Analysis of transcription factor binding motifs using Position Weight Matrices (PWMs) is a common task in analysis of genomic data. Two key tests for analysis of TFBMs using morifTestR are demonstrated below
motifTestR 1.3.1
Bioinformatic analysis of data from ChIP-Seq and ATAC-Seq commonly involves the analysis of sequences within the regions identified is being of interest. Whilst these analyses are not restricted to transcription factors, this can often form an important component of this type of analysis. Analysis of Transcription Factor Binding Motifs (TFBMs) is often performed using Position Weight Matrices (PWMs) to encode the flexibility in which exact sequence is bound by the particular transcription factor, and is a computationally demanding task with many popular tools enabling analysis outside of R.
The tools within motifTestR
aim to build on and expand the existing resources available to the Bioconductor community, performing all analyses inside the R environment.
The package offers two complementary approaches to TFBM analysis within XStringSet
objects containing multiple sequences.
The function testMotifPos()
identifies motifs showing positional bias within a set of sequences, whilst overall enrichment within a set of sequences is enabled by testMotifEnrich()
.
These are then extended to analyse motifs grouped into “clusters” using testClusterPos()
and testClusterEnrich()
.
Additional functions aid in the visualisation and preparation of these two key
approaches.
In order to perform the operations in this vignette, first install motifTestR
.
if (!"BiocManager" %in% rownames(installed.packages()))
install.packages("BiocManager")
BiocManager::install("motifTestR")
Once installed, we can load all required packages, set a default plotting theme and setup how many threads to use during the analysis.
library(motifTestR)
library(extraChIPs)
library(rtracklayer)
library(BSgenome.Hsapiens.UCSC.hg19)
library(parallel)
library(ggplot2)
library(patchwork)
library(universalmotif)
theme_set(theme_bw())
cores <- 1
The peaks used in this workflow were obtained from the bed files denoting binding sites of the Androgen Receptor and Estrogen Receptor along with H3K27ac marks, in ZR-75-1 cells under DHT treatment (Hickey et al. 2021).
The object ar_er_peaks
contains a subset of 849 peaks found within chromosome 1, with all peaks resized to 400bp
data("ar_er_peaks")
ar_er_peaks
## GRanges object with 849 ranges and 0 metadata columns:
## seqnames ranges strand
## <Rle> <IRanges> <Rle>
## [1] chr1 1008982-1009381 *
## [2] chr1 1014775-1015174 *
## [3] chr1 1051296-1051695 *
## [4] chr1 1299561-1299960 *
## [5] chr1 2179886-2180285 *
## ... ... ... ...
## [845] chr1 246771887-246772286 *
## [846] chr1 246868678-246869077 *
## [847] chr1 246873126-246873525 *
## [848] chr1 247095351-247095750 *
## [849] chr1 247267507-247267906 *
## -------
## seqinfo: 24 sequences from hg19 genome
sq <- seqinfo(ar_er_peaks)
Whilst the example dataset is small for the convenience of an R package, those wishing to work on the complete set of peaks (i.e. not just chromosome 1) may run the code provided in the final section to obtain all peaks. This will produce a greater number of significant results in subsequent analyses but will also increase running times for all functions.
Now that we have genomic co-ordinates as a set of peaks, we can obtain the sequences that are associated with each peak. The source ranges can optionally be added to the sequences as names by coercing the ranges to a character vector.
test_seq <- getSeq(BSgenome.Hsapiens.UCSC.hg19, ar_er_peaks)
names(test_seq) <- as.character(ar_er_peaks)
A small list of Position Frequency Matrices (PFMs), obtained from MotifDb are provided with the package and these will be suitable for all downstream analysis. All functions will convert PFMs to PWMs internally.
data("ex_pfm")
names(ex_pfm)
## [1] "ESR1" "ANDR" "FOXA1" "ZN143" "ZN281"
ex_pfm$ESR1
## 1 2 3 4 5 6 7 8 9 10 11 12 13
## A 0.638 0.074 0.046 0.094 0.002 0.856 0.108 0.396 0.182 0.104 0.054 0.618 0.040
## C 0.048 0.006 0.018 0.072 0.888 0.006 0.442 0.604 0.376 0.078 0.034 0.198 0.884
## G 0.260 0.808 0.908 0.178 0.048 0.112 0.312 0.000 0.286 0.044 0.908 0.070 0.014
## T 0.054 0.112 0.028 0.656 0.062 0.026 0.138 0.000 0.156 0.774 0.004 0.114 0.062
## 14 15
## A 0.090 0.058
## C 0.822 0.330
## G 0.008 0.066
## T 0.080 0.546
Again, a larger set of motifs may be obtained using or modifying the example code at the end of the vignette
All PWM matches within the test sequences can be returned for any of the PWMs, with getPwmMatches()
searching using the PWM and it’s reverse complement by default.
Matches are returned showing their position within the sequence, as well as the distance from the centre of the sequence and the matching section within the larger sequence.
