wiggleplotr is a tool to visualise RNA-seq read overage accross annotated exons. A key feature of wiggleplotr is that it is able rescale all introns of a gene to fixed length, making it easier to see differences in read coverage between neighbouring exons that can otherwise be too far away. Since wiggleplotr takes standard BigWig files as input, it can also be used to visualise read overage from other sequencing-based assays such as ATAC-seq and ChIP-seq.
##Getting started To install wiggleplotr, start R and enter:
To run the code examples shown in this vignette, we need to load the following packages:
library("wiggleplotr")
library("dplyr")
library("GenomicRanges")
library("GenomicFeatures")
library("biomaRt")
##Visualizing transcript annotations First, the plotTranscripts function allows you to visualise the structucte of all transcripts of a gene (or multiple genes). It takes the following three inputs, but only the first one is required:
exons
- list of GRanges objects containing the start and end coordinates of exons for each transcript.cdss
- list of GRanges objects containing the start and end coordinates of coding sequence (cds) for each transcript (optional).annotations
- a data frame with at least the following three columns: transcript_id, gene_name and strand (optional).To get you started, the wiggleplotr package comes with example annotations for the nine protein coding transcripts of the NCOA7 gene pre-loaded. Please see below to learn how to download those annotations from Ensembl on your own or how to extract them automatically from the EnsDb and TxDb objects. This is what the annotations look like:
## # A tibble: 9 x 4
## transcript_id gene_id gene_name strand
## <chr> <chr> <chr> <int>
## 1 ENST00000368357 ENSG00000111912 NCOA7 1
## 2 ENST00000453302 ENSG00000111912 NCOA7 1
## 3 ENST00000417494 ENSG00000111912 NCOA7 1
## 4 ENST00000229634 ENSG00000111912 NCOA7 1
## 5 ENST00000428318 ENSG00000111912 NCOA7 1
## 6 ENST00000419660 ENSG00000111912 NCOA7 1
## 7 ENST00000438495 ENSG00000111912 NCOA7 1
## 8 ENST00000444128 ENSG00000111912 NCOA7 1
## 9 ENST00000392477 ENSG00000111912 NCOA7 1
## [1] "ENST00000368357" "ENST00000453302" "ENST00000417494" "ENST00000229634"
## [5] "ENST00000428318" "ENST00000419660" "ENST00000438495" "ENST00000444128"
## [9] "ENST00000392477"
## [1] "ENST00000368357" "ENST00000453302" "ENST00000417494" "ENST00000229634"
## [5] "ENST00000428318" "ENST00000419660" "ENST00000438495" "ENST00000444128"
## [9] "ENST00000392477"
Now, to plot these nine transcripts, we simply use the plotTranscripts function:
You might have noticed that since NCOA7 gene has relatively long introns, it can be quite hard to see where all of the exons are. To focus on the exons, we can rescale all introns to a fixed length (50 bp by default):
It is now much easier to see, which of the exons can be alternatively spliced and which are shared by all transcripts.
If you are constructing your own transcript annotations, you only need to specify the exons
GRanges list for the code to work. In this case, the names of the list will be used as transcript labels on the plot.
##Visualising RNA-seq read coverage We used the NCOA7 example above, because we discovered recently that this gene undergoes alternative promoter usage in human macrophages in response to lipopolysaccharide (LPS) stimulation 1. We’ll now show how the plotCoverage function can be used to visualise RNA-seq read coverage accross the exons of a gene. In addition the the exons
, cdss
and transcript_annotations
paramteres required by plotTranscripts, plotCoverage also requires a track_data
data frame containing RNA-seq sample metadata as well as path to the read coverage data in BigWig format.
First, you need to create a data frame containing sample metadata. In our case we have four samples, two from the naive condition and two after LPS stimulation:
sample_data = dplyr::data_frame(
sample_id = c("aipt_A", "aipt_C", "bima_A", "bima_C"),
condition = factor(c("Naive", "LPS", "Naive", "LPS"), levels = c("Naive", "LPS")),
scaling_factor = 1)
sample_data = sample_data %>%
dplyr::mutate(bigWig = system.file("extdata", paste0(sample_id, ".str2.bw"),
package = "wiggleplotr"))
as.data.frame(sample_data)
## sample_id condition scaling_factor
## 1 aipt_A Naive 1
## 2 aipt_C LPS 1
## 3 bima_A Naive 1
## 4 bima_C LPS 1
## bigWig
## 1 /tmp/RtmprntIyd/Rinst61c914aecf6e/wiggleplotr/extdata/aipt_A.str2.bw
## 2 /tmp/RtmprntIyd/Rinst61c914aecf6e/wiggleplotr/extdata/aipt_C.str2.bw
## 3 /tmp/RtmprntIyd/Rinst61c914aecf6e/wiggleplotr/extdata/bima_A.str2.bw
## 4 /tmp/RtmprntIyd/Rinst61c914aecf6e/wiggleplotr/extdata/bima_C.str2.bw
Finally, we need to add the track_id
and colour_group
columns that define which sample belongs to which track and what their colour should be. For simplicity, we first set both of these values equal to the the experimental condition:
Now, we can make our first read coverage plot
selected_transcripts = c("ENST00000438495", "ENST00000392477") #Plot only two transcripts of the gens
plotCoverage(ncoa7_exons[selected_transcripts], ncoa7_cdss[selected_transcripts],
ncoa7_metadata, track_data,
heights = c(2,1), fill_palette = getGenotypePalette())
By default, plotCoverage plots the mean read coverage across all of the samples in the same colour group. However, it is also possible to overlay all of the individual samples by setting mean_only = FALSE
and alpha < 1
.
