A Recurrent ERCC3 Truncating Mutation Confers Moderate Risk for Breast Cancer.

Known gene mutations account for approximately 50% of the hereditary risk for breast cancer. Moderate and low penetrance variants, discovered by genomic approaches, account for an as-yet-unknown proportion of the remaining heritability. A truncating mutation c.325C>T:p.Arg109* (R109X) in the ATP-dependent helicase ERCC3 was observed recurrently among exomes sequenced in BRCA wild-type, breast cancer-affected individuals of Ashkenazi Jewish ancestry. Modeling of the mutation in ERCC3-deficient or CRISPR/Cas9-edited cell lines showed a consistent pattern of reduced expression of the protein and concomitant hypomorphic functionality when challenged with UVC exposure or treatment with the DNA alkylating agent IlludinS. Overexpressing the mutant protein in ERCC3-deficient cells only partially rescued their DNA repair-deficient phenotype. Comparison of frequency of this recurrent mutation in over 6,500 chromosomes of breast cancer cases and 6,800 Ashkenazi controls showed significant association with breast cancer risk (ORBC = 1.53, ORER+ = 1.73), particularly for the estrogen receptor-positive subset (P < 0.007). SIGNIFICANCE A functionally significant recurrent ERCC3 mutation increased the risk for breast cancer in a genetic isolate. Mutated cell lines showed lower survival after in vitro exposure to DNA-damaging agents. Thus, similar to tumors arising in the background of homologous repair defects, mutations in nucleotide excision repair genes such as ERCC3 could constitute potential therapeutic targets in a subset of hereditary breast cancers. Cancer Discov; 6(11); 1267-75. ©2016 AACR.This article is highlighted in the In This Issue feature, p. 1197.

[1]  Kenneth Offit,et al.  Two Decades After BRCA: Setting Paradigms in Personalized Cancer Care and Prevention , 2014, Science.

[2]  H. Gaylord,et al.  AMERICAN ASSOCIATION FOR CANCER RESEARCH. , 1913, California state journal of medicine.

[3]  D. Cheo,et al.  Ultraviolet B radiation-induced skin cancer in mice defective in the Xpc, Trp53, and Apex (HAP1) genes: genotype-specific effects on cancer predisposition and pathology of tumors. , 2000, Cancer research.

[4]  Kenneth Offit,et al.  Functional and genomic approaches reveal an ancient CHEK2 allele associated with breast cancer in the Ashkenazi Jewish population. , 2005, Human molecular genetics.

[5]  A. Meindl,et al.  RAD51Cdeletion screening identifies a recurrent gross deletion in breast cancer and ovarian cancer families , 2013, Breast Cancer Research.

[6]  J. Hoeijmakers,et al.  Premature aging and cancer in nucleotide excision repair-disorders. , 2011, DNA repair.

[7]  P. Chambon,et al.  DNA repair helicase: a component of BTF2 (TFIIH) basic transcription factor. , 1993, Science.

[8]  M. Kelner,et al.  Structure-activity relationships of illudins: analogs with improved therapeutic index. , 1992 .

[9]  H. Pospiech,et al.  Heterozygous mutations in PALB2 cause DNA replication and damage response defects , 2013, Nature Communications.

[10]  M. Piccart,et al.  An update on PARP inhibitors—moving to the adjuvant setting , 2015, Nature Reviews Clinical Oncology.

[11]  Katri Pylkäs,et al.  A recurrent mutation in PALB2 in Finnish cancer families , 2007, Nature.

[12]  R. Scott,et al.  Clinical heterogeneity within xeroderma pigmentosum associated with mutations in the DNA repair and transcription gene ERCC3. , 1994, American journal of human genetics.

[13]  V. Natale,et al.  H 2 AX phosphorylation within the G 1 phase after UV irradiation depends on nucleotide excision repair and not DNA double-strand breaks , 2006 .

[14]  Yate-Ching Yuan,et al.  The Novel Ribonucleotide Reductase Inhibitor COH29 Inhibits DNA Repair In Vitro , 2015, Molecular Pharmacology.