Whilst there is no strict requirement for sequences of the same width, generally this is good practice for this type of analysis and is commonly a requirement for downstream statistical analysis.
score_thresh <- "70%"
getPwmMatches(ex_pfm$ESR1, test_seq, min_score = score_thresh)
## DataFrame with 51 rows and 8 columns
## seq score direction start end from_centre
## <character> <numeric> <factor> <integer> <integer> <numeric>
## 1 chr1:1008982-1009381 17.3522 R 216 230 23
## 2 chr1:6543164-6543563 15.7958 R 176 190 -17
## 3 chr1:10010470-10010869 18.0880 F 193 207 0
## 4 chr1:11434290-11434689 20.8412 R 321 335 128
## 5 chr1:17855904-17856303 15.7429 F 195 209 2
## ... ... ... ... ... ... ...
## 47 chr1:212731397-21273.. 16.1154 R 88 102 -105
## 48 chr1:214500812-21450.. 17.1325 R 186 200 -7
## 49 chr1:217979498-21797.. 16.6438 F 186 200 -7
## 50 chr1:233243433-23324.. 15.7178 F 201 215 8
## 51 chr1:247267507-24726.. 16.8796 F 313 327 120
## seq_width match
## <integer> <DNAStringSet>
## 1 400 TGGTCACAGTGACCT
## 2 400 GGGTCATCCTGTCCC
## 3 400 AGGTCACCCTGGCCC
## 4 400 AGGTCACCGTGACCC
## 5 400 AGGGCAAAATGACCC
## ... ... ...
## 47 400 GTGTCACAGTGACCC
## 48 400 AGGTCACAATGACAT
## 49 400 GGGTCATCCTGCCCC
## 50 400 AGGTCATAAAGACCT
## 51 400 AGGTCAGAATGACCG
Many sequences will contain multiple matches, and we can subset our results to only the ‘best match’ by setting best_only = TRUE
.
The best match is chosen by the highest score returned for each match.
If multiple matches return identical scores, all tied matches are returned by default and will be equally down-weighted during positional analysis.
This can be further controlled by setting break_ties
to any of c(“random”, “first”, “last”, “central”), which will choose randomly, by sequence order or proximity to centre.
getPwmMatches(ex_pfm$ESR1, test_seq, min_score = score_thresh, best_only = TRUE)
## DataFrame with 50 rows and 8 columns
## seq score direction start end from_centre
## <character> <numeric> <factor> <integer> <integer> <numeric>
## 1 chr1:1008982-1009381 17.3522 R 216 230 23
## 2 chr1:6543164-6543563 15.7958 R 176 190 -17
## 3 chr1:10010470-10010869 18.0880 F 193 207 0
## 4 chr1:11434290-11434689 20.8412 R 321 335 128
## 5 chr1:17855904-17856303 15.7429 F 195 209 2
## ... ... ... ... ... ... ...
## 46 chr1:212731397-21273.. 16.1154 R 88 102 -105
## 47 chr1:214500812-21450.. 17.1325 R 186 200 -7
## 48 chr1:217979498-21797.. 16.6438 F 186 200 -7
## 49 chr1:233243433-23324.. 15.7178 F 201 215 8
## 50 chr1:247267507-24726.. 16.8796 F 313 327 120
## seq_width match
## <integer> <DNAStringSet>
## 1 400 TGGTCACAGTGACCT
## 2 400 GGGTCATCCTGTCCC
## 3 400 AGGTCACCCTGGCCC
## 4 400 AGGTCACCGTGACCC
## 5 400 AGGGCAAAATGACCC
## ... ... ...
## 46 400 GTGTCACAGTGACCC
## 47 400 AGGTCACAATGACAT
## 48 400 GGGTCATCCTGCCCC
## 49 400 AGGTCATAAAGACCT
## 50 400 AGGTCAGAATGACCG
We can return all matches for a complete list of PWMs, as a list of DataFrame objects. This strategy allows for visualisation of results as well as testing for positional bias.
bm_all <- getPwmMatches(
ex_pfm, test_seq, min_score = score_thresh, best_only = TRUE, break_ties = "all",
mc.cores = cores
)
This same strategy of passing a single, or multiple PWMs can be applied even when simply wishing to count the total matches for each PWM. Counting may be useful for restricting downstream analysis to the set of motifs with more than a given number of matches.
countPwmMatches(ex_pfm, test_seq, min_score = score_thresh, mc.cores = cores)
## ESR1 ANDR FOXA1 ZN143 ZN281
## 51 36 292 43 46
A commonly used tool within the MEME-Suite is centrimo
(Bailey and Machanick 2012) and motifTestR
provides a simple, easily interpretable alternative approach using testMotifPos()
.
This function bins the distances from the centre of each sequence with the central bin being symmetrical around zero, and if no positional bias is expected (i.e. H0), matches should be equally distributed between bins.
Unlike centrimo
, no assumption of centrality is made and any notable deviations from a discrete uniform distribution may be considered as significant.
A test within each bin is performed using binom.test()
and a single, summarised p-value across all bins is returned using the asymptotically exact harmonic mean p-value (HMP) (Wilson 2019).
By default, the binomial test is applied for the null hypothesis to detect matches in each bin which are greater than expected, however, this can also be set by the user.
