Pan-cancer Immunogenomic Analyses Reveal Genotype-Immunophenotype Relationships and Predictors of Response to Checkpoint Blockade

Charoentong, Pornpimol; Finotello, Francesca; Angelova, Mihaela; Mayer, Clemens; Efremova, Mirjana; Rieder, Dietmar; Hackl, Hubert; Trajanoski, Zlatko

doi:10.1016/j.celrep.2016.12.019

Cited by 2,996 publications

(2,408 citation statements)

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“…Another immune signature seen in C1, C3, C5, and C6 includes transcription factors NFKB1, STAT3, EGR1, and JUN/FOS, as well as TNF and chemokines CXCL1–3 mRNAs implicated in recruiting such cellular immune responses (Figures 4A and S4) (Davis et al, 2016). We explored if expression of PD-L1 overlaps signatures that were recently developed and validated in other cancers for MDSCs, CD8+ CTL, Tregs, and other immune cells (Charoentong et al, 2017; Gentles et al, 2015). Consensus clustering using an MDSC-related signature sorted 4 clusters with very high to low expression of 49 MDSC-related genes, including PD-L1 (Figure S5A).…”

Section: Resultsmentioning

confidence: 99%

“…mRNA clustering viewed using interactive Next-Generation Clustered Heat-maps (NG-CHMs) (Broom et al, 2017), and an updated Pathway Recognition Algorithm using Data Integration on Genomic Models (PARADIGM) tool (Vaske et al, 2010), helped to integrate omics data with pathways related to squamous cell stemness, differentiation, growth, immortalization, proliferation, survival, and inflammation. Clustered mRNA alterations for immune checkpoint PD-L1, cytokines, and cell determinants were deconvoluted using validated gene signatures for immune cell types and CIBERSORT, revealing overlap between effector T cell and immune checkpoint signatures with those of T-regulatory and Myeloid suppressor cells, which are linked to reduced efficacy of immune therapy (Charoentong et al, 2017; Gentles et al, 2015). These analyses and findings have the potential to influence how we classify SCCs into molecular subtypes, with possible implications for diagnosis, prognosis, and therapy.…”

Section: Introductionmentioning

confidence: 99%

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Genomic, Pathway Network, and Immunologic Features Distinguishing Squamous Carcinomas

Campbell¹,

Yau²,

Bowlby³

et al. 2018

Cell Reports

256

275

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SUMMARY This integrated, multiplatform PanCancer Atlas study co-mapped and identified distinguishing molecular features of squamous cell carcinomas (SCCs) from five sites associated with smoking and/or human papillomavirus (HPV). SCCs harbor 3q, 5p, and other recurrent chromosomal copy-number alterations (CNAs), DNA mutations, and/or aberrant methylation of genes and microRNAs, which are correlated with the expression of multi-gene programs linked to squamous cell stemness, epithelial-to-mesenchymal differentiation, growth, genomic integrity, oxidative damage, death, and inflammation. Low-CNA SCCs tended to be HPV(+) and display hypermethylation with repression of TET1 demethylase and FANCF, previously linked to predisposition to SCC, or harbor mutations affecting CASP8, RAS-MAPK pathways, chromatin modifiers, and immunoregulatory molecules. We uncovered hypomethylation of the alternative promoter that drives expression of the ΔNp63 oncogene and embedded miR944. Co-expression of immune checkpoint, T-regulatory, and Myeloid suppressor cells signatures may explain reduced efficacy of immune therapy. These findings support possibilities for molecular classification and therapeutic approaches.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Genomic, Pathway Network, and Immunologic Features Distinguishing Squamous Carcinomas

Campbell¹,

Yau²,

Bowlby³

et al. 2018

Cell Reports

256

275

View full text Add to dashboard Cite

show abstract

“…Using this approach, Angelova et al defined 31 custom gene sets representing genes up-regulated in specific immune cell sub-populations and used GSEAPreranked to characterize tumor-infiltrating immune cells in colorectal cancer (CRC) patients [10]. This approach was later extended through the definition of 28 pan-cancer immune gene sets and used to analyze more than 8000 samples across 19 different TCGA solid cancers (results available at https://tcia.at/) [11]. …”