[15]  P. Silberstein,et al.  Hereditary cancer syndromes: utilizing DNA repair deficiency as therapeutic target , 2016, Familial Cancer.

[16]  J. Hoeijmakers,et al.  An Xpb Mouse Model for Combined Xeroderma Pigmentosum and Cockayne Syndrome Reveals Progeroid Features upon Further Attenuation of DNA Repair , 2008, Molecular and Cellular Biology.

[17]  V. Natale,et al.  H2AX phosphorylation within the G1 phase after UV irradiation depends on nucleotide excision repair and not DNA double-strand breaks. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[18]  G. Boivin,et al.  Enhanced Tumor Formation in Mice Heterozygous for Blm Mutation , 2002, Science.

[19]  F. Couch,et al.  Association of a HOXB13 variant with breast cancer. , 2012, New England Journal of Medicine.

[20]  K. Sperling,et al.  Nijmegen breakage syndrome: consequences of defective DNA double strand break repair , 1999, BioEssays : news and reviews in molecular, cellular and developmental biology.

[21]  J. Egly,et al.  TFIIH subunit alterations causing xeroderma pigmentosum and trichothiodystrophy specifically disturb several steps during transcription. , 2015, American journal of human genetics.

[22]  R. Brosh DNA helicases involved in DNA repair and their roles in cancer , 2013, Nature Reviews Cancer.

[23]  F. Alt,et al.  Histone H2AX A Dosage-Dependent Suppressor of Oncogenic Translocations and Tumors , 2003, Cell.

[24]  Patrick Neven,et al.  Genome-wide association analysis of more than 120,000 individuals identifies 15 new susceptibility loci for breast cancer , 2015 .

[25]  E. Friedberg,et al.  Age-dependent spontaneous mutagenesis in Xpc mice defective in nucleotide excision repair , 2000, Oncogene.

[26]  M. King,et al.  The APCI1307K allele and breast cancer risk. , 1998, Nature genetics.

[27]  J. Groden,et al.  Crosslinks and crosstalk: human cancer syndromes and DNA repair defects. , 2004, Cancer cell.

[28]  E. Seemanová An increased risk for malignant neoplasms in heterozygotes for a syndrome of microcephaly, normal intelligence, growth retardation, remarkable facies, immunodeficiency and chromosomal instability. , 1990, Mutation research.

[29]  Sikandar G. Khan,et al.  Phenotypic heterogeneity in the XPB DNA helicase gene (ERCC3): xeroderma pigmentosum without and with Cockayne syndrome , 2006, Human mutation.

[30]  Kenneth Offit,et al.  Sequencing an Ashkenazi reference panel supports population-targeted personal genomics and illuminates Jewish and European origins , 2014, Nature Communications.

[31]  S. Linn,et al.  DDB2 gene disruption leads to skin tumors and resistance to apoptosis after exposure to ultraviolet light but not a chemical carcinogen , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[32]  T. Ried,et al.  H2AX Haploinsufficiency Modifies Genomic Stability and Tumor Susceptibility , 2003, Cell.

[33]  S. Powell,et al.  Molecular Pathways: Understanding the Role of Rad52 in Homologous Recombination for Therapeutic Advancement , 2012, Clinical Cancer Research.

[34]  Nazneen Rahman,et al.  Gene-panel sequencing and the prediction of breast-cancer risk. , 2015, The New England journal of medicine.

[35]  D. Goldstein,et al.  Genic Intolerance to Functional Variation and the Interpretation of Personal Genomes , 2013, PLoS genetics.

[36]  C. D. De Zeeuw,et al.  An Xpd mouse model for the combined xeroderma pigmentosum/Cockayne syndrome exhibiting both cancer predisposition and segmental progeria. , 2006, Cancer cell.

[37]  S. Bojesen,et al.  CHEK2*1100delC genotyping for clinical assessment of breast cancer risk: meta-analyses of 26,000 patient cases and 27,000 controls. , 2008, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[38]  J. Rosen,et al.  Chk1 is haploinsufficient for multiple functions critical to tumor suppression. , 2004, Cancer cell.