When using the harmonic-mean p-value however, choosing the alternate hypothesis as “greater” tends return a more conservative p-value across the entire set of bins.
res_pos <- testMotifPos(bm_all, mc.cores = cores)
head(res_pos)
## start end centre width total_matches matches_in_region expected
## ESR1 5 15 10 10 50 8 1.291990
## ANDR -25 -5 -15 20 34 12 1.770833
## FOXA1 -5 25 10 30 238 32 12.205128
## ZN143 -55 55 0 110 26 20 5.473684
## ZN281 -195 195 0 390 40 38 25.529716
## enrichment prop_total p fdr consensus_motif
## ESR1 6.192000 0.1600000 0.001643146 0.008215728 35, 0, 1....
## ANDR 6.776471 0.3529412 0.004700634 0.011751585 0, 0, 0,....
## FOXA1 2.621849 0.1344538 0.010576124 0.017626873 0, 0, 0,....
## ZN143 3.653846 0.7692308 0.243171867 0.303964834 6, 1, 13....
## ZN281 1.488462 0.9500000 0.977504172 0.977504172 8, 6, 22....
The bins returned by the function represent the widest range of bins where the raw p-values were below the HMP.
Wide ranges tend to be associated with lower significance for a specific PWM.
This is a further point of divergence from centrimo
in that results are dependent on the pre-determined bin-size and the region of enrichment is formed using p-values, instead of the adaptive methods of centrimo
(Bailey and Machanick 2012).
Due to the two-stranded nature of DNA, the distance from zero can also be assessed by setting abs = TRUE
and in this case the first bin begins at zero.
res_abs <- testMotifPos(bm_all, abs = TRUE, mc.cores = cores)
head(res_abs)
## start end centre width total_matches matches_in_region expected
## ESR1 10 20 15 10 50 11 2.590674
## ANDR 10 20 15 10 34 8 1.770833
## FOXA1 0 30 15 30 238 69 36.615385
## ZN143 0 50 25 50 26 20 6.842105
## ZN281 0 190 95 190 40 38 33.160622
## enrichment prop_total p fdr consensus_motif
## ESR1 4.246000 0.2200000 0.0007907262 0.003953631 35, 0, 1....
## ANDR 4.517647 0.2352941 0.0057468643 0.014367161 0, 0, 0,....
## FOXA1 1.884454 0.2899160 0.0106210602 0.017701767 0, 0, 0,....
## ZN143 2.923077 0.7692308 0.1963203926 0.245400491 6, 1, 13....
## ZN281 1.145938 0.9500000 0.9173293626 0.917329363 8, 6, 22....
This approach is particularly helpful for detecting co-located transcription factors which can be any distance from the TF which was used to obtain and centre the test set of sequences.
The complete set of matches returned as a list above can be simply passed to ggplot2
(Wickham 2016) for visualisation, in order to asses whether any PWM appears to have a positional bias.
By default, smoothed values across all motifs will be overlaid (Figure 1A), however, tailoring using ggplot is simple to produce a wide variety of outputs (Figure 1B)
topMotifs <- res_pos |>
subset(fdr < 0.05) |>
rownames()
A <- plotMatchPos(bm_all[topMotifs], binwidth = 10, se = FALSE)
B <- plotMatchPos(
bm_all[topMotifs], binwidth = 10, geom = "col", use_totals = TRUE
) +
geom_smooth(se = FALSE, show.legend = FALSE) +
facet_wrap(~name)
A + B + plot_annotation(tag_levels = "A") & theme(legend.position = "bottom")
Whilst the above will produce figures showing the symmetrical distribution around the peak centres, the distance from the peak centre can also be shown as an absolute distance. In Figure 2 distances shown as a heatmap (A) or as a CDF (B). The latter makes it easy to see that 50% of ESR1 matches occur within a short distance of the centre (~25bp), whilst for ANDR and FOXA1, this distance is roughly doubled. Changing the binwidth argument can either smooth data or increase the fine resolution.
topMotifs <- res_abs |>
subset(fdr < 0.05) |>
rownames()
A <- plotMatchPos(bm_all[topMotifs], abs = TRUE, type = "heatmap") +
scale_fill_viridis_c()
B <- plotMatchPos(
bm_all[topMotifs], abs = TRUE, type = "cdf", geom = "line", binwidth = 5
)
A + B + plot_annotation(tag_levels = "A") & theme(legend.position = "bottom")
As well as providing methods for analysing positional bias within a set of PWM matches, methods to test for enrichment are also implemented in motifTestR
.
A common approach when testing for motif enrichment is to obtain a set of random or background sequences which represent a suitable control set to define the null hypothesis (H0).
In motifTestR
, two alternatives are offered utilising this approach, which both return similar results but involve different levels of computational effort.
The first approach is to sample multiple sets of background sequences and by ‘iterating’ through to obtain a null distribution for PWM matches and comparing our observed counts against this distribution.
It has been noticed that this approach commonly produces a set of counts for H0 which closely resemble a Poisson distribution, and a second approach offered in motifTestR
is to sample a suitable large set of background sequences and estimate the parameters for the Poisson distribution for each PWM, and testing against these.
Choosing a suitable set of control sequences can be undertaken by any number of methods.
motifTestR
enables a strategy of matching sequences by any number of given features.
The data object zr75_enh
contains the candidate enhancers for ZR-75-1 cells defined by v2.0 of the Enhancer Atlas (Gao and Qian 2019), for chromosome 1 only.
