Vladislav Uzunangelov scite author profile

Recent genomic analyses of pathologically-defined tumor types identify “within-a-tissue” disease subtypes. However, the extent to which genomic signatures are shared across tissues is still unclear. We performed an integrative analysis using five genome-wide platforms and one proteomic platform on 3,527 specimens from 12 cancer types, revealing a unified classification into 11 major subtypes. Five subtypes were nearly identical to their tissue-of-origin counterparts, but several distinct cancer types were found to converge into common subtypes. Lung squamous, head & neck, and a subset of bladder cancers coalesced into one subtype typified by TP53 alterations, TP63 amplifications, and high expression of immune and proliferation pathway genes. Of note, bladder cancers split into three pan-cancer subtypes. The multi-platform classification, while correlated with tissue-of-origin, provides independent information for predicting clinical outcomes. All datasets are available for data-mining from a unified resource to support further biological discoveries and insights into novel therapeutic strategies.

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Integrative Analysis Identifies Four Molecular and Clinical Subsets in Uveal Melanoma

Robertson¹,

Shih²,

Yau³

et al. 2017

Cancer Cell

708

712

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SUMMARY Comprehensive multiplatform analysis of 80 uveal melanomas (UM) identifies four molecularly distinct, clinically relevant subtypes: two associated with poor-prognosis monosomy 3 (M3) and two with better-prognosis disomy 3 (D3). We show that BAP1 loss follows M3 occurrence and correlates with a global DNA methylation state that is distinct from D3-UM. Poor-prognosis M3-UM divide into subsets with divergent genomic aberrations, transcriptional features, and clinical outcomes. We report change-of-function SRSF2 mutations. Within D3-UM, EIF1AX- and SRSF2/SF3B1 -mutant tumors have distinct somatic copy number alterations and DNA methylation profiles, providing insight into the biology of these low-versus intermediate-risk clinical mutation subtypes.

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Integrative Analysis Identifies Four Molecular and Clinical Subsets in Uveal Melanoma

Robertson¹,

Shih²,

Yau³

et al. 2018

Cancer Cell

252

467

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In the originally published version of this paper, there were two instances in which a paper by Raab et al. was cited, but the full reference was accidentally omitted from the reference list. First, in the subsection titled ''Arid1a Haploinsufficiency Alters Global Chromatin Occupancy and Metastasis Genes,'' paragraph 4, the authors wrote, ''To determine if these genes have direct interactions with ARID1A and SWI/SNF components in human HCC, we examined ChIP-seq experiments from HepG2 cells performed by Raab et al.'' Second, in the legend for Figure 7G, the authors wrote, ''ChIP-seq data showing binding of EMILIN1, MAT1A, LCN2, and IL1R1 loci by ARID1A and SNF5 over input in human HepG2 hepatoma cells (data from Raab et al.).''

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Phosphoproteome Integration Reveals Patient-Specific Networks in Prostate Cancer

Drake

Paull

Graham

et al. 2016

Cell

209

234

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SUMMARY We used clinical tissue from lethal metastatic castration resistant prostate cancer (CRPC) patients obtained at rapid autopsy to evaluate diverse genomic, transcriptomic, and phosphoproteomic datasets for pathway analysis. Using Tied Diffusion through Interacting Events (TieDIE), we integrated differentially expressed master transcriptional regulators, functionally mutated genes, and differentially activated kinases in CRPC tissues to synthesize a robust signaling network consisting of druggable kinase pathways. Using MSigDB hallmark gene sets, six major signaling pathways with phosphorylation of several key residues were significantly enriched in CRPC tumors after incorporation of phosphoproteomic data. Individual autopsy profiles developed using these hallmarks revealed clinically relevant pathway information potentially suitable for patient stratification and targeted therapies in late stage prostate cancer. Here we describe phosphorylation-based cancer hallmarks using integrated personalized signatures (pCHIPS) that sheds light on the diversity of activated signaling pathways in metastatic CRPC while providing an integrative, pathway-based reference for drug prioritization in individual patients.

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A basal stem cell signature identifies aggressive prostate cancer phenotypes

Smith

Sokolov

Uzunangelov

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

178

172

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Evidence from numerous cancers suggests that increased aggressiveness is accompanied by up-regulation of signaling pathways and acquisition of properties common to stem cells. It is unclear if different subtypes of late-stage cancer vary in stemness properties and whether or not these subtypes are transcriptionally similar to normal tissue stem cells. We report a gene signature specific for human prostate basal cells that is differentially enriched in various phenotypes of late-stage metastatic prostate cancer. We FACSpurified and transcriptionally profiled basal and luminal epithelial populations from the benign and cancerous regions of primary human prostates. High-throughput RNA sequencing showed the basal population to be defined by genes associated with stem cell signaling programs and invasiveness. Application of a 91-gene basal signature to gene expression datasets from patients with organconfined or hormone-refractory metastatic prostate cancer revealed that metastatic small cell neuroendocrine carcinoma was molecularly more stem-like than either metastatic adenocarcinoma or organ-confined adenocarcinoma. Bioinformatic analysis of the basal cell and two human small cell gene signatures identified a set of E2F target genes common between prostate small cell neuroendocrine carcinoma and primary prostate basal cells. Taken together, our data suggest that aggressive prostate cancer shares a conserved transcriptional program with normal adult prostate basal stem cells.RNA-seq | prostate cancer | stem cell signature | basal cell | neuroendocrine prostate cancer

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