Using fgsea package

Alexey Sergushichev

2016-06-22

fgsea is an R-package for fast preranked gene set enrichment analysis (GSEA). The performance is achieved by using an algorithm for cumulative GSEA-statistic calculation. This allows to reuse samples between different gene set sizes. See the preprint for algorithmic details.

Loading necessary libraryries

Quick run

Loading example pathways and gene-level statistics:

data(examplePathways)
data(exampleRanks)

Running fgsea:

fgseaRes <- fgsea(pathways = examplePathways, 
                  stats = exampleRanks,
                  minSize=15,
                  maxSize=500,
                  nperm=10000)

The resulting table contains enrichment scores and p-values:

head(fgseaRes[order(pval), ])
##                                pathway         pval        padj        ES
## 1:                  5990980_Cell_Cycle 0.0001219512 0.001786368 0.5388497
## 2:         5990979_Cell_Cycle,_Mitotic 0.0001255808 0.001786368 0.5594755
## 3:    5991210_Signaling_by_Rho_GTPases 0.0001323452 0.001786368 0.4238512
## 4:                     5991454_M_Phase 0.0001381406 0.001786368 0.5576247
## 5: 5991023_Metabolism_of_carbohydrates 0.0001400756 0.001786368 0.4944766
## 6:        5991209_RHO_GTPase_Effectors 0.0001403312 0.001786368 0.5248796
##         NES nMoreExtreme size                             leadingEdge
## 1: 2.680171            0  369   66336,66977,12442,107995,66442,19361,
## 2: 2.741617            0  317   66336,66977,12442,107995,66442,12571,
## 3: 2.010502            0  231 66336,66977,20430,104215,233406,107995,
## 4: 2.555452            0  173   66336,66977,12442,107995,66442,52276,
## 5: 2.239412            0  160    11676,21991,15366,58250,12505,20527,
## 6: 2.373994            0  157 66336,66977,20430,104215,233406,107995,

It takes about ten seconds to get results with significant hits after FDR correction:

sum(fgseaRes[, padj < 0.01])
## [1] 84

One can make an enrichment plot for a pathway:

plotEnrichment(examplePathways[["5991130_Programmed_Cell_Death"]],
               exampleRanks) + labs(title="Programmed Cell Death")

Or make a table plot for a bunch of selected pathways:

topPathwaysUp <- fgseaRes[ES > 0][head(order(pval), n=10), pathway]
topPathwaysDown <- fgseaRes[ES < 0][head(order(pval), n=10), pathway]
topPathways <- c(topPathwaysUp, rev(topPathwaysDown))
plotGseaTable(examplePathways[topPathways], exampleRanks, fgseaRes, 
              gseaParam = 0.5)

From the plot above one can see that there are very similar pathways in the table (for example 5991502_Mitotic_Metaphase_and_Anaphase and 5991600_Mitotic_Anaphase). To select only independent pathways one can use collapsePathways function:

collapsedPathways <- collapsePathways(fgseaRes[order(pval)][padj < 0.01], 
                                      examplePathways, exampleRanks)
mainPathways <- fgseaRes[pathway %in% collapsedPathways$mainPathways][
                         order(-NES), pathway]
plotGseaTable(examplePathways[mainPathways], exampleRanks, fgseaRes, 
              gseaParam = 0.5)

To save the results data:table::fwrite function can be used:

library(data.table)
fwrite(fgseaRes, file="fgseaRes.txt", sep="\t", sep2=c("", " ", ""))

To make leading edge more human-readable it can be converted using mapIds function and a corresponding database (here org.Mm.eg.db for mouse):

library(org.Mm.eg.db)
fgseaResMain <- fgseaRes[match(mainPathways, pathway)]
fgseaResMain[, leadingEdge := lapply(leadingEdge, mapIds, x=org.Mm.eg.db, keytype="ENTREZID", column="SYMBOL")]
fwrite(fgseaResMain, file="fgseaResMain.txt", sep="\t", sep2=c("", " ", ""))

Performance considerations

Please, be aware that fgsea function takes about O(nk^{3/2}) time, where n is number of permutations and k is a maximal size of the pathways. That means that setting maxSize parameter with a value of ~500 is strongly recommended.

Also, fgsea is parallelized using BiocParallel package. By default the first registered backend returned by bpparam() is used. To tweak the parallelization one can either specify BPPARAM parameter used for bclapply of set nproc parameter, which is a shorthand for setting BPPARAM=MulticoreParam(workers = nproc).