A high proportion of our peaks are associated with these regions and choosing control sequences drawn from the same proportion of these regions may be a viable strategy.
data("zr75_enh")
mean(overlapsAny(ar_er_peaks, zr75_enh))
## [1] 0.6914016
First we can annotate each peak by whether there is any overlap with an enhancer, or whether the peak belongs to any other region. Next we can define two sets of GenomicRanges, one representing the enhancers and the other being the remainder of the genome, here restricted to chromosome 1 for consistency. Control regions can be drawn from each with proportions that match the test set of sequences.
ar_er_peaks$feature <- ifelse(
overlapsAny(ar_er_peaks, zr75_enh), "enhancer", "other"
)
chr1 <- GRanges(sq)[1]
bg_ranges <- GRangesList(
enhancer = zr75_enh,
other = GenomicRanges::setdiff(chr1, zr75_enh)
)
The provided object hg19_mask
contains regions of the genome which are rich in Ns, such as centromeres and telomeres.
Sequences containing Ns produce warning messages when matching PWMs and avoiding these regions may be wise, without introducing any sequence bias.
These are then passed to makeRMRanges()
as ranges to be excluded, whilst sampling multiple random, size-matched ranges corresponding to our test set of ranges with sequences being analysed, and drawn proportionally from matching genomic regions.
Whilst our example only used candidate enhancers, any type and number of genomic regions can be used, with a limitless number of classification strategies being possible.
data("hg19_mask")
set.seed(305)
rm_ranges <- makeRMRanges(
splitAsList(ar_er_peaks, ar_er_peaks$feature),
bg_ranges, exclude = hg19_mask,
n_iter = 100
)
This has now returned a set of control ranges which are randomly-selected (R) size-matched (M) to our peaks and are drawn from a similar distribution of genomic features.
By setting n_iter = 100
, this set will be 100 times larger than our test set and typically this value can be set to 1000 or even 5000 for better estimates of parameters under the null distribution.
However, this will increase the computational burden for analysis.
If not choosing an iterative strategy, a total number of sampled ranges can also be specified.
In this case the column iteration
will not be added to the returned ranges.
In order to perform the analysis, we can now extract the genomic sequences corresponding to our randomly selected control ranges.
Passing the mcols
element ensure the iteration numbers are passed to the sequences, as these are required for this approach.
rm_seq <- getSeq(BSgenome.Hsapiens.UCSC.hg19, rm_ranges)
mcols(rm_seq) <- mcols(rm_ranges)
If choosing strategies for enrichment testing outside of motifTestR
, these sequences can be exported as a fasta file using writeXStringSet
from the Biostrings package.
Testing for overall motif enrichment is implemented using multiple strategies, using Poisson, QuasiPoisson or pure Iterative approaches. Whilst some PWMs may closely follow a Poisson distribution under H0, others may be over-dispersed and more suited to a Quasi-Poisson approach. Each approach has unique advantages and weaknesses as summarised below:
From a per iteration perspective there is little difference between the Iterative and the modelled QuasiPoisson approaches, however the modelled approaches can still return reliable results from a lower number of iterative blocks, lending a clear speed advantage. Z-scores returned are only used for statistical testing under the iterative approach and are for indicative purposes only under all other models model.
Whilst no guidelines have been developed for an optimal number of sequences, a control set which is orders of magnitude larger than the test set may be prudent. A larger set of control sequences clearly leads to longer analytic time-frames and larger computational resources, so this is left to what is considered appropriate by the researcher, nothing that here, we chose a control set which is 100x larger than our test sequences. If choosing an iterative approach and using the iteration-derived p-values, setting a number of iterations based on the resolution required for these values may be important, noting that the lowest possible p-value is 1/n_iterations.
enrich_res <- testMotifEnrich(
ex_pfm, test_seq, rm_seq, min_score = score_thresh, model = "quasi", mc.cores = cores
)
head(enrich_res)
## sequences matches expected enrichment Z p
## ZN143 849 43 0.19 226.315789 102.144041 2.355850e-37
## ESR1 849 51 4.41 11.564626 21.469841 3.071728e-29
## FOXA1 849 292 125.64 2.324101 13.345825 9.782504e-23
## ANDR 849 36 11.53 3.122290 7.014137 2.621038e-09
## ZN281 849 46 19.53 2.355351 5.186250 2.777006e-06
## fdr n_iter sd_bg
## ZN143 1.177925e-36 100 0.419114
## ESR1 7.679321e-29 100 2.170021
## FOXA1 1.630417e-22 100 12.465322
## ANDR 3.276298e-09 100 3.488669
## ZN281 2.777006e-06 100 5.103880
Setting the model to “iteration” instead uses a classical iterative approach to define the null distributions of counts and Z-scores are calculated from these values. The returned p-values from this test are taken from the Z-scores directly, with p-values derived from the sampled iterations also returned if preferred for use in results by the researcher. Whilst requiring greater computational effort, fewer statistical assumptions are made and results may be more conservative than under modelling approaches.
