep6
## 0.7245767 1.2234676 0.6533518 1.2120361
## basal_Input_rep7 basal_IP_rep7
## 0.6148696 1.1139263
The second example dataset DMR_M3vsWT
comes from human
Hela cell lines (GEO46705).
This dataset contains samples from two conditions:
wild type (WT) and METTL3-Knockout (M3-KO).
Each sample contains two input & ip replicates.
For comparison between original M3-KO and WT samples,
TRESS called 10841 candidate DMRs,
but data (genomic coordinates and read counts matrix)
for only 200 randomly selected candidate DMRs are kept.
Library size factor for each sample is also saved.
In addition to 200 candidate DMRs,
data for 737 bins overlapping with 6 example candidate
DMRs are also included for visualization purpose.
data("DMR_M3vsWT")
Candidates <- DMR_M3vsWT$Regions
CandidatesCounts <- DMR_M3vsWT$Counts
sf <- DMR_M3vsWT$sf
### bins overlapping with 6 candidates
bins <- DMR_M3vsWT$Bins
Check the coordidates of candidate DMRs between WT and M3-KO samples.
dim(Candidates)
## [1] 200 5
head(Candidates, 3)
## chr start end strand summit
## 2291 chr4 56875218 56875817 + 56875342_56875592
## 3337 chr6 74284144 74284293 - 74284268
## 4518 chr9 136433265 136433564 + 136433439
Check the read counts in candidate DMRs between WT and M3-KO samples.
dim(CandidatesCounts)
## [1] 200 8
head(CandidatesCounts, 3)
## WT_Input_rep1 WT_IP_rep1 WT_Input_rep2 WT_IP_rep2 M3_Input_rep1 M3_IP_rep1
## 2291 130 1081 114 739 427 540
## 3337 694 815 867 449 171 2047
## 4518 82 731 104 404 268 350
## M3_Input_rep2 M3_IP_rep2
## 2291 529 518
## 3337 229 1855
## 4518 298 384
Check the library size factor of each sample.
sf
## WT_Input_rep1 WT_IP_rep1 WT_Input_rep2 WT_IP_rep2 M3_Input_rep1
## 0.5662048 1.9513728 0.6839914 1.1201070 0.8798930
## M3_IP_rep1 M3_Input_rep2 M3_IP_rep2
## 1.7702098 0.8732603 1.7191598
Check the overlapps between bins and candidate DMRs.
library(GenomicRanges)
bins.GR <- GRanges(Rle(bins$chr), IRanges(bins$start, bins$end),
Rle(bins$strand))
Candidates.GR <- GRanges(Rle(Candidates$chr),
IRanges(Candidates$start, Candidates$end),
Rle(Candidates$strand))
library(GenomicFeatures)
sum(countOverlaps(Candidates.GR, bins.GR) > 0)
## [1] 6
The third example dataset DMR_SixWeekvsTwoWeek
comes from mouse brain samples (GEO144032).
It consists of samples from mouse brain cortex and
hypothalamus regions at two time points, 2- and 6-week-old.
Each sample contains two paired input and ip replicates.
we focus on differential methylation between
2- and 6-week-old samples in each brain region.
A total of 15,724 candidate DMRs are called by
TRESS and only 200 randomly selected candidate DMRs are kept.
Library size factor for each sample is also saved. In addition,
methylation ratio of 200 candidate DMRs in each sample are also
included to provide an intuitive comparison of methylation level
in samples of different conditions.
data("DMR_SixWeekvsTwoWeek")
Candidates <- DMR_SixWeekvsTwoWeek$Regions
CandidatesCounts <- DMR_SixWeekvsTwoWeek$Counts
sf <- DMR_SixWeekvsTwoWeek$sf
Check coordidates of candidate DMRs between six and two week samples.
dim(Candidates)
## [1] 200 5
head(Candidates, 3)
## chr start end strand summit
## 255 chr1 44047402 44047551 + 44047476
## 4 chr16 4649245 4649394 + 4649319
## 3 chr7 5049157 5049306 + 5049231
Check read counts in candidate DMRs between six and two week samples.
