RNAsum
is an R package that can post-process, summarise and visualise
outputs primarily from DRAGEN
RNA
pipelines. Its main application is to complement whole-genome based
findings and to provide additional evidence for detected alterations.
DOCS: https://umccr.github.io/RNAsum
- R package can be installed directly from the GitHub source:
remotes::install_github("umccr/RNAsum") # latest main commit
remotes::install_github("umccr/[email protected]") # version 0.0.X
remotes::install_github("umccr/RNAsum@abcde") # commit abcde
remotes::install_github("umccr/RNAsum#123") # PR 123
- Conda package is available from the Anaconda umccr channel:
conda install r-rnasum==0.0.X -c umccr -c conda-forge -c bioconda
- Docker image is available from the GitHub Container Registy:
docker pull ghcr.io/umccr/rnasum:latest
The pipeline consists of five main components illustrated and briefly described below. For more details, see workflow.md.
- Collect patient WTS data from the DRAGEN RNA pipeline including per-gene read counts and gene fusions.
- Add expression data from reference cohorts to get an idea about the expression levels of genes of interest in other cancer patient cohorts. The read counts are normalised, transformed and converted into a scale that allows to present the patient’s expression measurements in the context of the reference cohorts.
- Supply genome-based findings from whole-genome sequencing (WGS)
data to focus on genes of interest and to provide additional
evidence for dysregulation of mutated genes, or genes located within
detected structural variants (SVs) or copy-number (CN) altered
regions.
RNAsum
is designed to be compatible with WGS patient outputs generated fromumccrise
. - Collate results with knowledge derived from in-house resources and public databases to provide additional sources of evidence for clinical significance of altered genes e.g. to flag variants with clinical significance or potential druggable targets.
- The final product is an interactive HTML report with searchable tables and plots presenting expression levels of the genes of interest. The report consists of several sections described here.
The reference expression data are available for 33 cancer types and were derived from external (TCGA) and internal (UMCCR) resources.
In order to explore expression changes in the patient, we have built a high-quality pancreatic cancer reference cohort.
Depending on the tissue from which the patient’s sample was taken, one
of 33 cancer datasets from TCGA can be used as a reference cohort
for comparing expression changes in genes of interest of the patient.
Additionally, 10 samples from each of the 33 TCGA datasets were combined
to create the Pan-Cancer
dataset,
and for some cohorts extended
sets are
also available. All available datasets are listed in the TCGA
projects summary table.
These datasets have been processed using methods described in the
TCGA-data-harmonization
repository. The dataset of interest can be specified by using one of the
TCGA project IDs for the RNAsum
--dataset
argument (see
Examples).
The publicly available TCGA datasets are expected to demonstrate prominent batch effects when compared to the in-house WTS data due to differences in applied experimental procedures and analytical pipelines. Moreover, TCGA data may include samples from tissue material of lower quality and cellularity compared to samples processed using local protocols. To address these issues, we have built a high-quality internal reference cohort processed using the same pipelines as input data (see data pre-processing).
This internal reference set of 40 pancreatic cancer samples is based on WTS data generated at UMCCR and processed with the bcbio-nextgen RNA-seq pipeline to minimise potential batch effects between investigated samples and the reference cohort and to make sure the data are comparable. The internal reference cohort assembly is summarised in the Pancreatic-data-harmonization repository.
Note
There are two rationales for using the internal reference cohort:
- In case of pancreatic cancer samples this cohort is used:
- in batch effects correction
- as a reference point for comparing per-gene expression levels observed in the data of the patient of interest and data from other pancreatic cancer patients.
- In case of samples from any cancer type the data from the internal reference cohort is used in the batch effects correction procedure performed to minimise technical-related variation in the data.
RNAsum
accepts WTS data processed by the state-of-the-art
bioinformatic tools such as kallisto and salmon for quantification and
Arriba for fusion calling. RNAsum can aso process and combine fusion
output from Illumina’s Dragen pipeline. Additionally, the WTS data can
be integrated with WGS-based data processed using the tools
discussed in the section WGS.
In the latter case, the genome-based findings from the corresponding sample are incorporated into the report and are used as a primary source for expression profile prioritisation.
The only required WTS input data are read counts provided in a quantification file.
The table below lists all input data accepted in RNAsum
:
Input file | Tool | Example | Required |
---|---|---|---|
Quantified transcript abundances | salmon (description) | *.quant.sf | Yes |
Quantified gene abundances | salmon (description) | *.quant.gene.sf | Yes |
Fusion gene list | Arriba | fusions.tsv | No |
Fusion gene list | DRAGEN RNA | *.fusion_candidates.final | No |
RNAsum
is designed to be compatible with WGS outputs.