iter_res <- testMotifEnrich(
ex_pfm, test_seq, rm_seq, min_score = score_thresh, mc.cores = cores, model = "iteration"
)
head(iter_res)
## sequences matches expected enrichment Z p
## ESR1 849 51 4.41 11.564626 21.469841 0.000000e+00
## FOXA1 849 292 125.64 2.324101 13.345825 0.000000e+00
## ZN143 849 43 0.19 226.315789 102.144041 0.000000e+00
## ANDR 849 36 11.53 3.122290 7.014137 2.313705e-12
## ZN281 849 46 19.53 2.355351 5.186250 2.145708e-07
## fdr iter_p n_iter sd_bg
## ESR1 0.000000e+00 0.01 100 2.170021
## FOXA1 0.000000e+00 0.01 100 12.465322
## ZN143 0.000000e+00 0.01 100 0.419114
## ANDR 2.892131e-12 0.01 100 3.488669
## ZN281 2.145708e-07 0.01 100 5.103880
Once we have selected our motifs of interest, sequences with matches can be compared to easily assess co-occurrence, using plotOverlaps()
from extraChIPs.
In our test set, peaks were selected based on co-detection of ESR1 and ANDR, however the rate of co-occurrence is low, revealing key insights into the binding dynamics of these two TFs.
ex_pfm |>
getPwmMatches(test_seq, min_score = score_thresh, mc.cores = cores) |>
lapply(\(x) x$seq) |>
plotOverlaps(type = "upset")
TFBMs often contain a high level of similarity to other TFBMs, especially those within large but closely related families, such as the GATA or STAT families. It can be difficult to ascertain which member of a family is truly bound to a site from inspecting the sequence data alone.
As a relevant example, when looking at the above UpSet plot, about half of the sequences where a match to the ANDR motif was found also contain a FOXA1 motif. Does this mean that both are bound to the sequence, or have the same sequences simply been matched to both PWMs? As we can see there is quite some similarity in the core regions of the two binding motifs
c("ANDR", "FOXA1") |>
lapply(
\(x) create_motif(ex_pfm[[x]], name = x, type = "PPM")
) |>
view_motifs()
motifTestR
offers a simple but helpful strategy for reducing the level of redundancy within a set of results, by grouping highly similar motifs into a cluster and testing for enrichment, or positional bias for any TFBM within that cluster.
The clustering methodology enabled within motifTestR
allows for the use of any of the comparison methods provided in compare_motifs()
(Tremblay 2024).
Whilst the example set of TFBMs is slightly artificial motifs can still be grouped into clusters. If using a larger database of TFBMs a carefully selected threshold may be more appropriate, however for this dataset, four clusters are able to be formed using the default settings. There is no ideal method to group PWMs into clusters and manual inspection of any clusters produced is the best strategy for this process. Names are not strictly required for downstream analysis, but can help with interpretability
cl <- clusterMotifs(ex_pfm, plot = TRUE, labels = NULL)
ex_cl <- split(ex_pfm, cl)
names(ex_cl) <- vapply(split(names(cl), cl), paste, character(1), collapse = "/")
These clusters can now be tested for positional bias using testClusterPos()
.
Matches are the unique sites with a match to any PWM within the cluster, and any overlapping sites from matches to multiple PWMs are counted as a single match.
When overlapping matches are found, the one with the highest relative score (score / maxScore) is chosen given that raw scores for each PWM will be on different scales.
A list of best matches can be produced in an analogous way to for individual PWMs, using getClusterMatches()
instead of getPwmMatches()
, and the motif assigned to each match is also provided.
cl_matches <- getClusterMatches(
ex_cl, test_seq, min_score = score_thresh, best_only = TRUE
)
