Identification of Subtypes of Barrett's Esophagus and Esophageal Adenocarcinoma Based on DNA Methylation Profiles and Integration of Transcriptome and Genome Data.
Adenocarcinoma
/ genetics
Aged
Antineoplastic Agents
/ pharmacology
Barrett Esophagus
/ drug therapy
Cyclin E
/ genetics
DNA Methylation
/ drug effects
Disease Progression
Epigenesis, Genetic
/ drug effects
Esophageal Mucosa
/ pathology
Esophageal Neoplasms
/ genetics
Female
Gene Amplification
Gene Expression Regulation, Neoplastic
/ drug effects
Humans
Male
Middle Aged
Oncogene Proteins
/ genetics
Promoter Regions, Genetic
/ genetics
RNA-Seq
Retrospective Studies
Temozolomide
/ pharmacology
Whole Genome Sequencing
antitumor immune response
gene repression
prognostic factor
response to treatment
Journal
Gastroenterology
ISSN: 1528-0012
Titre abrégé: Gastroenterology
Pays: United States
ID NLM: 0374630
Informations de publication
Date de publication:
05 2020
05 2020
Historique:
received:
12
09
2019
revised:
27
01
2020
accepted:
29
01
2020
pubmed:
8
2
2020
medline:
21
10
2020
entrez:
8
2
2020
Statut:
ppublish
Résumé
Esophageal adenocarcinomas (EACs) are heterogeneous and often preceded by Barrett's esophagus (BE). Many genomic changes have been associated with development of BE and EAC, but little is known about epigenetic alterations. We performed epigenetic analyses of BE and EAC tissues and combined these data with transcriptome and genomic data to identify mechanisms that control gene expression and genome integrity. In a retrospective cohort study, we collected tissue samples and clinical data from 150 BE and 285 EAC cases from the Oesophageal Cancer Classification and Molecular Stratification consortium in the United Kingdom. We analyzed methylation profiles of all BE and EAC tissues and assigned them to subgroups using non-negative matrix factorization with k-means clustering. Data from whole-genome sequencing and transcriptome studies were then incorporated; we performed integrative methylation and RNA-sequencing analyses to identify genes that were suppressed with increased methylation in promoter regions. Levels of different immune cell types were computed using single-sample gene set enrichment methods. We derived 8 organoids from 8 EAC tissues and tested their sensitivity to different drugs. BE and EAC samples shared genome-wide methylation features, compared with normal tissues (esophageal, gastric, and duodenum; controls) from the same patients and grouped into 4 subtypes. Subtype 1 was characterized by DNA hypermethylation with a high mutation burden and multiple mutations in genes in cell cycle and receptor tyrosine signaling pathways. Subtype 2 was characterized by a gene expression pattern associated with metabolic processes (ATP synthesis and fatty acid oxidation) and lack methylation at specific binding sites for transcription factors; 83% of samples of this subtype were BE and 17% were EAC. The third subtype did not have changes in methylation pattern, compared with control tissue, but had a gene expression pattern that indicated immune cell infiltration; this tumor type was associated with the shortest time of patient survival. The fourth subtype was characterized by DNA hypomethylation associated with structure rearrangements, copy number alterations, with preferential amplification of CCNE1 (cells with this gene amplification have been reported to be sensitive to CDK2 inhibitors). Organoids with reduced levels of MGMT and CHFR expression were sensitive to temozolomide and taxane drugs. In a comprehensive integrated analysis of methylation, transcriptome, and genome profiles of more than 400 BE and EAC tissues, along with clinical data, we identified 4 subtypes that were associated with patient outcomes and potential responses to therapy.
Sections du résumé
BACKGROUND & AIMS
Esophageal adenocarcinomas (EACs) are heterogeneous and often preceded by Barrett's esophagus (BE). Many genomic changes have been associated with development of BE and EAC, but little is known about epigenetic alterations. We performed epigenetic analyses of BE and EAC tissues and combined these data with transcriptome and genomic data to identify mechanisms that control gene expression and genome integrity.
METHODS
In a retrospective cohort study, we collected tissue samples and clinical data from 150 BE and 285 EAC cases from the Oesophageal Cancer Classification and Molecular Stratification consortium in the United Kingdom. We analyzed methylation profiles of all BE and EAC tissues and assigned them to subgroups using non-negative matrix factorization with k-means clustering. Data from whole-genome sequencing and transcriptome studies were then incorporated; we performed integrative methylation and RNA-sequencing analyses to identify genes that were suppressed with increased methylation in promoter regions. Levels of different immune cell types were computed using single-sample gene set enrichment methods. We derived 8 organoids from 8 EAC tissues and tested their sensitivity to different drugs.
