Supplementary Figure 3. Classification of the 42 purified mutated BRCT domains as a function of their thermostability as measured using a high throughput fluorescence assay. from Combining Homologous Recombination and Phosphopeptide-binding Data to Predict the Impact of BRCA1 BRCT Variants on Cancer Risk
posted on 2023-04-03, 17:28authored byAmbre Petitalot, Elodie Dardillac, Eric Jacquet, Naima Nhiri, Josée Guirouilh-Barbat, Patrick Julien, Isslam Bouazzaoui, Dorine Bonte, Jean Feunteun, Jeff A. Schnell, Philippe Lafitte, Jean-Christophe Aude, Catherine Noguès, Etienne Rouleau, Rosette Lidereau, Bernard S. Lopez, Sophie Zinn-Justin, Sandrine M. Caputo
The black bar corresponds to WT BRCA1, the blue bars to VUS of classes 1 and 2, the grey bars to VUS of class 3 and the red bars to VUS of classes 4 and 5. Bars boxed in green correspond to mutants that are defective in phosphopeptide-binding, as observed using fluorescence based thermal shift assays. HR- marks VUS that are HR-defective.
Funding
National Cancer Institute
INCa
DGOS
History
ARTICLE ABSTRACT
BRCA1 mutations have been identified that increase the risk of developing hereditary breast and ovarian cancers. Genetic screening is now offered to patients with a family history of cancer, to adapt their treatment and the management of their relatives. However, a large number of BRCA1 variants of uncertain significance (VUS) are detected. To better understand the significance of these variants, a high-throughput structural and functional analysis was performed on a large set of BRCA1 VUS. Information on both cellular localization and homology-directed DNA repair (HR) capacity was obtained for 78 BRCT missense variants in the UMD-BRCA1 database and measurement of the structural stability and phosphopeptide-binding capacities was performed for 42 mutated BRCT domains. This extensive and systematic analysis revealed that most characterized causal variants affect BRCT-domain solubility in bacteria and all impair BRCA1 HR activity in cells. Furthermore, binding to a set of 5 different phosphopeptides was tested: all causal variants showed phosphopeptide-binding defects and no neutral variant showed such defects. A classification is presented on the basis of mutated BRCT domain solubility, phosphopeptide-binding properties, and VUS HR capacity. These data suggest that HR-defective variants, which present, in addition, BRCT domains either insoluble in bacteria or defective for phosphopeptide binding, lead to an increased cancer risk. Furthermore, the data suggest that variants with a WT HR activity and whose BRCT domains bind with a WT affinity to the 5 phosphopeptides are neutral. The case of variants with WT HR activity and defective phosphopeptide binding should be further characterized, as this last functional defect might be sufficient per se to lead to tumorigenesis.
The analysis of the current study on BRCA1 structural and functional defects on cancer risk and classification presented may improve clinical interpretation and therapeutic selection.