plotCoverage(ncoa7_exons[selected_transcripts], ncoa7_cdss[selected_transcripts],
ncoa7_metadata, track_data,
heights = c(2,1), fill_palette = getGenotypePalette(), mean_only = FALSE, alpha = 0.5)
It is clear from both plots that the short transcript skipping the first 11 exons of the gene is only expressed after LPS stimulation.
Finally, we can overlay the two conditions in different colours by assigning all of the samples to a single track. This approach can we very useful for visualising eQTLs and splice QTLs. Setting coverage_type = "line"
allows us to see both signals even if one overlaps the other:
track_data = dplyr::mutate(sample_data, track_id = "RNA-seq", colour_group = condition)
plotCoverage(ncoa7_exons[selected_transcripts], ncoa7_cdss[selected_transcripts],
ncoa7_metadata, track_data,
heights = c(2,1), fill_palette = getGenotypePalette(), coverage_type = "line")
## Warning: Removed 2 rows containing missing values (geom_path).
Unfortunately, it is currently not possible to automatically add legends to the read coverage plots. This is because plotTranscripts uses the cowplot::plot_grid function to align the read coverage and transcript annotations plots and plot_grid does not support legends.
Although wiggleplotr was initially written with RNA-seq data in mind, it can be used equally well to visualise any other sequencing data that can be summarised as read coverage in BigWig format (ATAC-seq, DNAse-seq, ChIP-seq). All you need to do is specify your own exons
, cdss
, transcript_annotations
and track_data
parameters. Furthermore, setting connect_exons = FALSE
and transcript_label = FALSE
makes it easier to plot other types of genomic annotations.
track_data = dplyr::mutate(sample_data, track_id = "RNA-seq", colour_group = condition)
plotCoverage(ncoa7_exons[selected_transcripts], ncoa7_cdss[selected_transcripts],
ncoa7_metadata, track_data,
heights = c(2,1), fill_palette = getGenotypePalette(), coverage_type = "line",
connect_exons = FALSE, transcript_label = FALSE, rescale_introns = FALSE)
In addition specifying your own transcript annotations, wiggleplotr also provides four additional wrapper functions that can extract transcript annotations directly from ensembldb and TxDb (UCSC) objects. For ensembldb, you can use the plotTranscriptsFromEnsembldb and plotCoverageFromEnsembldb functions:
library("ensembldb")
library("EnsDb.Hsapiens.v86")
plotTranscriptsFromEnsembldb(EnsDb.Hsapiens.v86, gene_names = "NCOA7",
transcript_ids = c("ENST00000438495", "ENST00000392477"))
For UCSC transcript annotations in TxDb objects, you can use the corresponding plotTranscriptsFromUCSC and plotCoverageFromUCSC functions:
#Load OrgDb and TxDb objects with UCSC gene annotations
require("org.Hs.eg.db")
require("TxDb.Hsapiens.UCSC.hg38.knownGene")
plotTranscriptsFromUCSC(orgdb = org.Hs.eg.db, txdb = TxDb.Hsapiens.UCSC.hg38.knownGene,
gene_names = "NCOA7", transcript_ids = c("uc003qae.5", "uc063rdt.2"))
## 'select()' returned 1:many mapping between keys and columns
The easiest way to access reference transcript annotations in R is to download them directly from Ensembl using the biomaRt R package.
First, we want to download transcript metadata, such as which transcripts belong to which genes and what are their names. We can use the biomaRt package to do that. First, let’s define which mart and dataset we want to use.
ensembl_mart = useMart("ENSEMBL_MART_ENSEMBL", host = "dec2014.archive.ensembl.org")
ensembl_dataset = useDataset("hsapiens_gene_ensembl",mart=ensembl_mart)
ensembl_dataset
## Object of class 'Mart':
## Using the ENSEMBL_MART_ENSEMBL BioMart database
## Using the hsapiens_gene_ensembl dataset
The host
helps to make sure that we get the annotations from a specific Ensembl version. For example, Ensembl 78 correseponds to host="dec2014.archive.ensembl.org"
. You can use the Ensembl Archives website to check which host name corresponds to desired Ensembl version. More information using specific ensembl versions with biomaRt can be found in the biomaRt vignette.
We can see all available attributes with the listAttributes
command.
