Loss Cooperates with Overexpression to Promote Lymphoma in Mice

Overview

Journal Blood

Publisher Elsevier

Specialty Hematology

Date 2017 Mar 15

PMID 28288979

Citations 49

Authors

Idoia Garcia-Ramirez

Saber Tadros

Ines Gonzalez-Herrero

Alberto Martin-Lorenzo

Guillermo Rodriguez-Hernandez

Dalia Moore

Lucia Ruiz-Roca

Oscar Blanco

Diego Alonso-Lopez

Javier De Las Rivas

Keenan Hartert

Romain Duval

David Klinkebiel

Martin Bast

Julie Vose

Matthew Lunning

Kai Fu

Timothy Greiner

Fernando Rodrigues-Lima

Rafael Jimenez

Francisco Javier Garcia Criado

Maria Begona Garcia Cenador

Paul Brindle

Carolina Vicente-Duenas

Ash Alizadeh

Isidro Sanchez-Garcia

Michael R Green

Affiliations

Soon will be listed here.

Abstract

CREBBP is targeted by inactivating mutations in follicular lymphoma (FL) and diffuse large B-cell lymphoma (DLBCL). Here, we provide evidence from transgenic mouse models that Crebbp deletion results in deficits in B-cell development and can cooperate with Bcl2 overexpression to promote B-cell lymphoma. Through transcriptional and epigenetic profiling of these B cells, we found that Crebbp inactivation was associated with broad transcriptional alterations, but no changes in the patterns of histone acetylation at the proximal regulatory regions of these genes. However, B cells with Crebbp inactivation showed high expression of Myc and patterns of altered histone acetylation that were localized to intragenic regions, enriched for Myc DNA binding motifs, and showed Myc binding. Through the analysis of CREBBP mutations from a large cohort of primary human FL and DLBCL, we show a significant difference in the spectrum of CREBBP mutations in these 2 diseases, with higher frequencies of nonsense/frameshift mutations in DLBCL compared with FL. Together, our data therefore provide important links between Crebbp inactivation and Bcl2 dependence and show a role for Crebbp inactivation in the induction of Myc expression. We suggest this may parallel the role of CREBBP frameshift/nonsense mutations in DLBCL that result in loss of the protein, but may contrast the role of missense mutations in the lysine acetyltransferase domain that are more frequently observed in FL and yield an inactive protein.

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