dim(CandidatesCounts)
## [1] 200 16
head(CandidatesCounts, 3)
## 2wk_cortex_input_rep1 2wk_cortex_IP_rep1 2wk_cortex_input_rep2
## 255 35 4 44
## 4 16 54 5
## 3 160 237 102
## 2wk_cortex_IP_rep2 2wk_hypothalamus_input_rep1 2wk_hypothalamus_IP_rep1
## 255 5 63 16
## 4 48 26 53
## 3 280 216 267
## 2wk_hypothalamus_input_rep2 2wk_hypothalamus_IP_rep2 6wk_cortex_input_rep1
## 255 24 16 7
## 4 23 102 29
## 3 180 459 121
## 6wk_cortex_IP_rep1 6wk_cortex_input_rep2 6wk_cortex_IP_rep2
## 255 22 0 14
## 4 31 20 9
## 3 129 124 102
## 6wk_hypothalamus_input_rep1 6wk_hypothalamus_IP_rep1
## 255 20 4
## 4 19 26
## 3 99 135
## 6wk_hypothalamus_input_rep2 6wk_hypothalamus_IP_rep2
## 255 15 7
## 4 12 35
## 3 105 156
Check the library size factor of each sample.
sf
## 2wk_cortex_input_rep1 2wk_cortex_IP_rep1
## 1.5475925 1.4187376
## 2wk_cortex_input_rep2 2wk_cortex_IP_rep2
## 1.0272155 0.9727845
## 2wk_hypothalamus_input_rep1 2wk_hypothalamus_IP_rep1
## 1.8370234 1.4062373
## 2wk_hypothalamus_input_rep2 2wk_hypothalamus_IP_rep2
## 1.1989765 1.8434219
## 6wk_cortex_input_rep1 6wk_cortex_IP_rep1
## 0.7262692 0.9211943
## 6wk_cortex_input_rep2 6wk_cortex_IP_rep2
## 0.4519580 0.7454718
## 6wk_hypothalamus_input_rep1 6wk_hypothalamus_IP_rep1
## 0.7324076 0.8373596
## 6wk_hypothalamus_input_rep2 6wk_hypothalamus_IP_rep2
## 0.5351408 1.1228511
Check methylation ratio of 200 candidate DMRs across all samples.
MeRatio <- DMR_SixWeekvsTwoWeek$MeRatio
head(MeRatio, 3)
## 2wk_Cortex_rep1 2wk_Cortex_rep2 2wk_Hypothalamus_rep1 2wk_Hypothalamus_rep2
## 255 0.1108468 0.1071387 0.2491189 0.3024580
## 4 0.7863946 0.9102105 0.7269940 0.7425612
## 3 0.6177052 0.7435040 0.6175588 0.6238538
## 6wk_Cortex_rep1 6wk_Cortex_rep2 6wk_Hypothalamus_rep1 6wk_Hypothalamus_rep2
## 255 0.7124642 0.9036763 0.1488874 0.1819433
## 4 0.4573393 0.2143442 0.5448147 0.5816000
## 3 0.4566768 0.3327581 0.5439460 0.4145467
Peak calling in TRESS is performed using one wrapper function
TRESS_peak()
. Here we use example BAM files from datasetTRES
as an example.
## Directly take BAM files in "datasetTRES" available on github
library(datasetTRES)
Input.file = c("cb_input_rep1_chr19.bam", "cb_input_rep2_chr19.bam")
IP.file = c("cb_ip_rep1_chr19.bam", "cb_ip_rep2_chr19.bam")
BamDir = file.path(system.file(package = "datasetTRES"), "extdata/")
annoDir = file.path(system.file(package = "datasetTRES"),
"extdata/mm9_chr19_knownGene.sqlite")
OutDir = "/directory/to/output"
TRESS_peak(IP.file = IP.file,
Input.file = Input.file,
Path_To_AnnoSqlite = annoDir,
InputDir = BamDir,
OutputDir = OutDir, # specify a directory for output
experiment_name = "examplebyBam", # name your output
filetype = "bam")
### example peaks
peaks = read.table(file.path(system.file(package = "TRESS"),
"extdata/examplebyBam_peaks.xls"),
sep = "\t", header = TRUE)
head(peaks[, -c(5, 14, 15)], 3)
To replace the example BAM files with your BAM files, the codes are:
## or, take BAM files from your path
Input.file = c("input_rep1.bam", "input_rep2.bam")
IP.file = c("ip_rep1.bam", "ip_rep2.bam")
BamDir = "/directory/to/BAMfile"
annoDir = "/path/to/xxx.sqlite"
OutDir = "/directory/to/output"
TRESS_peak(IP.file = IP.file,
Input.file = Input.file,
Path_To_AnnoSqlite = annoDir,
InputDir = BamDir,
OutputDir = OutDir,
experiment_name = "xxx",
filetype = "bam")
peaks = read.table(paste0(OutDir, "/",
"xxx_peaks.xls"),
sep = "\t", header = TRUE)
head(peaks, 3)
As a wrapper function, TRESS_peak()
combines multiple subfunctions to
detect m6A regions transcriptome-wide.
