Sylvia De Brakeleer

Cancer predisposing missense and protein truncating BARD1 mutations in non‐BRCA1 or BRCA2 breast cancer families

Fifteen years ago BRCA1 and BRCA2 were reported as high penetrant breast cancer predisposing genes. However, mutations in these genes are found in only a fraction of high risk families. BARD1 is a candidate breast cancer gene, but only a limited number of missense mutations with rather unclear pathogenic consequences have been reported.We screened 196 high risk breast cancer families for the occurrence of BARD1 variants. All genetic variants were analyzed using clinical information as well as IN SILICO predictive tools, including protein modeling. We found three candidate pathogenic mutations in seven families including a first case of a protein truncating mutation (p.Glu652fs) removing the entire second BRCT domain of BARD1. In conclusion, we provide evidence for an increased breast cancer risk associated to specific BARD1 germline mutations. However, these BARD1 mutations occur in a minority of hereditary breast cancer families. ©2010 Wiley‐Liss, Inc.

Correlation of EGFR, IDH1 and PTEN status with the outcome of patients with recurrent glioblastoma treated in a phase II clinical trial with the EGFR-blocking monoclonal antibody cetuximab

Mutation and gene amplification of the epithelial growth factor receptor (EGFR) is one of the most common genetic alterations in glioblastoma (GB). EGFR is, therefore, an attractive molecular target for the treatment of GB. EGFR-targeted therapies however have been largely ineffective in clinical trials. In this study, we investigated the correlation between the EGFR gene amplification status, expression of the EGFR variant III (EGFRvIII) and EGFR variant IV (EGFRvIV) mutations, expression of the phosphatase and tensin homologue gene on chromosome 10 (PTEN) and mutation of the isocitrate dehydrogenase 1 (IDH1) gene and the survival of patients suffering from recurrent glioblastoma who were treated with the EGFR-targeted monoclonal antibody cetuximab in a prospective phase II clinical trial. EGFR amplification was detected in 19 out of 35 GB (54%), EGFRvIII expression in 11 (31.4%) and EGFRvIV expression in 7 (20%). The EGFRvIII and EGFRvIV mutations were exclusively found in GB with EGFR amplification and were almost mutually exclusive with IDH1 mutation (EGFRvIII mutation was found in 1 out of 11 GB with an IDH1 mutation). Patients with an EGFR amplification lacking EGFRvIII expression had a significantly superior progression free survival (PFS) and a numerical better overall survival (OS) following treatment with cetuximab [median PFS 3.03 vs. 1.63 months (p=0.006); median OS 5.57 vs. 3.97 months (p=0.12)]. Within the subgroup of patients with EGFR amplification, patients with EGFRvIII positive glioblastoma had a worse survival [median PFS 1.63 vs. 3.03 months (p=0.01); median OS 3.27 vs. 5.57 months (p=0.08)]. Our observations indicate that the type of EGFR mutation may determine the outcome of GB patients treated with cetuximab. Prospective investigation of both the EGFR amplification and mutation status in clinical trials with EGFR-targeted therapies for GB is indicated.

Non-V600 BRAF mutations recurrently found in lung cancer predict sensitivity to the combination of Trametinib and Dabrafenib

Approximately half of BRAF-mutated Non-small cell lung cancers (NSCLCs) harbor a non-V600 BRAF mutation, accounting for ∼40,000 annual deaths worldwide. Recent studies have revealed the benefits of combined targeted therapy with a RAF-inhibitor (Dabrafenib) and a MEK-inhibitor (Trametinib) in treating V600 BRAF mutant cancers, including NSCLC. In contrast, sensitivity of non-V600 BRAF mutations to these inhibitors is not documented. Non-V600 mutations can either increase or impair BRAF kinase activity. However, impaired BRAF kinases can still activate the ERK pathway in a CRAF-dependent manner. Herein, beyond describing a cohort of BRAF mutant NSCLC patients and functionally analyzing 13 tumor-derived BRAF mutations, we demonstrate that both types of non-V600 BRAF mutations can be sensitive to clinically relevant doses of Dabrafenib and Trametinib in HEK293T cells, in lung epithelial cellular model (BEAS-2B) and in human cancer cell lines harboring non-V600 BRAF mutations. ERK activity induced by both types of these mutations is further reduced by combinatorial drug treatment. Moreover, the combination leads to more prolonged ERK inhibition and has anti-proliferative and pro-apoptotic effects in cells harboring both types of non-V600 BRAF mutations. This study provides a basis for the clinical exploration of non-V600 BRAF mutant lung cancers upon treatment with Trametinib and Dabrafenib.

Hereditary breast cancer: from bench to bedside.

Purpose of review The proportion of breast cancers directly attributable to determinant hereditary factors is estimated to be 5–10%. A number of recent findings with regard to hereditary breast cancer should affect the criteria and scope of routine genetic testing and, soon, breast cancer therapy. Recent findings The number of genes causing genetic cancer has expanded, mostly with genes that encode proteins that function in the BRCA1/2 pathways. The risk level associated with some genes is still under investigation, but is high for specific mutations. Some mutant alleles occur frequently, some are rare. High-throughput technologies will progressively allow investigating all genes involved in genetic (breast) cancer risks in all individuals for whom this information could be relevant. This and the emerging novel treatment options specific for cancers in mutation carriers will oblige us to progressively drop all currently used selection criteria such as familial phenotype for genomic testing. A major challenge remains the effective penetration of this knowledge in the professional and lay community, the broad application and financing of this high-throughput technology, and the identification of as yet unknown breast cancer predisposition genes. Summary The assessment of breast cancer predisposition genes, previously only an optional predictive genetic test, is growing in importance as it also becomes a therapeutic predictive test.

Systematic Detection of Pathogenic Alu Element Insertions in NGS-Based Diagnostic Screens: The BRCA1/BRCA2 Example

Pathogenic Alu element insertions are rarely reported, whereas their occurrence is expected to be much higher. Alu containing alleles are usually out‐competed during the PCR process and consequently undetectable with the classical screening methods. However, with the introduction of the next generation sequencing (NGS) technology in the diagnostic field, new opportunities are emerging. NGS data for a particular genomic region can be seen as the summation of all the individual sequences (reads) obtained for that region and no longer as the mean of this sum as it is the case for traditional Sanger sequencing. Because each single read covering that region is expected to be generated from a different template molecule, the presence of one single mutant read must theoretically be sufficient to identify the mutation. However, generation and identification of mutant reads bearing Alu insertions remains challenging and several wet/dry bench parameters need to be optimized. Hereby we present the proof of principle of a NGS‐based mutation screening procedure allowing the detection of inherited Alu insertions within any predefined sequence by investigating 2 cases: c.1739_1740insAlu in BRCA1 and c.156_157insAlu in BRCA2.

An alternative model for (breast) cancer predisposition

While environmental factors can greatly increase cancer risk, it is clear that an individual’s genetic constitution has strong impact on tumor formation. Hereby we present an alternative cancer predisposition model built on the assumption that efficiencies of DNA maintenance mechanisms in normal cells are similar but not identical for each person. Small variations in an individual’s genetic constitution may result in slightly increased genomic instability and generate typical mutational signatures in normal cells. With recent and expected advances in the next-generation sequencing field, qualitative and quantitative establishment of such mutational signatures in normal tissue must become feasible, and may meanwhile provide a more accurate estimation of individual cancer risks, even in persons without familial antecedents. An additional advantage of this approach is that cancer risk assessment will not strictly rely on the individual’s genetic identity, but will also consider other factors (e.g., environmental and age) that can affect genomic integrity.