The table below lists all input data accepted in RNAsum
:
Input file | Tool | Example | Required |
---|---|---|---|
SNVs/Indels | PCGR | pcgr.snvs_indels.tiers.tsv | No |
CNVs | PURPLE | purple.cnv.gene.tsv | No |
SVs | Manta | sv-prioritize-manta.tsv | No |
rnasum_cli=$(Rscript -e 'x = system.file("cli", package = "RNAsum"); cat(x, "\n")' | xargs)
export PATH="${rnasum_cli}:${PATH}"
$ rnasum.R --version
1.1.0
$ rnasum.R --help
Usage
=====
/Library/Frameworks/R.framework/Versions/4.2/Resources/library/RNAsum/cli/rnasum.R [options]
Options
=======
--arriba_dir=ARRIBA_DIR
Directory path to Arriba results containing fusions.pdf and fusions.tsv.
--arriba_pdf=ARRIBA_PDF
File path of Arriba PDF output.
--arriba_tsv=ARRIBA_TSV
File path of Arriba TSV output.
--batch_rm
Remove batch-associated effects between datasets.
--cn_gain=CN_GAIN
CN threshold value to classify genes within gained regions. [def: 95]
--cn_loss=CN_LOSS
CN threshold value to classify genes within lost regions. [def: 5]
--dataset=DATASET
Dataset to be used as external reference cohort. [def: PANCAN]
--dataset_name_incl
Include dataset in report name.
--dragen_fusions=DRAGEN_FUSIONS
File path to DRAGEN RNA-seq 'fusion_candidates.final' output.
--dragen_mapping_metrics=DRAGEN_MAPPING_METRICS
File path to DRAGEN RNA-seq 'mapping_metrics.csv' output.
--dragen_wts_dir=DRAGEN_WTS_DIR
Directory path to DRAGEN RNA-seq results.
--drugs
Include drug matching section in report.
--filter
Filter out low expressed genes.
--immunogram
Include immunogram in report.
--log
Log2 transform data before normalisation.
--manta_tsv=MANTA_TSV
File path to umccrise 'manta.tsv' output.
--norm=NORM
Normalisation method.
--pcgr_splice_vars
Include non-coding splice region variants reported in PCGR.
--pcgr_tier=PCGR_TIER
Tier threshold for reporting variants reported in PCGR. [def: 4]
--pcgr_tiers_tsv=PCGR_TIERS_TSV
File path to PCGR 'snvs_indels.tiers.tsv' output.
--project=PROJECT
Project name, used for annotation purposes only.
--purple_gene_tsv=PURPLE_GENE_TSV
File path to PURPLE 'purple.cnv.gene.tsv' output.
--report_dir=REPORT_DIR
Directory path to output report.
--salmon=SALMON
File path to salmon 'quant.genes.sf' output.
--sample_name=SAMPLE_NAME
Sample name to be presented in report.
--sample_source=SAMPLE_SOURCE
Type of investigated sample. [def: -]
--save_tables
Save interactive summary tables as HTML.
--scaling=SCALING
Scaling for z-score transformation (gene-wise or group-wise). [def: gene-wise]
--subject_id=SUBJECT_ID
Subject ID.
--top_genes=TOP_GENES
Number of top ranked genes to be presented in report.
--transform=TRANSFORM
Transformation method to be used when converting read counts. [def: CPM]
--umccrise=UMCCRISE
Directory path of the corresponding WGS-related umccrise data.
--version, -v
Print RNAsum version and exit.
--help, -h
Show this help message and exit
Note
Human reference genome GRCh38 (Ensembl based annotation version 105) is used for gene annotation by default. GRCh37 is no longer supported.
Below are RNAsum
CLI commands for generating HTML reports under
different data availability scenarios:
Note
- Example data is provided in the
/inst/rawdata/test_data
folder of the GitHub repo. - The
RNAsum
runtime should be less than 15 minutes using 16GB RAM memory and 1 CPU.
