Mutation Analysis of the ERCC4/FANCQ Gene in Hereditary Breast Cancer

Sandra Kohlhase,Thilo Dörk,Tjoung-Won Park-Simon,Andreas Meyer,Peter Schürmann,Natalia Antonenkova,Hans Christiansen,Peter Hillemanns,Marina Bermisheva,Detlev Schindler,Natalia V Bogdanova,Elza Khusnutdinova

doi:10.1371/journal.pone.0085334

Abstract

The ERCC4 protein forms a structure-specific endonuclease involved in the DNA damage response. Different cancer syndromes such as a subtype of Xeroderma pigmentosum, XPF, and recently a subtype of Fanconi Anemia, FA-Q, have been attributed to biallelic ERCC4 gene mutations. To investigate whether monoallelic ERCC4 gene defects play some role in the inherited component of breast cancer susceptibility, we sequenced the whole ERCC4 coding region and flanking untranslated portions in a series of 101 Byelorussian and German breast cancer patients selected for familial disease (set 1, n = 63) or for the presence of the rs1800067 risk haplotype (set 2, n = 38). This study confirmed six known and one novel exonic variants, including four missense substitutions but no truncating mutation. Missense substitution p.R415Q (rs1800067), a previously postulated breast cancer susceptibility allele, was subsequently screened for in a total of 3,698 breast cancer cases and 2,868 controls from Germany, Belarus or Russia. The Gln415 allele appeared protective against breast cancer in the German series, with the strongest effect for ductal histology (OR 0.67; 95%CI 0.49; 0.92; p = 0.003), but this association was not confirmed in the other two series, with the combined analysis yielding an overall Mantel-Haenszel OR of 0.94 (95% CI 0.81; 1.08). There was no significant effect of p.R415Q on breast cancer survival in the German patient series. The other three detected ERCC4 missense mutations included two known rare variants as well as a novel substitution, p.E17V, that we identified on a p.R415Q haplotype background. The p.E17V mutation is predicted to be probably damaging but was present in just one heterozygous patient. We conclude that the contribution of ERCC4/FANCQ coding mutations to hereditary breast cancer in Central and Eastern Europe is likely to be small.

Highlights

An individual’s breast cancer risk is shaped by inherited variation in genes that normally ensure genome stability through their function in DNA damage recognition and repair
We investigated the mutational spectrum of the ERCC4/FANCQ coding sequence in a series of German or Byelorussian patients with familial breast cancer
The p.R415Q allele tended to associate with breast cancer in the Hannover Breast Cancer Study (HaBCS) series, though with a protective effect of the rare allele (Table 2)

Summary

Introduction

An individual’s breast cancer risk is shaped by inherited variation in genes that normally ensure genome stability through their function in DNA damage recognition and repair. This includes the resolution of deleterious DNA structures that result as a consequence of damage or from abnormal replication and recombination intermediates. The proteins ERCC4 ( known as XPF or FANCQ) and ERCC1 form a heterodimeric structurespecific endonuclease that promotes DNA cleavage at singlestranded/double-stranded junctions as a prerequisite to the removal of structures resulting from DNA intra- and interstrand crosslinks [1,2,3]. ERCC4 activity is regulated by SLX4, a coordinator of structure-specific endonucleases required for the resolution of Holliday junctions and interstrand crosslink repair [5]. ERCC4 is a versatile protein that is required for different types of DNA repair

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Results

Conclusion