The whole process involves following steps:
\(\quad 1\). Divide genome into equal sized bins and obtain read counts in each replicate using
DivideBins()
.
\(\quad 2\). Call candidate regions based on bin-level data across all replicates using
CallCandidates()
\(\quad 3\). Fit Negative binomial models for read counts in candidate regions to
detect and rank peaks among all candidates using CallPeaks.multiRep()
.
If there is only one replicate, functions in step 2
and step 3 will be replaced by
one function CallPeaks.oneRep()
, while function DivideBins()
will still be used to obtain bin-level data. Please see the man pages for
detailed usage of DivideBins()
. Given bin-level data, peak calling
by sub-functions are included in following
Section 4.1 and Section 4.2.
With bin-level read counts, binomial test is first conducted
for each bin. Then an ad hoc bump-finding algorithm
is applied to merge significant bins
(and/or bins with large fold change) and form bumps in each replicate.
Bumps from all input & IP replicates are unioned together to
construct a list of candidate regions.
Both binomial tests and bump-finding are done by
function CallCandidates()
in TRESS.
Here, we use example dataset Basal
introduced in Section 3 to run CallCandidates()
.
## load in first example dataset
data("Basal")
Candidates = CallCandidates(
Counts = Basal$Bins$Counts,
bins = Basal$Bins$Bins
)
After obtaining candidate regions, TRESS models read counts
in candidate regions using a hierarchical negative-binomial model.
Wald tests are then conducted to detect significant regions
from candidates, where a region with methylation level significantly higher than the background is considered as sigificant.
The background methylation level is estimated based on
total read counts
from non-candidate regions, which is calculated as the total
bin-counts subtracted by counts from candidate regions.
This can be obtained using function BgMethylevel()
in TRESS.
With background methylation level estimated,
complete parameter estimation and statistical inference
for candidate regions are achieved by function
CallPeaks.multiRep()
in TRESS, where argument Candidates
is a list containing at least two components: genomic coordinates
(e.g., “chr”, “start” and “end” etc) of all candidate regions
and their read counts across all samples.
Here is an example, provided that the background
methylation level is 0.5,
data("Basal") ### load candidate regions
Basal$Candidates$sf = Basal$Bins$sf
peaks1 = CallPeaks.multiRep(
Candidates = Basal$Candidates,
mu.cutoff = 0.5
)
head(peaks1, 3)
A word about CallPeaks.multiRep()
Different criteria are available in TRESS to filter peaks based on results of Wald tests, including p-values, FDR and
log fold change (logFC).
One needs to first specify a criterion through argument WhichThreshold
and
then provide a cutoff for that criterion
through one or two arguments named *.cutoff
.
By default, TRESS adopts both FDR and
logFC (throughWhichThreshold = "fdr_lfc"
) to select peaks.
The default cutoffs for FDR and logFC are 0.05 and 0.7
(for fold change of 2) respectively, meaning that peaks
with FDR < 0.05 and logFC > 0.7 will be kept.
With WhichThreshold = "fdr_lfc"
, one can
change the cutoffs to more stringent values,
e.g., FDR < 0.01 and logFC > 1.6 by setting
fdr.cutoff = 0.01
and lfc.cutoff = 1.6
:
### use different threshold to filter peaks
peaks2 = CallPeaks.multiRep(
Candidates = Basal$Candidates,
mu.cutoff = 0.5,
fdr.cutoff = 0.01,
lfc.cutoff = 1.6
)
However, one can also set WhichThreshold = "fdr"
to select
peaks only with FDR, then by default peaks
with FDR < 0.05 will be kept:
### use different threshold to filter peaks
peaks3 = CallPeaks.multiRep(
Candidates = Basal$Candidates,
mu.cutoff = 0.5,
WhichThreshold = "fdr"
)
Please read the manual page of function CallPeaks.multiRep()
for more details on each argument.