Section: Gene Set Enrichment Analysis and Other Scoring Methods Basedmentioning

confidence: 99%

“…Specifically, we considered tumor samples from three TCGA cancers for which both microarrays and RNA-seq data were available and estimated a gene-specific model by fitting a smoothing spline with four degrees of freedom to transform RNA-seq data, as log-transformed transcripts per millions (TPM), into “microarrays-like” data [11]. We then used the model to transform RNA-seq data from more than 8000 TCGA tumors across 19 different cancer types and inferred the fractions of tumor-infiltrating immune cells with CIBERSORT (results available at https://tcia.at) [11]. Similarly, Ali et al [61] analyzed with CIBERSORT more than 11,000 breast tumor RNA-seq data sets normalized with limma voom, a method that transforms RNA-seq log counts to enable downstream application of microarray-specific methodologies [62].…”

Section: Challenges In the Quantification Of Tumor-infiltrating Immunmentioning

confidence: 99%

Quantifying tumor-infiltrating immune cells from transcriptomics data

Finotello

Trajanoski

2018

Cancer Immunol Immunother

Self Cite

299

244

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By exerting pro- and anti-tumorigenic actions, tumor-infiltrating immune cells can profoundly influence tumor progression, as well as the success of anti-cancer therapies. Therefore, the quantification of tumor-infiltrating immune cells holds the promise to unveil the multi-faceted role of the immune system in human cancers and its involvement in tumor escape mechanisms and response to therapy. Tumor-infiltrating immune cells can be quantified from RNA sequencing data of human tumors using bioinformatics approaches. In this review, we describe state-of-the-art computational methods for the quantification of immune cells from transcriptomics data and discuss the open challenges that must be addressed to accurately quantify immune infiltrates from RNA sequencing data of human bulk tumors.Electronic supplementary materialThe online version of this article (10.1007/s00262-018-2150-z) contains supplementary material, which is available to authorized users.

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“…Molecular subtypes of ovarian, melanoma, and pancreatic cancer have been defined based on measures of immune infiltration (Cancer Genome Atlas Research Network, 2011; Cancer Genome Atlas Network, 2015; Bailey et al, 2016), and a number of other tumors show variation in immune gene expression by molecular subtype (Iglesia et al, 2014, 2016; Kardos et al, 2016). Recent publications (Charoentong et al, 2017; Li et al, 2016; Rooney et al, 2015) have presented comprehensive analyses of TCGA data on the basis of immune content response. A recent study (Thorsson et al, 2018) reports on a series of immunogenomic characterizations that include assessments such as total lymphocytic infiltrate, immune cell type fractions, immune gene expression signatures, HLA type and expression, neoantigen prediction, T cell and B cell repertoire, and viral RNA expression.…”

Section: Introductionmentioning

confidence: 99%

Spatial Organization and Molecular Correlation of Tumor-Infiltrating Lymphocytes Using Deep Learning on Pathology Images

et al. 2018

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SUMMARY Beyond sample curation and basic pathologic characterization, the digitized H&E-stained images of TCGA samples remain underutilized. To highlight this resource, we present mappings of tumor-infiltrating lymphocytes (TILs) based on H&E images from 13 TCGA tumor types. These TIL maps are derived through computational staining using a convolutional neural network trained to classify patches of images. Affinity propagation revealed local spatial structure in TIL patterns and correlation with overall survival. TIL map structural patterns were grouped using standard histopathological parameters. These patterns are enriched in particular T cell subpopulations derived from molecular measures. TIL densities and spatial structure were differentially enriched among tumor types, immune subtypes, and tumor molecular subtypes, implying that spatial infiltrate state could reflect particular tumor cell aberration states. Obtaining spatial lymphocytic patterns linked to the rich genomic characterization of TCGA samples demonstrates one use for the TCGA image archives with insights into the tumor-immune microenvironment.

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Pan-cancer Immunogenomic Analyses Reveal Genotype-Immunophenotype Relationships and Predictors of Response to Checkpoint Blockade

Cited by 2,996 publications

References 39 publications

Genomic, Pathway Network, and Immunologic Features Distinguishing Squamous Carcinomas

Genomic, Pathway Network, and Immunologic Features Distinguishing Squamous Carcinomas

Quantifying tumor-infiltrating immune cells from transcriptomics data

Spatial Organization and Molecular Correlation of Tumor-Infiltrating Lymphocytes Using Deep Learning on Pathology Images

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