cl_matches
## $ESR1
## DataFrame with 50 rows and 9 columns
## seq score direction start end from_centre
## <character> <numeric> <factor> <integer> <integer> <numeric>
## 1 chr1:1008982-1009381 17.3522 R 216 230 23
## 2 chr1:6543164-6543563 15.7958 R 176 190 -17
## 3 chr1:10010470-10010869 18.0880 F 193 207 0
## 4 chr1:11434290-11434689 20.8412 R 321 335 128
## 5 chr1:17855904-17856303 15.7429 F 195 209 2
## ... ... ... ... ... ... ...
## 46 chr1:212731397-21273.. 16.1154 R 88 102 -105
## 47 chr1:214500812-21450.. 17.1325 R 186 200 -7
## 48 chr1:217979498-21797.. 16.6438 F 186 200 -7
## 49 chr1:233243433-23324.. 15.7178 F 201 215 8
## 50 chr1:247267507-24726.. 16.8796 F 313 327 120
## seq_width motif match
## <integer> <character> <DNAStringSet>
## 1 400 ESR1 TGGTCACAGTGACCT
## 2 400 ESR1 GGGTCATCCTGTCCC
## 3 400 ESR1 AGGTCACCCTGGCCC
## 4 400 ESR1 AGGTCACCGTGACCC
## 5 400 ESR1 AGGGCAAAATGACCC
## ... ... ... ...
## 46 400 ESR1 GTGTCACAGTGACCC
## 47 400 ESR1 AGGTCACAATGACAT
## 48 400 ESR1 GGGTCATCCTGCCCC
## 49 400 ESR1 AGGTCATAAAGACCT
## 50 400 ESR1 AGGTCAGAATGACCG
##
## $`ANDR/FOXA1`
## DataFrame with 255 rows and 9 columns
## seq score direction start end from_centre
## <character> <numeric> <factor> <integer> <integer> <numeric>
## 1 chr1:5658040-5658439 13.7470 R 203 214 8.5
## 2 chr1:6969924-6970323 14.0694 F 199 210 4.5
## 3 chr1:8077594-8077993 12.6907 F 28 39 -166.5
## 4 chr1:8121343-8121742 14.4605 F 177 188 -17.5
## 5 chr1:8130962-8131361 15.1441 F 341 352 146.5
## ... ... ... ... ... ... ...
## 251 chr1:241913254-24191.. 12.3147 F 196 207 1.5
## 252 chr1:244065451-24406.. 13.4339 R 288 299 93.5
## 253 chr1:244417385-24441.. 23.0102 R 167 184 -24.5
## 254 chr1:244490601-24449.. 16.6073 F 189 206 -2.5
## 255 chr1:246746473-24674.. 14.3461 F 40 51 -154.5
## seq_width motif match
## <integer> <character> <DNAStringSet>
## 1 400 FOXA1 TGTCATCCCGCC
## 2 400 FOXA1 GGCTGGCGGGAT
## 3 400 FOXA1 CAGGATCCGCTG
## 4 400 FOXA1 ACTTGCCAGTGA
## 5 400 FOXA1 CCCACCCCTCCA
## ... ... ... ...
## 251 400 FOXA1 ACAGGCTGGCGG
## 252 400 FOXA1 CAGAGCACAGTC
## 253 400 ANDR TGGCAAGTCAGGGGTGGG
## 254 400 ANDR GTCCCAGACAGGCTGGCG
## 255 400 FOXA1 CAGGGAGCCACA
##
## $ZN143
## DataFrame with 26 rows and 9 columns
## seq score direction start end from_centre
## <character> <numeric> <factor> <integer> <integer> <numeric>
## 1 chr1:1051296-1051695 24.3993 F 360 381 170.5
## 2 chr1:6673482-6673881 24.5459 R 199 220 9.5
## 3 chr1:10532432-10532831 26.8427 F 166 187 -23.5
## 4 chr1:22109982-22110381 29.0591 F 210 231 20.5
## 5 chr1:36614982-36615381 23.8117 R 243 264 53.5
## ... ... ... ... ... ... ...
## 22 chr1:224544286-22454.. 28.4852 R 151 172 -38.5
## 23 chr1:243418636-24341.. 22.4081 F 206 227 16.5
## 24 chr1:243419063-24341.. 24.5149 F 143 164 -46.5
## 25 chr1:244615397-24461.. 28.9222 R 166 187 -23.5
## 26 chr1:244815816-24481.. 30.0534 F 216 237 26.5
## seq_width motif match
## <integer> <character> <DNAStringSet>
## 1 400 ZN143 AGCGCCCTGGGAAATGTAGTCC
## 2 400 ZN143 TGCCTTGTGGGAGTGGTAGTCC
## 3 400 ZN143 AGCCTGCCGGGAGATGTAGTTC
## 4 400 ZN143 GGCATGCTGGGATTTGTAGTCT
## 5 400 ZN143 AGCACTCCGGGAGTTGTAGTTG
## ... ... ... ...
## 22 400 ZN143 CGCATGCTGGGAATTGTAGTTC
## 23 400 ZN143 GGCATGCTAGGAGTTGTAGTGT
## 24 400 ZN143 TGGTTTCTGGGAATTGTAGTGT
## 25 400 ZN143 TGCATGCTGGGATTTGTAGTCC
## 26 400 ZN143 TGCATGCTGGGAGTTGTAGTCT
##
## $ZN281
## DataFrame with 40 rows and 9 columns
## seq score direction start end from_centre
## <character> <numeric> <factor> <integer> <integer> <numeric>
## 1 chr1:6673482-6673881 18.2091 R 35 49 -158
## 2 chr1:8077594-8077993 16.4907 R 224 238 31
## 3 chr1:10010470-10010869 17.5981 R 319 333 126
## 4 chr1:15240346-15240745 18.1241 F 91 105 -102
## 5 chr1:17846899-17847298 16.5147 F 123 137 -70
## ... ... ... ... ... ... ...
## 36 chr1:226063163-22606.. 