The BRCA2 R2645G variant increases DNA binding and induces hyper-recombination.

BRCA2 tumor suppressor protein ensures genome integrity by mediating DNA repair via homologous recombination (HR). This function is executed in part by its canonical DNA binding domain located at the C-terminus (BRCA2CTD), the only folded domain of the protein. Most germline pathogenic missense variants are located in this highly conserved region which binds to single-stranded DNA (ssDNA) and to the acidic protein DSS1. These interactions are essential for the HR function of BRCA2. Here, we report that the variant R2645G, identified in breast cancer and located at the DSS1 interface, unexpectedly increases the ssDNA binding activity of BRCA2CTDin vitro. Human cells expressing this variant display a hyper-recombination phenotype, chromosomal instability in the form of chromatid gaps when exposed to DNA damage, and increased PARP inhibitor sensitivity. In mouse embryonic stem cells (mES), this variant alters viability and confers sensitivity to cisplatin and Mitomycin C. These results suggest that BRCA2 interaction with ssDNA needs to be tightly regulated to limit HR and prevent chromosomal instability and we propose that this control mechanism involves DSS1. Given that several missense variants located within this region have been identified in breast cancer patients, these findings might have clinical implications for carriers.

Replication gap suppression depends on the double-strand DNA binding activity of BRCA2.

Replication stress (RS) is a major source of genomic instability and is intrinsic to cancer cells. RS is also the consequence of chemotherapeutic drugs for treating cancer. However, adaptation to RS is also a mechanism of resistance to chemotherapy. BRCA2 deficiency results in replication stress in human cells. BRCA2 protein's main functions include DNA repair by homologous recombination (HR) both at induced DNA double-strand breaks (DSB) and spontaneous replicative lesions. At stalled replication forks, BRCA2 protects the DNA from aberrant nucleolytic degradation and is thought to limit the appearance of ssDNA gaps by arresting replication and via post-replicative HR. However, whether and how BRCA2 acts to limit the formation of ssDNA gaps or mediate their repair, remains ill-defined. Here, we use breast cancer variants affecting different domains of BRCA2 to shed light on this function. We demonstrate that the N-terminal DNA binding domain (NTD), and specifically, its dsDNA binding activity, is required to prevent and repair/fill-in ssDNA gaps upon nucleotide depletion but not to limit PARPi-induced ssDNA gaps. Thus, these findings suggest that nucleotide depletion and PARPi trigger gaps via distinct mechanisms and that the NTD of BRCA2 prevents nucleotide depletion-induced ssDNA gaps.

Monitoring Homologous Recombination Activity in Human Cells.

DNA double-strand breaks (DSBs) are among the most toxic lesions. This type of DNA damage is repaired by two major pathways, homologous recombination (HR), operating only in S/G2 cell-cycle phases and nonhomologous end joining (NHEJ) which is operative throughout the cell cycle. Because HR is a template-directed repair, it is generally less prone to errors and/or translocations than NHEJ.The HR pathway involves several effector proteins and regulators that modulate the efficiency of repair and limit the repair outside S/G2 phase. Some of the genes coding for these proteins are frequently mutated in human diseases such as cancer, and pathogenic mutations or variants identified in patients often alter the HR proficiency of the cells.This chapter describes a cell-based gene-targeting reporter assay in human cells to evaluate the repair of a site-specific DSB by HR . In it, a promoter-less fluorescent protein is encoded in a plasmid flanked by two homology arms directed to a safe-harbour locus in the genome. The expression of the fluorescent protein is driven by the promoter of the endogenous locus enabling to quantify the efficiency of HR by flow cytometry. This approach can be used to determine the requirement of certain proteins, protein domains, or protein modifications for HR . It can also be used to functionally evaluate variants of the genes encoding these proteins such as BRCA1, BRCA2, RAD51C, and PALB2; which may help assess their pathogenicity. Here, we use the homologous recombination mediator BRCA2 to illustrate the assay.