Given the usage of function “CallPeaks.multiRep()”,
it can also be adopted to re-rank existing peaks with our
developed methods, if their read counts are available.
This may perform bad if one didn’t properly
estimate library size factor (one argument of Candidates
)
for each sample.
Based on our experience, the estimation of size factor
should be based on the bin-level counts across the
whole transcriptome, not the region-level counts.
For background methylation level,
one can use 0.5 but it would be informative if
estimating it from the data.
The above two-step approach is for data with multiple replicates.
For data with only one replicate, TRESS_peak()
calls function CallPeaks.oneRep()
for peak calling given bin-level data. In this case,
bumps in the only one replicate are taken as final list of peaks.
The statistical significance of each peak comes from binomial tests. Here is an example of how to run function CallPeaks.oneRep()
.
# A toy example
data("Basal")
bincounts = Basal$Bins$Counts[, 1:2]
sf0 = Basal$Bins$sf[1:2]
bins = Basal$Bins$Bins
peaks = CallPeaks.oneRep(Counts = bincounts,
sf = sf0, bins = bins)
head(peaks, 3)
With pre-called peaks in hand, one can visualize them using function “ShowOnePeak()” in TRESS. The usage of this function is
ShowOnePeak(onePeak, allBins, binCounts, ext = 500, ylim = c(0,1))
In order to run this function, one needs to have: 1) “onePeak”: a pre-called peak saved as a dataframe, which contains genomic positions for that peak: “chr”, “start”, “end”, “strand”; 2) “allBins”: genomic positions (“chr”, “start”, “end”, “strand”) of bins overlapping at least with the pre-called peak; 3) “binCounts”: the corresponding bin-level read counts in each replicate. This function will plot for each replicate: the methylation level of bins (blue bars) within the target peak (shade region in pink), and the normalized sequencing depth for input samples (curves in grey). We show some example plots here:
peaks = read.table(file.path(system.file(package = "TRESS"),
"extdata/examplebyBam_peaks.xls"),
sep = "\t", header = TRUE)
load(file.path(system.file(package = "TRESS"),
"extdata/examplebyBam.rda"))
allBins = as.data.frame(bins$bins)
colnames(allBins)[1] = "chr"
allBins$strand = binStrand
head(peaks, 1)
## chr start end strand summit lg.fc cb_input_rep1_chr19.bam
## 1 chr19 23239316 23240265 + 23240090 1.357281 529
## cb_ip_rep1_chr19.bam cb_input_rep2_chr19.bam cb_ip_rep2_chr19.bam mu
## 1 6092 380 2479 0.863035
## mu.var stats shrkPhi shrkTheta pvals p.adj rScore
## 1 0.001154263 13.20332 0.002447933 9.974182 0 0 2.850148
ShowOnePeak(onePeak = peaks[1,], allBins = allBins,
binCounts = allCounts)
Unlike peak calling which implements all steps in one function
TRESS_peak()
, TRESS separates the model fitting, which is the most
computationally heavy part, from the hypothesis testing. The model fitting is
implemented by TRESS_DMRfit()
while the hypothesis testing is implemented
by TRESS_DMRtest()
. Given an experimental design with multiple factors,
the parameter estimation (model fitting) only
needs to be performed once, and then the hypothesis
testing for DMR calling can be performed for different
factors efficiently.