22.6040 R 274 288 81
## 37 chr1:226249719-22625.. 18.8379 R 310 324 117
## 38 chr1:235667696-23566.. 17.6496 R 69 83 -124
## 39 chr1:236666415-23666.. 16.6439 F 7 21 -186
## 40 chr1:246158593-24615.. 16.4984 F 366 380 173
## seq_width motif match
## <integer> <character> <DNAStringSet>
## 1 400 ZN281 CGCGGGGGGAGGGGC
## 2 400 ZN281 AGGTGGGGGTTGGGC
## 3 400 ZN281 AACGGGGGGAGGGGA
## 4 400 ZN281 GGATGGAGGAGGGGA
## 5 400 ZN281 TCGTGGGGGAGGGGT
## ... ... ... ...
## 36 400 ZN281 GGGTGGGGGAGGGGG
## 37 400 ZN281 AGTGGGGGGAGGGGA
## 38 400 ZN281 CGGAGGGGGCGGGGC
## 39 400 ZN281 GGGTGGAGGTGGGGG
## 40 400 ZN281 AGTAGGGGGTGGGGG
These matches can then be passed to testClusterPos()
, which works in a near-identical manner to testMotifPos()
testClusterPos(cl_matches, test_seq, abs = TRUE)
## start end centre width total_matches matches_in_region expected
## ANDR/FOXA1 0 30 15 30 253 57 26.354167
## ESR1 10 20 15 10 50 11 2.590674
## ZN143 0 50 25 50 26 20 6.842105
## ZN281 0 190 95 190 40 38 33.160622
## enrichment prop_total p fdr consensus_motif
## ANDR/FOXA1 2.162846 0.2252964 0.0004845717 0.001581452 46, 79, ....
## ESR1 4.246000 0.2200000 0.0007907262 0.001581452 35, 0, 1....
## ZN143 2.923077 0.7692308 0.1963203926 0.261760523 6, 1, 13....
## ZN281 1.145938 0.9500000 0.9173293626 0.917329363 8, 6, 22....
All methods implemented for testing enrichment against a set of background sequences can also be used for clusters of motifs.
testClusterEnrich(
ex_cl, test_seq, rm_seq, min_score = score_thresh, model = "quasi", mc.cores = cores
)
## sequences matches expected enrichment Z p
## ZN143 849 43 0.19 226.315789 102.14404 2.355850e-37
## ESR1 849 51 4.41 11.564626 21.46984 3.071728e-29
## ANDR/FOXA1 849 312 133.08 2.344454 14.11311 2.961045e-24
## ZN281 849 46 19.53 2.355351 5.18625 2.777006e-06
## fdr n_iter sd_bg
## ZN143 9.423401e-37 100 0.419114
## ESR1 6.143457e-29 100 2.170021
## ANDR/FOXA1 3.948060e-24 100 12.677571
## ZN281 2.777006e-06 100 5.103880
Vignettes are commonly prepared for compiling with limited resources and as such example datasets and analyses may reveal less information than realistically sized data. Motif analysis is particularly well-known for taking many minutes when working with large datasets. For more comprehensive analysis and realistically sized data, the following code snippets will allow analysis of the above dataset, but without being restricted to chromosome 1.
To obtain the full set of peaks, simply run the following and use these peaks repeating the steps above.
## Not run
base_url <- "https://ftp.ncbi.nlm.nih.gov/geo/samples/GSM3511nnn"
bed_url <- list(
AR = file.path(
base_url, "GSM3511083/suppl/GSM3511083%5FAR%5Fpeaks%5FED.bed.gz"
),
ER = file.path(
base_url, "GSM3511085/suppl/GSM3511085%5FER%5Fpeaks%5FED.bed.gz"
),
H3K27ac = file.path(
base_url, "GSM3511087/suppl/GSM3511087%5FH3K27ac%5Fpeaks%5FED.bed.gz"
)
)
all_peaks <- GRangesList(lapply(bed_url, import.bed))
seqlevels(all_peaks) <- seqnames(sq)
seqinfo(all_peaks) <- sq
## Return the ranges with coverage from 2 or more targets
ar_er_peaks <- makeConsensus(
all_peaks, p = 2/3, method = "coverage", min_width = 200
) |>
## Now subset to the ranges which overlap a peak from every target
subset(n == 3) |>
resize(width = 400, fix = 'center')
The full set of PWMs for HOCOMOCOv11 (core-A) provided in MotifDb
can be obtained using the following.
Alternatively, query fields can be customised as preferred.
## Not run
library(MotifDb)
ex_pfm <- MotifDb |>
subset(organism == "Hsapiens") |>
query("HOCOMOCOv11-core-A") |>
as.list()
names(ex_pfm) <- gsub(".+HOCOMOCOv11-core-A-(.+)_.+", "\\1", names(ex_pfm))
Similarly, a set of candidate enhancers found on all chromosomes can be obtained here.
If choosing this dataset, note that bg_ranges
will need to be drawn from the entire genome, not just chromosome 1.