Using Reactome pathways

For convenience there is reactomePathways function that obtains pathways from Reactome for given set of genes. Package reactome.db is required to be installed.

pathways <- reactomePathways(names(exampleRanks))
fgseaRes <- fgsea(pathways, exampleRanks, nperm=1000, maxSize=500)
head(fgseaRes)
##                                                            pathway
## 1:                      5-Phosphoribose 1-diphosphate biosynthesis
## 2: A tetrasaccharide linker sequence is required for GAG synthesis
## 3:                           ABC transporters in lipid homeostasis
## 4:                          ABC-family proteins mediated transport
## 5:                       ADP signalling through P2Y purinoceptor 1
## 6:                      ADP signalling through P2Y purinoceptor 12
##           pval       padj         ES        NES nMoreExtreme size
## 1: 0.893442623 0.96125515  0.4267378  0.6764002          435    2
## 2: 0.631178707 0.85768606  0.3218180  0.8492249          331   11
## 3: 0.355748373 0.67618349 -0.3850118 -1.1103541          163   13
## 4: 0.351598174 0.67526730  0.2709658  1.0753693          230   66
## 5: 0.005434783 0.05349567  0.6228710  1.8069153            2   16
## 6: 0.025878004 0.15678431  0.5959844  1.6505511           13   13
##                              leadingEdge
## 1:                          328099,19139
## 2: 14733,20971,20970,12032,29873,218271,
## 3: 19299,27403,11307,11806,217265,27409,
## 4: 18669,56199,17463,26444,19179,228769,
## 5:  14696,14702,14700,14682,14676,66066,
## 6:  14696,14702,14700,66066,14697,14693,

Starting from files

One can also start from .rnk and .gmt files as in original GSEA:

rnk.file <- system.file("extdata", "naive.vs.th1.rnk", package="fgsea")
gmt.file <- system.file("extdata", "mouse.reactome.gmt", package="fgsea")

Loading ranks:

ranks <- read.table(rnk.file,
                    header=TRUE, colClasses = c("character", "numeric"))
ranks <- setNames(ranks$t, ranks$ID)
str(ranks)
##  Named num [1:12000] -63.3 -49.7 -43.6 -41.5 -33.3 ...
##  - attr(*, "names")= chr [1:12000] "170942" "109711" "18124" "12775" ...

Loading pathways:

pathways <- gmtPathways(gmt.file)
str(head(pathways))
## List of 6
##  $ 1221633_Meiotic_Synapsis                                                : chr [1:64] "12189" "13006" "15077" "15078" ...
##  $ 1368092_Rora_activates_gene_expression                                  : chr [1:9] "11865" "12753" "12894" "18143" ...
##  $ 1368110_Bmal1:Clock,Npas2_activates_circadian_gene_expression           : chr [1:16] "11865" "11998" "12753" "12952" ...
##  $ 1445146_Translocation_of_Glut4_to_the_Plasma_Membrane                   : chr [1:55] "11461" "11465" "11651" "11652" ...
##  $ 186574_Endocrine-committed_Ngn3+_progenitor_cells                       : chr [1:4] "18012" "18088" "18506" "53626"
##  $ 186589_Late_stage_branching_morphogenesis_pancreatic_bud_precursor_cells: chr [1:4] "11925" "15205" "21410" "246086"

And runnig fgsea:

fgseaRes <- fgsea(pathways, ranks, minSize=15, maxSize=500, nperm=1000)
head(fgseaRes)
##                                                                                    pathway
## 1:                                                                1221633_Meiotic_Synapsis
## 2:                                   1445146_Translocation_of_Glut4_to_the_Plasma_Membrane
## 3: 442533_Transcriptional_Regulation_of_Adipocyte_Differentiation_in_3T3-L1_Pre-adipocytes
## 4:                                                                  508751_Circadian_Clock
## 5:                                               5334727_Mus_musculus_biological_processes
## 6:                                        573389_NoRC_negatively_regulates_rRNA_expression
##         pval      padj         ES        NES nMoreExtreme size
## 1: 0.5201342 0.6911534  0.2885754  0.9579996          309   27
## 2: 0.6721582 0.8255169  0.2387284  0.8457709          407   39
## 3: 0.1119403 0.2562383 -0.3640706 -1.3365538           44   31
## 4: 0.7801418 0.8807758  0.2516324  0.7477776          439   17
## 5: 0.3585714 0.5573551  0.2469065  1.0596762          250  106
## 6: 0.3829787 0.5844415  0.3607407  1.0720155          215   17
##                              leadingEdge
## 1:               15270,12189,71846,19357
## 2:  17918,19341,20336,22628,22627,20619,
## 3: 76199,19014,26896,229003,17977,17978,
## 4:                     20893,59027,19883
## 5:  60406,19361,15270,20893,12189,68240,
## 6:              60406,20018,245688,20017