This is the most frequent and preferred case, in which the
WGS-based findings will be used as a primary source for
expression profile prioritisation. The genome-based results can be
incorporated into the report by specifying the location of the
corresponding output files (including results from PCGR
, PURPLE
, and
Manta
). The Mutated genes
, Structural variants
and
CN altered genes
report sections will contain information about
expression levels of the mutated genes, genes located within detected
SVs and CN altered regions, respectively. The results in the
Fusion genes
section will be ordered based on the evidence from
genome-based data. A subset of the TCGA pancreatic adenocarcinoma
dataset is used as reference cohort (--dataset TEST
).
rnasum.R \
--sample_name test_sample_WTS \
--dataset TEST \
--dragen_wts_dir inst/rawdata/test_data/dragen \
--report_dir inst/rawdata/test_data/dragen/RNAsum \
--umccrise inst/rawdata/test_data/umccrised/test_sample_WGS \
--save_tables FALSE
The HTML report test_sample_WTS.RNAsum.html
will be created in the
inst/rawdata/test_data/dragen/RNAsum
folder.
In this scenario, only WTS data will be used and only expression
levels of key
Cancer genes
,
Fusion genes
, Immune markers
and homologous recombination
deficiency genes (HRD genes
) will be reported. Moreover, gene
fusions reported in the Fusion genes
report section will not contain
information about evidence from genome-based data. A subset of the TCGA
pancreatic adenocarcinoma dataset is used as the reference cohort
(--dataset TEST
).
rnasum.R \
--sample_name test_sample_WTS \
--dataset TEST \
--dragen_wts_dir inst/rawdata/test_data/dragen \
--report_dir inst/rawdata/test_data/dragen/RNAsum \
--save_tables FALSE
The output HTML report test_sample_WTS.RNAsum.html
will be created in
the inst/rawdata/test_data/dragen/RNAsum
folder.
For samples derived from subjects, for which clinical information is
available, a treatment regimen timeline can be added to the HTML report.
This can be added by specifying the location of a relevant excel
spreadsheet (see example test_clinical_data.xlsx
under
inst/rawdata/test_data/test_clinical_data.xlsx
) using the
--clinical_info
argument. In this spreadsheet, at least one of the
following columns is expected: NEOADJUVANT REGIMEN
,
ADJUVANT REGIMEN
, FIRST LINE REGIMEN
, SECOND LINE REGIMEN
or
THIRD LINE REGIMEN
, along with START
and STOP
dates of
corresponding treatments. A subset of the TCGA pancreatic adenocarcinoma
dataset is used as the reference cohort (--dataset TEST
).
rnasum.R \
--sample_name test_sample_WTS \
--dataset TEST \
--dragen_wts_dir $(pwd)/../rawdata/test_data/dragen \
--report_dir $(pwd)/../rawdata/test_data/dragen/RNAsum \
--umccrise $(pwd)/../rawdata/test_data/umccrised/test_sample_WGS \
--save_tables FALSE \
--clinical_info $(pwd)/../rawdata/test_data/test_clinical_data.xlsx \
--save_tables FALSE
The HTML report test_sample_WTS.RNAsum.html
will be created in the
../rawdata/test_data/stratus/test_sample_WTS_dragen_v3.9.3/RNAsum
folder.
The pipeline generates a HTML Patient Transcriptome Summary report and a results folder:
|
|____<output>
|____<SampleName>.<output>.html
|____results
|____exprTables
|____glanceExprPlots
|____...
The generated HTML report includes searchable tables and interactive plots presenting expression levels of altered genes, as well as links to public resources describing the genes of interest. The report consists of several sections, including:
- Input data
- Clinical information*
- Findings summary
- Mutated genes**
- Fusion genes
- Structural variants**
- CN altered genes**
- Immune markers
- HRD genes
- Cancer genes
- Drug matching
* if clinical information is available; see --clinical_info
argument
** if genome-based results are available; see --umccrise
argument
Detailed description of the report structure, including result prioritisation and visualisation is available here.
The results
folder contains intermediate files, including plots and
tables that are presented in the HTML report.
The code of conduct can be accessed here.
To cite package ‘RNAsum’ in publications use:
Kanwal S, Marzec J, Diakumis P, Hofmann O, Grimmond S (2024). “RNAsum: An R package to comprehensively post-process, summarise and visualise genomics and transcriptomics data.” version 1.1.0, https://umccr.github.io/RNAsum/.
A BibTeX entry for LaTeX users is
@Unpublished{,
title = {RNAsum: An R package to comprehensively post-process, summarise and visualise genomics and transcriptomics data},
author = {Sehrish Kanwal and Jacek Marzec and Peter Diakumis and Oliver Hofmann and Sean Grimmond},
year = {2024},
note = {version 1.1.0},
url = {https://umccr.github.io/RNAsum/},
}