## Not run
zr75_url <- "http://www.enhanceratlas.org/data/download/enhancer/hs/ZR75-1.bed"
zr75_enh <- import.bed(zr75_url)
zr75_enh <- granges(zr75_enh)
seqlevels(zr75_enh) <- seqnames(sq)
seqinfo(zr75_enh) <- sq
mean(overlapsAny(ar_er_peaks, zr75_enh))
## R Under development (unstable) (2024-10-21 r87258)
## Platform: x86_64-pc-linux-gnu
## Running under: Ubuntu 24.04.1 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.21-bioc/R/lib/libRblas.so
## LAPACK: /usr/lib/x86_64-linux-gnu/lapack/liblapack.so.3.12.0
##
## 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
##
## time zone: America/New_York
## tzcode source: system (glibc)
##
## attached base packages:
## [1] parallel stats4 stats graphics grDevices utils datasets
## [8] methods base
##
## other attached packages:
## [1] universalmotif_1.25.0 patchwork_1.3.0
## [3] BSgenome.Hsapiens.UCSC.hg19_1.4.3 BSgenome_1.75.0
## [5] BiocIO_1.17.0 rtracklayer_1.67.0
## [7] extraChIPs_1.11.0 tibble_3.2.1
## [9] SummarizedExperiment_1.37.0 Biobase_2.67.0
## [11] MatrixGenerics_1.19.0 matrixStats_1.4.1
## [13] ggside_0.3.1 BiocParallel_1.41.0
## [15] motifTestR_1.3.1 ggplot2_3.5.1
## [17] GenomicRanges_1.59.0 Biostrings_2.75.0
## [19] GenomeInfoDb_1.43.0 XVector_0.47.0
## [21] IRanges_2.41.0 S4Vectors_0.45.0
## [23] BiocGenerics_0.53.1 generics_0.1.3
## [25] BiocStyle_2.35.0
##
## loaded via a namespace (and not attached):
## [1] splines_4.5.0 bitops_1.0-9
## [3] filelock_1.0.3 polyclip_1.10-7
## [5] XML_3.99-0.17 rpart_4.1.23
## [7] lifecycle_1.0.4 httr2_1.0.5
## [9] edgeR_4.5.0 lattice_0.22-6
## [11] ensembldb_2.31.0 MASS_7.3-61
## [13] backports_1.5.0 magrittr_2.0.3
## [15] limma_3.63.0 Hmisc_5.2-0
## [17] sass_0.4.9 rmarkdown_2.28
## [19] jquerylib_0.1.4 yaml_2.3.10
## [21] metapod_1.15.0 Gviz_1.51.0
## [23] DBI_1.2.3 RColorBrewer_1.1-3
## [25] harmonicmeanp_3.0.1 abind_1.4-8
## [27] zlibbioc_1.53.0 purrr_1.0.2
## [29] AnnotationFilter_1.31.0 biovizBase_1.55.0
## [31] RCurl_1.98-1.16 nnet_7.3-19
## [33] VariantAnnotation_1.53.0 tweenr_2.0.3
## [35] rappdirs_0.3.3 GenomeInfoDbData_1.2.13
## [37] ggrepel_0.9.6 codetools_0.2-20
## [39] DelayedArray_0.33.1 xml2_1.3.6
## [41] ggforce_0.4.2 tidyselect_1.2.1
## [43] futile.logger_1.4.3 UCSC.utils_1.3.0
## [45] farver_2.1.2 ComplexUpset_1.3.3
## [47] BiocFileCache_2.15.0 base64enc_0.1-3
## [49] GenomicAlignments_1.43.0 jsonlite_1.8.9
## [51] Formula_1.2-5 tools_4.5.0
## [53] progress_1.2.3 Rcpp_1.0.13
## [55] glue_1.8.0 gridExtra_2.3
## [57] SparseArray_1.7.0 mgcv_1.9-1
## [59] xfun_0.49 dplyr_1.1.4
## [61] withr_3.0.2 formatR_1.14
## [63] BiocManager_1.30.25 fastmap_1.2.0
## [65] latticeExtra_0.6-30 fansi_1.0.6
## [67] digest_0.6.37 R6_2.5.1
## [69] colorspace_2.1-1 jpeg_0.1-10
## [71] dichromat_2.0-0.1 biomaRt_2.63.0
## [73] RSQLite_2.3.7 utf8_1.2.4
## [75] tidyr_1.3.1 data.table_1.16.2
## [77] prettyunits_1.2.0 InteractionSet_1.35.0
## [79] httr_1.4.7 htmlwidgets_1.6.4
## [81] S4Arrays_1.7.1 pkgconfig_2.0.3
## [83] gtable_0.3.6 blob_1.2.4
## [85] htmltools_0.5.8.1 bookdown_0.41
## [87] ProtGenerics_1.39.0 scales_1.3.0
## [89] png_0.1-8 knitr_1.48
## [91] lambda.r_1.2.4 rstudioapi_0.17.1
## [93] rjson_0.2.23 nlme_3.1-166
## [95] checkmate_2.3.2 curl_5.2.3
## [97] cachem_1.1.0 stringr_1.5.1
## [99] foreign_0.8-87 AnnotationDbi_1.69.0
## [101] restfulr_0.0.15 pillar_1.9.0
## [103] grid_4.5.0 vctrs_0.6.5
## [105] dbplyr_2.5.0 cluster_2.1.6
## [107] htmlTable_2.4.3 evaluate_1.0.1
## [109] VennDiagram_1.7.3 GenomicFeatures_1.59.0
## [111] cli_3.6.3 locfit_1.5-9.10
## [113] compiler_4.5.0 futile.options_1.0.1
## [115] Rsamtools_2.23.0 rlang_1.1.4
## [117] crayon_1.5.3 FMStable_0.1-4
## [119] labeling_0.4.3 interp_1.1-6
## [121] forcats_1.0.0 stringi_1.8.4
## [123] viridisLite_0.4.2 deldir_2.0-4
## [125] munsell_0.5.1 lazyeval_0.2.2
## [127] csaw_1.41.0 Matrix_1.7-1
## [129] hms_1.1.3 bit64_4.5.2
## [131] KEGGREST_1.47.0 statmod_1.5.0
## [133] highr_0.11 igraph_2.1.1
## [135] broom_1.0.7 memoise_2.0.1
## [137] bslib_0.8.0 bit_4.5.0
## [139] GenomicInteractions_1.41.0