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DESeq2 with Global Perturbations
In BRGenomics: Tools for the Efficient Analysis of High-Resolution Genomics Data
Using DESeq2 for Pairwise Differential Expression
Rationale
DESeq2's default treatment of data relies on the assumption that genewise
estimates of dispersion are largely unchanged across samples. While this
assumption holds for a typical RNA-seq data, it can be violated if there are
samples within the DESeqDataSet object for which there are meaningful signal
changes across a majority of regions of interest.
The BRGenomics functions getDESeqDataSet() and getDESeqResults() are simple
and flexible wrappers for making pairwise comparisons between individual
samples, without relying on the assumption of globally-similar dispersion
estimates. In particular, getDESeqResults() follows the logic that the
presence of a dataset $X$ within the DESeqDataSet object will not affect the
comparison of datasets $Y$ and $Z$.
While the intuition above is appealing, users should note that if the
globally-similar dispersions assumption does hold, then DESeq2's default
behavior should be more sensitive in its estimates of genewise dispersion. In
this case, users can still take advantage of the convenience of the BRGenomics
function getDESeqDataSet(), but they should subsequently call
DESeq2::DESeq() and DESeq2::results() directly.
If the globally-similar dispersions assumption is violated, but something beyond
simple pairwise comparisons is desired (e.g. group comparisons or additional
model terms), we note that, with some prying, DESeq2 can be used without "blind
dispersion estimation" (see the DESeq2 manual).
Formatting Data for DESeq2
Just like the functions that generate batch-normalized spike-in normalization
factors, the DESeq-oriented functions require that the names of the input
datasets end in "rep1", "rep2", etc.
Let's first make a toy list of multiple datasets to compare:
library(BRGenomics)
data("PROseq")
ps_list <- lapply(1:6, function(i) PROseq[seq(i, length(PROseq), 6)])
names(ps_list) <- c("A_rep1", "A_rep2",
"B_rep1", "B_rep2",
"C_rep1", "C_rep2")
ps_list[1:2]
names(ps_list)
As you can see, the names all end in "repX", where X indicates the replicate.
Replicates will be grouped by anything that follows "rep". If the sample names
do not conform to this standard, the sample_names argument can be used to
rename the samples within the call to getDESeqDataSet().
data("txs_dm6_chr4")
dds <- getDESeqDataSet(ps_list, txs_dm6_chr4,
gene_names = txs_dm6_chr4$gene_id,
ncores = 1)
dds
Notice that the dim attribute of the DESeqDataSet object is c(111, 6).
There are 6 samples, but length(txs_dm6_chr4) is not 111. This is because we
provided gene names to getDESeqDataSet(), which were non-unique. The feature
being exploited here is for use with discontinuous gene regions, not for
multiple overlapping transcript isoforms.
By default, getDESeqDataSet() will combine counts across all ranges
belonging to a gene, but if they overlap, they will be counted twice. For
addressing issues related to overlaps, see the reduceByGene() and
intersectByGene() functions.
We could have added normalization factors, which DESeq2 calls "size factors", in
the call to getDESeqDataSet(), or we can supply them to getDESeqResults()
below. (Supplying them twice will overwrite the previous size factors).
Important note on normalization factors: DESeq2 "size factors" are the
inverse of BRGenomics normalization factors. So if you calculate normalization
factors with NF <- getSpikeInNFs(...), set sizeFactors <- 1/NF.
Getting DESeq2 Results
Generating DESeq2 results is simple:
getDESeqResults(dds, contrast.numer = "B", contrast.denom = "A",
quiet = TRUE, ncores = 1)
We can also make multiple pairwise-comparisons by ignoring the contrast.numer
and contrast.denom arguments, and instead using the comparisons argument.
The resulting list of results is named according to the comparisons:
comparison_list <- list(c("B", "A"),
c("C", "A"),
c("C", "B"))
dsres <- getDESeqResults(dds, comparisons = comparison_list,
quiet = TRUE, ncores = 1)
names(dsres)
dsres$C_vs_B
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BRGenomics documentation built on Nov. 8, 2020, 8:03 p.m.
