In reactome/ReactomeGSA: Client for the Reactome Analysis Service for comparative multi-omics gene set analysis
knitr::opts_chunk$set(
collapse = TRUE,
comment = "#>"
)
Introduction
The ReactomeGSA package is a client to the web-based Reactome Analysis System. Essentially, it performs a gene set analysis using the latest version of the Reactome pathway database as a backend.
This vignette shows how the ReactomeGSA package can be used to perform a pathway analysis of cell clusters in single-cell RNA-sequencing data.
Citation
To cite this package, use
Griss J. ReactomeGSA, https://github.com/reactome/ReactomeGSA (2019)
Installation
The ReactomeGSA package can be directly installed from Bioconductor:
if (!requireNamespace("BiocManager", quietly = TRUE))
install.packages("BiocManager")
if (!require(ReactomeGSA))
BiocManager::install("ReactomeGSA")
# install the ReactomeGSA.data package for the example data
if (!require(ReactomeGSA.data))
BiocManager::install("ReactomeGSA.data")
For more information, see https://bioconductor.org/install/.
Example data
As an example we load single-cell RNA-sequencing data of B cells extracted from the dataset published by Jerby-Arnon et al. (Cell, 2018).
Note: This is not a complete Seurat object. To decrease the size, the object only contains gene expression values and cluster annotations.
library(ReactomeGSA.data)
data(jerby_b_cells)
jerby_b_cells
Pathway analysis of cell clusters
The pathway analysis is at the very end of a scRNA-seq workflow. This means, that any Q/C was already performed, the data was normalized and cells were already clustered.
The ReactomeGSA package can now be used to get pathway-level expression values for every cell cluster. This is achieved by calculating the mean gene expression for every cluster and then submitting this data to a gene set variation analysis.
All of this is wrapped in the single analyse_sc_clusters function.
library(ReactomeGSA)
gsva_result <- analyse_sc_clusters(jerby_b_cells, verbose = TRUE)
The resulting object is a standard ReactomeAnalysisResult object.
gsva_result
pathways returns the pathway-level expression values per cell cluster:
pathway_expression <- pathways(gsva_result)
# simplify the column names by removing the default dataset identifier
colnames(pathway_expression) <- gsub("\\.Seurat", "", colnames(pathway_expression))
pathway_expression[1:3,]
A simple approach to find the most relevant pathways is to assess the maximum difference in expression for every pathway:
# find the maximum differently expressed pathway
max_difference <- do.call(rbind, apply(pathway_expression, 1, function(row) {
values <- as.numeric(row[2:length(row)])
return(data.frame(name = row[1], min = min(values), max = max(values)))
}))
max_difference$diff <- max_difference$max - max_difference$min
# sort based on the difference
max_difference <- max_difference[order(max_difference$diff, decreasing = T), ]
head(max_difference)
Plotting the results
The ReactomeGSA package contains two functions to visualize these pathway results. The first simply plots the expression for a selected pathway:
plot_gsva_pathway(gsva_result, pathway_id = rownames(max_difference)[1])
For a better overview, the expression of multiple pathways can be shown as a heatmap using gplots heatmap.2 function:
# Additional parameters are directly passed to gplots heatmap.2 function
plot_gsva_heatmap(gsva_result, max_pathways = 15, margins = c(6,20))
The plot_gsva_heatmap function can also be used to only display specific pahtways:
# limit to selected B cell related pathways
relevant_pathways <- c("R-HSA-983170", "R-HSA-388841", "R-HSA-2132295", "R-HSA-983705", "R-HSA-5690714")
plot_gsva_heatmap(gsva_result,
pathway_ids = relevant_pathways, # limit to these pathways
margins = c(6,30), # adapt the figure margins in heatmap.2
dendrogram = "col", # only plot column dendrogram
scale = "row", # scale for each pathway
key = FALSE, # don't display the color key
lwid=c(0.1,4)) # remove the white space on the left
This analysis shows us that cluster 8 has a marked up-regulation of B Cell receptor signalling, which is linked to a co-stimulation of the CD28 family. Additionally, there is a gradient among the cluster with respect to genes releated to antigen presentation.
Therefore, we are able to further classify the observed B cell subtypes based on their pathway activity.
Pathway-level PCA
The pathway-level expression analysis can also be used to run a Principal Component Analysis on the samples. This is simplified through the function plot_gsva_pca:
plot_gsva_pca(gsva_result)
In this analysis, cluster 11 is a clear outlier from the other B cell subtypes and therefore might be prioritised for further evaluation.