## name description page
## 1 ensembl_gene_id Ensembl Gene ID feature_page
## 2 ensembl_transcript_id Ensembl Transcript ID feature_page
## 3 ensembl_peptide_id Ensembl Protein ID feature_page
## 4 ensembl_exon_id Ensembl Exon ID feature_page
## 5 description Description feature_page
## 6 chromosome_name Chromosome Name feature_page
Now, let’s select gene id, gene name, transcript id and strand from the biomart and download the corresponding columns.
selected_attributes = c("ensembl_transcript_id", "ensembl_gene_id",
"external_gene_name", "strand",
"gene_biotype", "transcript_biotype")
data = getBM(attributes = selected_attributes, mart = ensembl_dataset)
head(data)
## ensembl_transcript_id ensembl_gene_id external_gene_name strand
## 1 ENST00000508957 ENSG00000197468 RP11-747H12.1 1
## 2 ENST00000435337 ENSG00000231049 OR52B5P 1
## 3 ENST00000618935 ENSG00000276385 RP5-859I17.3 -1
## 4 ENST00000614589 ENSG00000275151 RP11-42L13.2 1
## 5 ENST00000432676 ENSG00000228913 UBD -1
## 6 ENST00000449391 ENSG00000231948 HS1BP3-IT1 -1
## gene_biotype transcript_biotype
## 1 unprocessed_pseudogene unprocessed_pseudogene
## 2 unprocessed_pseudogene unprocessed_pseudogene
## 3 processed_pseudogene processed_pseudogene
## 4 processed_pseudogene processed_pseudogene
## 5 protein_coding protein_coding
## 6 sense_intronic sense_intronic
Finally, we need to rename the columns
data = dplyr::rename(data,
transcript_id = ensembl_transcript_id,
gene_id = ensembl_gene_id,
gene_name = external_gene_name)
head(data)
## transcript_id gene_id gene_name strand
## 1 ENST00000508957 ENSG00000197468 RP11-747H12.1 1
## 2 ENST00000435337 ENSG00000231049 OR52B5P 1
## 3 ENST00000618935 ENSG00000276385 RP5-859I17.3 -1
## 4 ENST00000614589 ENSG00000275151 RP11-42L13.2 1
## 5 ENST00000432676 ENSG00000228913 UBD -1
## 6 ENST00000449391 ENSG00000231948 HS1BP3-IT1 -1
## gene_biotype transcript_biotype
## 1 unprocessed_pseudogene unprocessed_pseudogene
## 2 unprocessed_pseudogene unprocessed_pseudogene
## 3 processed_pseudogene processed_pseudogene
## 4 processed_pseudogene processed_pseudogene
## 5 protein_coding protein_coding
## 6 sense_intronic sense_intronic
We can now save the metadata into a file to avoid downloading it every time we need to use it.
temporary_file = tempfile(pattern = "file", tmpdir = tempdir(), fileext = ".rds")
saveRDS(data, temporary_file)
Next time we need to access the metadata, we can load it directly from disk.
## transcript_id gene_id gene_name strand
## 1 ENST00000508957 ENSG00000197468 RP11-747H12.1 1
## 2 ENST00000435337 ENSG00000231049 OR52B5P 1
## 3 ENST00000618935 ENSG00000276385 RP5-859I17.3 -1
## 4 ENST00000614589 ENSG00000275151 RP11-42L13.2 1
## 5 ENST00000432676 ENSG00000228913 UBD -1
## 6 ENST00000449391 ENSG00000231948 HS1BP3-IT1 -1
## gene_biotype transcript_biotype
## 1 unprocessed_pseudogene unprocessed_pseudogene
## 2 unprocessed_pseudogene unprocessed_pseudogene
## 3 processed_pseudogene processed_pseudogene
## 4 processed_pseudogene processed_pseudogene
## 5 protein_coding protein_coding
## 6 sense_intronic sense_intronic
However, just the transcript metadata is not enought to use wiggleplotr, we also need the coordinates for all exons. We can get those using the GenomicFeatures packages. First, we use the makeTxDbFromBiomart function to download the full transcript database corresponding to a sepcifc Ensembl version, in this case Ensembl 78. Please note that as the database is quite large, this can take at least a couple of minutes to run.
txdb = makeTxDbFromBiomart(biomart = "ENSEMBL_MART_ENSEMBL",
dataset = "hsapiens_gene_ensembl",
host="dec2014.archive.ensembl.org")
We can save the database to disk to avoid downloading it again every time we want to use it.
txdb_file = tempfile(pattern = "file", tmpdir = tempdir(), fileext = ".rds")
saveDb(txdb, txdb_file)
And we can load it from disk using the loadDb function.
We can extract exon and coding sequence (CDS) coordinates for all annotated transcripts from the database. The following commands will produce a a list of GRanges objects, each element containing the exons or coding sequences of a single transcript.
Finally, we use the newly downloaded annotations to visualise the structure of all protein coding transcripts of NCOA7.
Alasoo, Kaur, et al. “Transcriptional profiling of macrophages derived from monocytes and iPS cells identifies a conserved response to LPS and novel alternative transcription.” Scientific reports 5 (2015): 12524.↩