From the Genomic Data Commons (GDC) website:
The National Cancer Institute's (NCI's) Genomic Data Commons (GDC) is a data sharing platform that promotes precision medicine in oncology. It is not just a database or a tool; it is an expandable knowledge network supporting the import and standardization of genomic and clinical data from cancer research programs.
The GDC contains NCI-generated data from some of the largest and most comprehensive cancer genomic datasets, including The Cancer Genome Atlas (TCGA) and Therapeutically Applicable Research to Generate Effective Therapies (TARGET). For the first time, these datasets have been harmonized using a common set of bioinformatics pipelines, so that the data can be directly compared.
As a growing knowledge system for cancer, the GDC also enables researchers to submit data, and harmonizes these data for import into the GDC. As more researchers add clinical and genomic data to the GDC, it will become an even more powerful tool for making discoveries about the molecular basis of cancer that may lead to better care for patients.
The data model for the GDC is complex, but it worth a quick overview. The data model is encoded as a so-called property graph. Nodes represent entities such as Projects, Cases, Diagnoses, Files (various kinds), and Annotations. The relationships between these entities are maintained as edges. Both nodes and edges may have Properties that supply instance details. The GDC API exposes these nodes and edges in a somewhat simplified set of RESTful endpoints.
This software is available at Bioconductor.org and can be downloaded via
To report bugs or problems, either
submit a new issue
or submit a
bug.report(package='GenomicDataCommons') from within R (which
will redirect you to the new issue on GitHub).
Installation can be achieved via Bioconductor's
if (!require("BiocManager")) install.packages("BiocManager") BiocManager::install('GenomicDataCommons')
The following code builds a
manifest that can be used to guide the
download of raw data. Here, filtering finds gene expression files
quantified as raw counts using
HTSeq from ovarian cancer patients.
library(magrittr) ge_manifest = files() %>% filter( cases.project.project_id == 'TCGA-OV') %>% filter( type == 'gene_expression' ) %>% filter( analysis.workflow_type == 'HTSeq - Counts') %>% manifest()
This code block downloads the
r nrow(ge_manifest) gene expression files specified in the query above. Using multiple processes to do the download very significantly speeds up the transfer in many cases. The following completes in about 15 seconds.
library(BiocParallel) register(MulticoreParam()) destdir = tempdir() fnames = lapply(ge_manifest$id,gdcdata)
If the download had included controlled-access data, the download above would have needed to include a
token. Details are available in the authentication section below.
expands = c("diagnoses","annotations", "demographic","exposures") clinResults = cases() %>% GenomicDataCommons::select(NULL) %>% GenomicDataCommons::expand(expands) %>% results(size=50) clinDF = as.data.frame(clinResults) library(DT) datatable(clinDF, extensions = 'Scroller', options = list( deferRender = TRUE, scrollY = 200, scrollX = TRUE, scroller = TRUE ))
This package design is meant to have some similarities to the "hadleyverse" approach of dplyr. Roughly, the functionality for finding and accessing files and metadata can be divided into:
In addition, there are exhiliary functions for asking the GDC API for information about available and default fields, slicing BAM files, and downloading actual data files. Here is an overview of functionality[^1].
[^1]: See individual function and methods documentation for specific details.
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