Given all required files, differential peak calling in TRESS can be done through,
InputDir = "/directory/to/BAMfile"
Input.file = c("input1.bam", "input2.bam",..., "inputN.bam")
IP.file = c("ip1.bam", "ip2.bam", ..., "ipN.bam")
OutputDir = "/directory/to/output"
Path_sqlit = "/path/to/xxx.sqlite"
variable = "YourVariable" # a dataframe containing both
# testing factor and potential covariates,
# e.g., for a two-group comparison with balanced samples
# variable = data.frame(Trt = rep(c("Ctrl", "Trt"), each = N/2))
model = "YourModel" # e.g. model = ~1 + Trt
DMR.fit = TRESS_DMRfit(IP.file = IP.file,
Input.file = Input.file,
Path_To_AnnoSqlite = Path_sqlit,
variable = variable,
model = model,
InputDir = InputDir,
OutputDir = OutputDir,
experimentName = "xxx"
)
CoefName(DMR.fit)# show the name and order of coefficients
# in the design matrix
Contrast = "YourContrast" # e.g., Contrast = c(0, 1)
DMR.test = TRESS_DMRtest(DMR = DMR.fit, contrast = Contrast)
Similar to TRESS_peak()
, TRESS_DMRfit()
involves
multiple procedures for differential analysis:
\(\quad 1\). Divide the whole genome into equal sized bins and obtain bin
read counts for samples across all conditions using DivideBins()
\(\quad 2\). Loosely call candidate DMRs from samples across
all conditions using CallCandidates()
.
\(\quad 3\). Model candidate DMRs using Negative binomial distribution and
estimates all parameters for each candidate DMR, using
CallDMRs.paramEsti()
.
TRESS applies the same algorithm used in peak calling to call candidate DMRs, which is a union of candidate regions from group-specific samples. Given \(N\) paired input and IP BAM files, candidate DMRs from all samples are obtained using:
InputDir = "/directory/to/BAMfile"
Input.file = c("input1.bam", "input2.bam",..., "inputN.bam")
IP.file = c("ip1.bam", "ip2.bam", ..., "ipN.bam")
OutputDir = "/directory/to/output"
Path_sqlit = "/path/to/xxx.sqlite"
allBins = DivideBins(IP.file = IP.file,
Input.file = Input.file,
Path_To_AnnoSqlite = Path_sqlit,
InputDir = InputDir,
OutputDir = OutputDir,
experimentName = "example")
Candidates = CallCandidates(Counts = allBins$binCount,
bins = allBins$bins)
Candidates = filterRegions(Candidates)
As listed above, prior to DMR detection, TRESS filters out some candidates who have small marginal coefficient of variation in methylation ratio ( \(\frac{\text{normalized } IP}{ \text{normalized } IP \text{ + }\text{normalized } input}\)). Similar to modeling transcriptome regions instead of bins, this pre-filtering step helps to reduce the hypothesis testing space and thus improves statistical power after multiple testing correction.
With candidate DMRs, TRESS fits hierarchical negative binomial models for read counts in them, where methylation level of each candidate DMR is connected to factors of interest using a linear frame work. The Negative binomial model fitting here consists of: (1) estimate coefficients in design matrix for each candidate DMR; (2) estimate dispersion of methylation for each candidate DMR;
After model fitting, TRESS conducts Wald test for each candidate DMR. As mentioned earlier, the methylation level of each candidate is linked to factors in a linear frame work. This characteristic allows for testing all coefficients in the design and any linear combination of them through a particular contrast. Therefore, TRESS can be applied in studies only considering a two-group comparison and studies with a more complex design.
Here, we use a human data DMR_M3vsWT
as an example.
As introduced in the second example dataset in
Section 3, it consists of
read counts in candidate DMRs from
samples under two conditions: WT and M3-KO.
There are two replicates of paired IP and input data for
samples from each condition. Given candidate DMRs,
the estimation of parameters in each candidate DMR
can be done through:
data("DMR_M3vsWT") # data from TRESS
head(DMR_M3vsWT$Counts, 3)
variable = data.frame(predictor = rep(c("WT", "M3"), c(2, 2)))
model = ~1+predictor
DMR.fit = CallDMRs.paramEsti(counts = DMR_M3vsWT$Counts,
sf = DMR_M3vsWT$sf,
variable = variable,
model = model)
Note, the sample order in above variable$predictor
must be exactly the same as that in data matrix DMR_M3vsWT$Counts
.
To compare methylation levels between WT and M3-KO samples, do,
CoefName(DMR.fit) ## show variable name of each coefficient
DMR.test = TRESS_DMRtest(DMR = DMR.fit, contrast = c(0, 1))
DMR.test[which(DMR.test$padj < 0.05)[1:3], ]
The option contrast = c(0, 1)
is equivalent to test
coefficient \(\beta^{predictorWT} = 0\).