RESULTS
BE and EAC samples shared genome-wide methylation features, compared with normal tissues (esophageal, gastric, and duodenum; controls) from the same patients and grouped into 4 subtypes. Subtype 1 was characterized by DNA hypermethylation with a high mutation burden and multiple mutations in genes in cell cycle and receptor tyrosine signaling pathways. Subtype 2 was characterized by a gene expression pattern associated with metabolic processes (ATP synthesis and fatty acid oxidation) and lack methylation at specific binding sites for transcription factors; 83% of samples of this subtype were BE and 17% were EAC. The third subtype did not have changes in methylation pattern, compared with control tissue, but had a gene expression pattern that indicated immune cell infiltration; this tumor type was associated with the shortest time of patient survival. The fourth subtype was characterized by DNA hypomethylation associated with structure rearrangements, copy number alterations, with preferential amplification of CCNE1 (cells with this gene amplification have been reported to be sensitive to CDK2 inhibitors). Organoids with reduced levels of MGMT and CHFR expression were sensitive to temozolomide and taxane drugs.
CONCLUSIONS
In a comprehensive integrated analysis of methylation, transcriptome, and genome profiles of more than 400 BE and EAC tissues, along with clinical data, we identified 4 subtypes that were associated with patient outcomes and potential responses to therapy.
Identifiants
pubmed: 32032585
pii: S0016-5085(20)30156-6
doi: 10.1053/j.gastro.2020.01.044
pmc: PMC7305027
mid: EMS86517
pii:
doi:
Substances chimiques
Antineoplastic Agents
0
CCNE1 protein, human
0
Cyclin E
0
Oncogene Proteins
0
Temozolomide
YF1K15M17Y
Types de publication
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
1682-1697.e1Subventions
Organisme : Cancer Research UK
ID : RG81771/84119
Pays : United Kingdom
Organisme : Medical Research Council
ID : MR/M009157/1
Pays : United Kingdom
Organisme : Cancer Research UK
ID : A15874
Pays : United Kingdom
Organisme : Medical Research Council
ID : RG84369
Pays : United Kingdom
Organisme : Medical Research Council
ID : MC_UU_12022/2
Pays : United Kingdom
Investigateurs
Rebecca C Fitzgerald
(RC)
Ayesha Noorani
(A)
Paul A W Edwards
(PAW)
Nicola Grehan
(N)
Barbara Nutzinger
(B)
Caitriona Hughes
(C)
Elwira Fidziukiewicz
(E)
Jan Bornschein
(J)
Shona MacRae
(S)
Jason Crawte
(J)
Alex Northrop
(A)
Gianmarco Contino
(G)
Xiaodun Li
(X)
Rachel de la Rue
(R)
Maria O'Donovan
(M)
Ahmad Miremadi
(A)
Shalini Malhotra
(S)
Monika Tripathi
(M)
Simon Tavaré
(S)
Andy G Lynch
(AG)
Matthew Eldridge
(M)
Maria Secrier
(M)
Lawrence Bower
(L)
Ginny Devonshire
(G)
Juliane Perner
(J)
Sriganesh Jammula
(S)
Jim Davies
(J)
Charles Crichton
(C)
Nick Carroll
(N)
Peter Safranek
(P)
Andrew Hindmarsh
(A)
Vijayendran Sujendran
(V)
Stephen J Hayes
(SJ)
Yeng Ang
(Y)
Shaun R Preston
(SR)
Sarah Oakes
(S)
Izhar Bagwan
(I)
Vicki Save
(V)
Richard J E Skipworth
(RJE)
Ted R Hupp
(TR)
J Robert O'Neill
(JR)
Olga Tucker
(O)
Andrew Beggs
(A)
Philippe Taniere
(P)
Sonia Puig
(S)
Timothy J Underwood
(TJ)
Fergus Noble
(F)
Jack Owsley
(J)
Hugh Barr
(H)
Neil Shepherd
(N)
Oliver Old
(O)
Jesper Lagergren
(J)
James Gossage
(J)
Andrew Davies
(A)
Fuju Chang
(F)
Janine Zylstra
(J)
Ula Mahadeva
(U)
Vicky Goh
(V)
Francesca D Ciccarelli
(FD)
Grant Sanders
(G)
Richard Berrisford
(R)
Catherine Harden
(C)
Mike Lewis
(M)
Ed Cheong
(E)
Bhaskar Kumar
(B)
Simon L Parsons
(SL)
Irshad Soomro
(I)
Philip Kaye
(P)
John Saunders
(J)
Laurence Lovat
(L)
Rehan Haidry
(R)
Laszlo Igali
(L)
Michael Scott
(M)
Sharmila Sothi
(S)
Sari Suortamo
(S)
Suzy Lishman
(S)
George B Hanna
(GB)
Krishna Moorthy
(K)
Christopher J Peters
(CJ)
Anna Grabowska
(A)
Richard Turkington
(R)
Commentaires et corrections
Type : CommentIn
Type : ErratumIn
Informations de copyright
Copyright © 2020 AGA Institute. Published by Elsevier Inc. All rights reserved.
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