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Using DESeq2 for Pairwise Differential Expression
Rationale
DESeq2's default treatment of data relies on the assumption that genewise
estimates of dispersion are largely unchanged across samples. While this
assumption holds for a typical RNA-seq data, it can be violated if there are
samples within the DESeqDataSet object for which there are meaningful signal
changes across a majority of regions of interest.
The BRGenomics functions getDESeqDataSet() and getDESeqResults() are simple
and flexible wrappers for making pairwise comparisons between individual
samples, without relying on the assumption of globally-similar dispersion
estimates. In particular, getDESeqResults() follows the logic that the
presence of a dataset $X$ within the DESeqDataSet object will not affect the
comparison of datasets $Y$ and $Z$.
While the intuition above is appealing, users should note that if the
globally-similar dispersions assumption does hold, then DESeq2's default
behavior should be more sensitive in its estimates of genewise dispersion. In
this case, users can still take advantage of the convenience of the BRGenomics
function getDESeqDataSet(), but they should subsequently call
DESeq2::DESeq() and DESeq2::results() directly.
If the globally-similar dispersions assumption is violated, but something beyond simple pairwise comparisons is desired (e.g. group comparisons or additional model terms), we note that, with some prying, DESeq2 can be used without "blind dispersion estimation" (see the DESeq2 manual).
Formatting Data for DESeq2
Just like the functions that generate batch-normalized spike-in normalization
factors, the DESeq-oriented functions require that the names of the input
datasets end in "rep1", "rep2", etc.
Let's first make a toy list of multiple datasets to compare:
library(BRGenomics) data("PROseq")
ps_list <- lapply(1:6, function(i) PROseq[seq(i, length(PROseq), 6)]) names(ps_list) <- c("A_rep1", "A_rep2", "B_rep1", "B_rep2", "C_rep1", "C_rep2")
ps_list[1:2] names(ps_list)
As you can see, the names all end in "repX", where X indicates the replicate.
Replicates will be grouped by anything that follows "rep". If the sample names
do not conform to this standard, the sample_names argument can be used to
rename the samples within the call to getDESeqDataSet().
data("txs_dm6_chr4")
dds <- getDESeqDataSet(ps_list, txs_dm6_chr4, gene_names = txs_dm6_chr4$gene_id, ncores = 1) dds
Notice that the dim attribute of the DESeqDataSet object is c(111, 6).
There are 6 samples, but length(txs_dm6_chr4) is not 111. This is because we
provided gene names to getDESeqDataSet(), which were non-unique. The feature
being exploited here is for use with discontinuous gene regions, not for
multiple overlapping transcript isoforms.
By default, getDESeqDataSet() will combine counts across all ranges
belonging to a gene, but if they overlap, they will be counted twice. For
addressing issues related to overlaps, see the reduceByGene() and
intersectByGene() functions.
We could have added normalization factors, which DESeq2 calls "size factors", in
the call to getDESeqDataSet(), or we can supply them to getDESeqResults()
below. (Supplying them twice will overwrite the previous size factors).
Important note on normalization factors: DESeq2 "size factors" are the
inverse of BRGenomics normalization factors. So if you calculate normalization
factors with NF <- getSpikeInNFs(...), set sizeFactors <- 1/NF.
Getting DESeq2 Results
Generating DESeq2 results is simple:
getDESeqResults(dds, contrast.numer = "B", contrast.denom = "A", quiet = TRUE, ncores = 1)
We can also make multiple pairwise-comparisons by ignoring the contrast.numer
and contrast.denom arguments, and instead using the comparisons argument.
The resulting list of results is named according to the comparisons:
comparison_list <- list(c("B", "A"), c("C", "A"), c("C", "B")) dsres <- getDESeqResults(dds, comparisons = comparison_list, quiet = TRUE, ncores = 1) names(dsres) dsres$C_vs_B
Try the BRGenomics 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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