Individual DMR can be visualized using function ShowOnePeak()
:
data("DMR_M3vsWT")
snames = paste0(rep(c("WT_", "M3_"), each = 2),
rep(c("Replicate1", "Replicate2"), 2))
ShowOnePeak(onePeak = DMR_M3vsWT$Regions[1, ],
allBins = DMR_M3vsWT$Bins,
binCounts = DMR_M3vsWT$BinsCounts,
isDMR = TRUE,
Sname = snames)
For data from experiments with a general design including multiple factors, hypothesis testing can be performed for one, multiple, or any linear combination of the parameters.
Here, we use an example mouse brain data DMR_SixWeekvsTwoWeek
as an example to
illustrate how TRESS detects DMRs in a multifactor design.
As mentioned in Section 3, it contains
candidate read counts from two mouse brain regions
(cortex and hypothalamus) at two time points (2-week-old and 6-week-old).
Each sample contains two paired input and IP replicates.
To fit TRESS on this data without considering the interaction between time and region, do,
library(TRESS)
data("DMR_SixWeekvsTwoWeek")
variable = data.frame(time = rep(c("2wk", "6wk"), each = 4),
region = rep(rep(c("Cortex", "Hypothalamus"),
each = 2),2)
)
model = ~1 + time + region
DMRfit = CallDMRs.paramEsti(counts = DMR_SixWeekvsTwoWeek$Counts,
sf = DMR_SixWeekvsTwoWeek$sf,
variable = variable,
model = model)
## [1] "Start to estimate preliminary MLE ..."
## [1] "Update phi with its posterior ..."
## The 1th sampling of data...
## The 2th sampling of data...
## The 3th sampling of data...
## The 4th sampling of data...
## The 5th sampling of data...
## The 6th sampling of data...
## The 7th sampling of data...
## The 8th sampling of data...
## The 9th sampling of data...
## The 10th sampling of data...
## [1] "Calculate variance-covariance of coefficients..."
## [1] "Output all estimate..."
Again, the sample order in variable$time
and in
variable$region
must be exactly the same as that
in data matrix DMR_SixWeekvsTwoWeek$Counts
.
To test the whole time effect, do:
CoefName(DMRfit)
## [1] "(Intercept)" "time6wk" "regionHypothalamus"
DMRtest = TRESS_DMRtest(DMRfit, contrast = c(0, 1, 0))
idx = order(abs(DMRtest$stat), decreasing = TRUE)
DMRtest[idx[1:3], ]
## baseMean logOR lorSE stat pvalue padj
## 1 0.4834676 1.3607333 0.2450986 5.552 2.827751e-08 5.514115e-06
## 2 0.6561851 -0.9591358 0.1850525 -5.183 2.182882e-07 2.128310e-05
## 4 0.6205323 -1.4985708 0.3041586 -4.927 8.352760e-07 4.244322e-05
DMR_SixWeekvsTwoWeek$MeRatio[idx[1:3],]
## 2wk_Cortex_rep1 2wk_Cortex_rep2 2wk_Hypothalamus_rep1 2wk_Hypothalamus_rep2
## 1 0.1958101 0.3814389 0.3317863 0.3795577
## 2 0.7854077 0.7823082 0.6885950 0.7802045
## 4 0.7863946 0.9102105 0.7269940 0.7425612
## 6wk_Cortex_rep1 6wk_Cortex_rep2 6wk_Hypothalamus_rep1 6wk_Hypothalamus_rep2
## 1 0.5260813 0.5728586 0.7698927 0.7103151
## 2 0.5797789 0.5206678 0.5920979 0.5204208
## 4 0.4573393 0.2143442 0.5448147 0.5816000
Here, the reason we specify contrast = c(0, 1, 0)
is that
the second column of design
matrix model.matrix( model, variable)
corresponds to time.
This contrast is equivalent to test the
coefficient of time equal to 0, i.e., \(\beta^{\text{time6wk}} = 0\).