Session Info
sessionInfo()
reactome/ReactomeGSA documentation built on Nov. 13, 2023, 11:13 p.m.
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knitr::opts_chunk$set( collapse = TRUE, comment = "#>" )
Introduction
The ReactomeGSA package is a client to the web-based Reactome Analysis System. Essentially, it performs a gene set analysis using the latest version of the Reactome pathway database as a backend.
This vignette shows how the ReactomeGSA package can be used to perform a pathway analysis of cell clusters in single-cell RNA-sequencing data.
Citation
To cite this package, use
Griss J. ReactomeGSA, https://github.com/reactome/ReactomeGSA (2019)
Installation
The ReactomeGSA package can be directly installed from Bioconductor:
if (!requireNamespace("BiocManager", quietly = TRUE)) install.packages("BiocManager") if (!require(ReactomeGSA)) BiocManager::install("ReactomeGSA") # install the ReactomeGSA.data package for the example data if (!require(ReactomeGSA.data)) BiocManager::install("ReactomeGSA.data")
For more information, see https://bioconductor.org/install/.
Example data
As an example we load single-cell RNA-sequencing data of B cells extracted from the dataset published by Jerby-Arnon et al. (Cell, 2018).
Note: This is not a complete Seurat object. To decrease the size, the object only contains gene expression values and cluster annotations.
library(ReactomeGSA.data) data(jerby_b_cells) jerby_b_cells
Pathway analysis of cell clusters
The pathway analysis is at the very end of a scRNA-seq workflow. This means, that any Q/C was already performed, the data was normalized and cells were already clustered.
The ReactomeGSA package can now be used to get pathway-level expression values for every cell cluster. This is achieved by calculating the mean gene expression for every cluster and then submitting this data to a gene set variation analysis.
All of this is wrapped in the single analyse_sc_clusters function.
library(ReactomeGSA) gsva_result <- analyse_sc_clusters(jerby_b_cells, verbose = TRUE)
The resulting object is a standard ReactomeAnalysisResult object.
gsva_result
pathways returns the pathway-level expression values per cell cluster:
pathway_expression <- pathways(gsva_result) # simplify the column names by removing the default dataset identifier colnames(pathway_expression) <- gsub("\\.Seurat", "", colnames(pathway_expression)) pathway_expression[1:3,]
A simple approach to find the most relevant pathways is to assess the maximum difference in expression for every pathway:
# find the maximum differently expressed pathway max_difference <- do.call(rbind, apply(pathway_expression, 1, function(row) { values <- as.numeric(row[2:length(row)]) return(data.frame(name = row[1], min = min(values), max = max(values))) })) max_difference$diff <- max_difference$max - max_difference$min # sort based on the difference max_difference <- max_difference[order(max_difference$diff, decreasing = T), ] head(max_difference)
Plotting the results
The ReactomeGSA package contains two functions to visualize these pathway results. The first simply plots the expression for a selected pathway:
plot_gsva_pathway(gsva_result, pathway_id = rownames(max_difference)[1])
For a better overview, the expression of multiple pathways can be shown as a heatmap using gplots heatmap.2 function:
# Additional parameters are directly passed to gplots heatmap.2 function plot_gsva_heatmap(gsva_result, max_pathways = 15, margins = c(6,20))
The plot_gsva_heatmap function can also be used to only display specific pahtways:
# limit to selected B cell related pathways relevant_pathways <- c("R-HSA-983170", "R-HSA-388841", "R-HSA-2132295", "R-HSA-983705", "R-HSA-5690714") plot_gsva_heatmap(gsva_result, pathway_ids = relevant_pathways, # limit to these pathways margins = c(6,30), # adapt the figure margins in heatmap.2 dendrogram = "col", # only plot column dendrogram scale = "row", # scale for each pathway key = FALSE, # don't display the color key lwid=c(0.1,4)) # remove the white space on the left
This analysis shows us that cluster 8 has a marked up-regulation of B Cell receptor signalling, which is linked to a co-stimulation of the CD28 family. Additionally, there is a gradient among the cluster with respect to genes releated to antigen presentation.
Therefore, we are able to further classify the observed B cell subtypes based on their pathway activity.
Pathway-level PCA
The pathway-level expression analysis can also be used to run a Principal Component Analysis on the samples. This is simplified through the function plot_gsva_pca:
plot_gsva_pca(gsva_result)
In this analysis, cluster 11 is a clear outlier from the other B cell subtypes and therefore might be prioritised for further evaluation.
Session Info
sessionInfo()
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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