Mutated KRAS Results in Overexpression of DUSP4, a MAP-kinase Phosphatase, and SMYD3, a Histone Methyltransferase, in Rectal Carcinomas

Overview

Journal Genes Chromosomes Cancer

Specialties Molecular Biology
Oncology

Date 2010 Aug 21

PMID 20725992

Citations 124

Authors

Jochen Gaedcke

Marian Grade

Klaus Jung

Jordi Camps

Peter Jo

Georg Emons

Anastasia Gehoff

Ulrich Sax

Markus Schirmer

Heinz Becker

Tim Beissbarth

Thomas Ried

B Michael Ghadimi

Affiliations

Soon will be listed here.

Abstract

Mutations of the KRAS oncogene are predictive for resistance to treatment with antibodies against the epithelial growth factor receptor in patients with colorectal cancer. Overcoming this therapeutic dilemma could potentially be achieved by the introduction of drugs that inhibit signaling pathways that are activated by KRAS mutations. To identify comprehensively such signaling pathways, we profiled pretreatment biopsies and normal mucosa from 65 patients with locally advanced rectal cancer-30 of which carried mutated KRAS-using global gene expression microarrays. By comparing all tumor tissues exclusively to matched normal mucosa, we could improve assay sensitivity, and identified a total of 22,297 features that were differentially expressed (adjusted P-value <0.05) between normal mucosa and cancer, including several novel potential rectal cancer genes. We then used this comprehensive description of the rectal cancer transcriptome as the baseline for identifying KRAS-dependent alterations. The presence of activating KRAS mutations is significantly correlated to an upregulation of 13 genes (adjusted P-value <0.05), among them DUSP4, a MAP-kinase phosphatase, and SMYD3, a histone methyltransferase. Inhibition of the expression of both genes has previously been shown using the MEK1-inhibitor PD98059 and the antibacterial compound Novobiocin, respectively. These findings suggest a potential approach to overcome resistance to treatment with antibodies against the epithelial growth factor receptor in patients with KRAS-mutant rectal carcinomas.

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