If one considers the interaction between time and region and
wants to test region-specific time effect, just include time*region
into model
and do,
model.int = ~1+ time + region + time*region
model.matrix( model.int, variable)
## (Intercept) time6wk regionHypothalamus time6wk:regionHypothalamus
## 1 1 0 0 0
## 2 1 0 0 0
## 3 1 0 1 0
## 4 1 0 1 0
## 5 1 1 0 0
## 6 1 1 0 0
## 7 1 1 1 1
## 8 1 1 1 1
## attr(,"assign")
## [1] 0 1 2 3
## attr(,"contrasts")
## attr(,"contrasts")$time
## [1] "contr.treatment"
##
## attr(,"contrasts")$region
## [1] "contr.treatment"
DMRfit.int = CallDMRs.paramEsti(
counts = DMR_SixWeekvsTwoWeek$Counts,
sf = DMR_SixWeekvsTwoWeek$sf,
variable = variable,
model = model.int
)
## [1] "Start to estimate preliminary MLE ..."
## [1] "Update phi with its posterior ..."
## The 1th sampling of data...
## The 2th sampling of data...
## The 3th sampling of data...
## The 4th sampling of data...
## The 5th sampling of data...
## The 6th sampling of data...
## The 7th sampling of data...
## The 8th sampling of data...
## The 9th sampling of data...
## The 10th sampling of data...
## [1] "Calculate variance-covariance of coefficients..."
## [1] "Output all estimate..."
Then, in cortex, DMRs caused by time effect can be obtained through:
CoefName(DMRfit.int)
## [1] "(Intercept)" "time6wk"
## [3] "regionHypothalamus" "time6wk:regionHypothalamus"
CTX.6vs2 = TRESS_DMRtest(DMRfit.int, contrast = c(0, 1, 0, 0))
idx = order(abs(CTX.6vs2$stat), decreasing = TRUE)
CTX.6vs2[idx[1:3], ]
## baseMean logOR lorSE stat pvalue padj
## 4 0.6205323 -2.276190 0.4100658 -5.551 2.843795e-08 5.687590e-06
## 255 0.3451794 3.339234 0.6153009 5.427 5.731112e-08 5.731112e-06
## 3 0.5438187 -1.173738 0.2545293 -4.611 3.999513e-06 2.666342e-04
DMR_SixWeekvsTwoWeek$MeRatio[
idx[1:3],
grepl("Cortex",colnames(DMR_SixWeekvsTwoWeek$MeRatio))]
## 2wk_Cortex_rep1 2wk_Cortex_rep2 6wk_Cortex_rep1 6wk_Cortex_rep2
## 4 0.7863946 0.9102105 0.4573393 0.2143442
## 255 0.1108468 0.1071387 0.7124642 0.9036763
## 3 0.6177052 0.7435040 0.4566768 0.3327581
In hypothalamus, DMRs caused by time effect can be obtained through:
HTH.6vs2 = TRESS_DMRtest(DMRfit.int, contrast = c(0, 1, 0, 1))
idx = order(abs(HTH.6vs2$stat), decreasing = TRUE)
HTH.6vs2[idx[1:3], ]
## baseMean logOR lorSE stat pvalue padj
## 64 0.5472207 2.106293 0.4145625 5.081 3.759274e-07 7.518548e-05
## 1 0.4834676 1.602397 0.3427196 4.676 2.931897e-06 2.931897e-04
## 36 0.5742661 2.005997 0.4481641 4.476 7.604350e-06 4.475474e-04
DMR_SixWeekvsTwoWeek$MeRatio[
idx[1:3],
grepl("Hypothalamus",colnames(DMR_SixWeekvsTwoWeek$MeRatio))]
## 2wk_Hypothalamus_rep1 2wk_Hypothalamus_rep2 6wk_Hypothalamus_rep1
## 64 0.3211882 0.5110739 0.8158931
## 1 0.3317863 0.3795577 0.7698927
## 36 0.3121385 0.4428793 0.8194071
## 6wk_Hypothalamus_rep2
## 64 0.9110851
## 1 0.7103151
## 36 0.8325004
Detection of DMRs by interaction of time and region (meaning that the temporal difference in methylation of these DMRs changes spatially) can be done through:
CTXvsHTH.6vs2 = TRESS_DMRtest(DMRfit.int, contrast = c(0, 0, 0, 1))
idx = order(abs(CTXvsHTH.6vs2$stat), decreasing = TRUE)
CTXvsHTH.6vs2[idx[1:3], ]
## baseMean logOR lorSE stat pvalue padj
## 255 0.3451794 -3.908651 0.7947053 -4.918 8.726963e-07 0.0001745393
## 669 0.7239899 1.736373 0.4252336 4.083 4.439317e-05 0.0036570899
## 672 0.5599793 -4.510067 1.1250237 -4.009 6.101147e-05 0.0036570899
DMR_SixWeekvsTwoWeek$MeRatio[
idx[1:3], c(1,2,5,6,3,4,7,8)]
## 2wk_Cortex_rep1 2wk_Cortex_rep2 6wk_Cortex_rep1 6wk_Cortex_rep2
## 255 0.1108468 0.1071387 0.7124642 0.9036763
## 669 0.7854224 0.6935109 0.6467831 0.6260932
## 672 0.4999804 0.1310775 0.7862882 0.9368236
## 2wk_Hypothalamus_rep1 2wk_Hypothalamus_rep2 6wk_Hypothalamus_rep1
## 255 0.2491189 0.3024580 0.1488874
## 669 0.5920845 0.7076847 0.8763107
## 672 0.6902550 0.6243643 0.1551789
## 6wk_Hypothalamus_rep2
## 255 0.1819433
## 669 0.8640297
## 672 0.6559275
## R version 4.2.1 (2022-06-23)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 20.04.5 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.16-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.16-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] stats4 parallel stats graphics grDevices utils datasets
## [8] methods base
##
## other attached packages:
## [1] GenomicFeatures_1.50.0 AnnotationDbi_1.60.0 Biobase_2.58.0
## [4] GenomicRanges_1.50.0 GenomeInfoDb_1.34.0 IRanges_2.32.0
## [7] TRESS_1.4.0 S4Vectors_0.36.0 BiocGenerics_0.44.0
## [10] BiocStyle_2.26.0
##
## loaded via a namespace (and not attached):
## [1] MatrixGenerics_1.10.0 httr_1.4.4
## [3] sass_0.4.2 bit64_4.0.5
## [5] jsonlite_1.8.3 bslib_0.4.0
## [7] assertthat_0.2.1 BiocManager_1.30.19
## [9] highr_0.9 BiocFileCache_2.6.0
## [11] blob_1.2.3 GenomeInfoDbData_1.2.9
## [13] Rsamtools_2.14.0 yaml_2.3.6
## [15] progress_1.2.2 lattice_0.20-45
## [17] pillar_1.8.1 RSQLite_2.2.18
## [19] glue_1.6.2 digest_0.6.30
## [21] XVector_0.38.0 Matrix_1.5-1
## [23] htmltools_0.5.3 XML_3.99-0.12
## [25] pkgconfig_2.0.3 biomaRt_2.54.0
## [27] magick_2.7.3 bookdown_0.29
## [29] zlibbioc_1.44.0 BiocParallel_1.32.0
## [31] tibble_3.1.8 KEGGREST_1.38.0
## [33] generics_0.1.3 ellipsis_0.3.2
## [35] SummarizedExperiment_1.28.0 cachem_1.0.6
## [37] cli_3.4.1 magrittr_2.0.3
## [39] crayon_1.5.2 memoise_2.0.1
## [41] evaluate_0.17 fansi_1.0.3
## [43] xml2_1.3.3 tools_4.2.1
## [45] prettyunits_1.1.1 hms_1.1.2
## [47] matrixStats_0.62.0 BiocIO_1.8.0
## [49] lifecycle_1.0.3 stringr_1.4.1
## [51] DelayedArray_0.24.0 Biostrings_2.66.0
## [53] compiler_4.2.1 jquerylib_0.1.4
## [55] rlang_1.0.6 grid_4.2.1
## [57] RCurl_1.98-1.9 rjson_0.2.21
## [59] rappdirs_0.3.3 bitops_1.0-7
## [61] rmarkdown_2.17 restfulr_0.0.15
## [63] codetools_0.2-18 DBI_1.1.3
## [65] curl_4.3.3 R6_2.5.1
## [67] GenomicAlignments_1.34.0 knitr_1.40
## [69] dplyr_1.0.10 rtracklayer_1.58.0
## [71] fastmap_1.1.0 bit_4.0.4
## [73] utf8_1.2.2 filelock_1.0.2
## [75] stringi_1.7.8 Rcpp_1.0.9
## [77] vctrs_0.5.0 png_0.1-7
## [79] dbplyr_2.2.1 tidyselect_1.2.0
## [81] xfun_0.34