Significant over-representation of pathway gene sets for a given gene list

Glioma (Primary solid tumor)

28 January 2016 | analyses__2016_01_28

Maintainer Information

Citation Information

Maintained by Juok Cho (Broad Institute)

Cite as Broad Institute TCGA Genome Data Analysis Center (2016): Significant over-representation of pathway gene sets for a given gene list. Broad Institute of MIT and Harvard. doi:10.7908/C1Z60NFH

Overview

Introduction

This pipeline inspects significant overlapping pathway gene sets for a given gene list using a hypergeometric test. For the gene set database, we uses GSEA MSigDB Class2: Canonical Pathways DB as a gene set data. Further details about the MsigDB gene sets, please visit The Broad Institute GSEA MsigDB

Summary

For a given gene list, a hypergeometric test was tried to find significant overlapping canonical pathways using 1320 gene sets. In terms of FDR adjusted p.values, top 5 significant overlapping gene sets are listed as below.

KEGG_GLIOMA, KEGG_MELANOMA, KEGG_NON_SMALL_CELL_LUNG_CANCER, KEGG_CHRONIC_MYELOID_LEUKEMIA, PID_ERBB1_RECEPTOR_PROXIMAL_PATHWAY

Results

For a given gene list, top significant overlapping canonical pathway gene sets

Table 1. Get Full Table This table shows significant gene sets in which at least one gene is found and its FDR adjusted p.value is smaller than 0.3. the hypergeometric p-value is a probability of randomly drawing x or more successes(gene overlaps in gene set database) from the population (gene universe consisting of N number of genes) in k total draws(the number of input genes). The hypergeometric test is identical to the corresponding one-tailed version of Fisher's exact test. That is, P(X=x) = f(x| N,m,k). The FDR q.value was obtained for 1320 multiple comparison.

GS(gene set) pathway name	gene.list	GS size (m)	n.NotInGS (n)	Gene universe (N)	n.drawn (k)	n.found (x)	p.value (p(X>=x))	FDR (q.value)
KEGG GLIOMA	gene.list	65	45891	45956	221	12	3.643e-16	4.809e-13
KEGG MELANOMA	gene.list	71	45885	45956	221	11	4.923e-14	3.249e-11
KEGG NON SMALL CELL LUNG CANCER	gene.list	54	45902	45956	221	10	1.072e-13	4.717e-11
KEGG CHRONIC MYELOID LEUKEMIA	gene.list	73	45883	45956	221	10	2.571e-12	8.484e-10
PID ERBB1 RECEPTOR PROXIMAL PATHWAY	gene.list	35	45921	45956	221	8	5.301e-12	1.399e-09
KEGG PROSTATE CANCER	gene.list	89	45867	45956	221	10	1.968e-11	4.330e-09
KEGG NEUROTROPHIN SIGNALING PATHWAY	gene.list	126	45830	45956	221	11	3.101e-11	5.848e-09
KEGG MAPK SIGNALING PATHWAY	gene.list	267	45689	45956	221	14	6.082e-11	1.004e-08
KEGG ENDOMETRIAL CANCER	gene.list	52	45904	45956	221	8	1.580e-10	2.318e-08
REACTOME SIGNALING BY CONSTITUTIVELY ACTIVE EGFR	gene.list	18	45938	45956	221	6	2.044e-10	2.698e-08
PID PI3KPLCTRKPATHWAY	gene.list	36	45920	45956	221	7	4.009e-10	4.811e-08
PID PDGFRBPATHWAY	gene.list	129	45827	45956	221	10	8.053e-10	8.858e-08
KEGG PATHWAYS IN CANCER	gene.list	328	45628	45956	221	14	8.952e-10	9.089e-08
KEGG BLADDER CANCER	gene.list	42	45914	45956	221	7	1.264e-09	1.192e-07
PID P53DOWNSTREAMPATHWAY	gene.list	137	45819	45956	221	10	1.452e-09	1.278e-07
KEGG PANCREATIC CANCER	gene.list	70	45886	45956	221	8	1.840e-09	1.518e-07
PID ERBB1 DOWNSTREAM PATHWAY	gene.list	105	45851	45956	221	9	2.353e-09	1.827e-07
KEGG ERBB SIGNALING PATHWAY	gene.list	87	45869	45956	221	8	1.062e-08	6.676e-07
REACTOME SIGNALLING BY NGF	gene.list	217	45739	45956	221	11	1.014e-08	6.676e-07
REACTOME DEVELOPMENTAL BIOLOGY	gene.list	396	45560	45956	221	14	9.867e-09	6.676e-07

Figure 1. Get High-res Image This figure is an event heatmap indicating gene matches across gene sets

Methods & Data

Input

Gene set database = c2.cp.v4.0.symbols.gmt

Input gene list = MutSig2CV.input.genenames.txt

Hypergeometric Test

For a given gene list, it uses a hypergeometric test to get a significance of each overlapping pathway gene set. The hypergeometric p-value is obtained by R library function phyper() and is defined as a probability of randomly drawing x or more successes(gene matches) from the population consisting N genes in k(the input genes) total draws.

a cumulative p-value using the R function phyper():

ex). a probability to see at least x genes in the group is defined as p(X>=x) = 1 - p(X<=x)= 1 - phyper(x-1, m, n, k, lower.tail=FALSE, log.p=FALSE) that is, f(x| N, m, k) = (m) C (k) * ((N-m) C (n-k)) / ((N) C (n))

The hypergeometric test is identical to the corresponding one-tailed version of Fisher's exact test.

ex). Fisher' exact test = matrix(c(n.Found, n.GS-n.Found, n.drawn-n.Found, n.NotGS- (n.drawn-n.Found)), nrow=2, dimnames = list(inputGenes = c("Found", "NotFound"),GeneUniverse = c("GS", "nonGS")) )

Download Results

In addition to the links below, the full results of the analysis summarized in this report can also be downloaded programmatically using firehose_get, or interactively from either the Broad GDAC website or TCGA Data Coordination Center Portal.

References

[1] Johnson, N.L., et al, Univariate Discrete Distributions, Second Edition, Wiley (1992)

[2] Berkopec, Aleš, HyperQuick algorithm for discrete hypergeometric distribution, Journal of Discrete Algorithms:341-347 (2007)

[3] Tamayo, et al, Molecular Signatures Database, MSigDB, PNAS:15545-15550 (2005)

[4] The GSEA MSigDB Compute overlaps

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