A cancer-associated BRCA2 mutation reveals masked nuclear export signals controlling localization.

Germline missense mutations affecting a single BRCA2 allele predispose humans to cancer. Here we identify a protein-targeting mechanism that is disrupted by the cancer-associated mutation, BRCA2(D2723H), and that controls the nuclear localization of BRCA2 and its cargo, the recombination enzyme RAD51. A nuclear export signal (NES) in BRCA2 is masked by its interaction with a partner protein, DSS1, such that point mutations impairing BRCA2-DSS1 binding render BRCA2 cytoplasmic. In turn, cytoplasmic mislocalization of mutant BRCA2 inhibits the nuclear retention of RAD51 by exposing a similar NES in RAD51 that is usually obscured by the BRCA2-RAD51 interaction. Thus, a series of NES-masking interactions localizes BRCA2 and RAD51 in the nucleus. Notably, BRCA2(D2723H) decreases RAD51 nuclear retention even when wild-type BRCA2 is also present. Our findings suggest a mechanism for the regulation of the nucleocytoplasmic distribution of BRCA2 and RAD51 and its impairment by a heterozygous disease-associated mutation.

Tetraploidy in BRCA2 breast tumours.

Tetraploidy and aneuploidy can be caused by cell division errors and are frequently observed in many human carcinomas. We have recently reported delayed cytokinesis in primary human fibroblasts from BRCA2 mutation carriers, implying a function for the BRCA2 tumour suppressor in completion of cell division. Here, we address ploidy aberrations in breast tumours derived from BRCA2 germline mutation carriers. Ploidy aberrations were evaluated from flow cytometry histograms on selected breast tumour samples (n=236), previously screened for local BRCA mutations. The ploidy between BRCA2-mutated (n=71) and matched sporadic (n=165) cancers was compared. Differences in ploidy distribution were examined with respect to molecular tumour subtypes, previously defined by immunohistochemistry on tissue microarray sections. Tetraploidy was significantly 3 times more common in BRCA2 breast cancers than sporadic. However, no differences were found in the overall ploidy distribution between BRCA2-mutation carriers and non-carriers. In BRCA2 cancers, tetraploidy was associated with luminal characteristics. The increased frequency of tetraploidy in BRCA2 associated cancers may be linked to cell division errors, particularly cytokinesis. Additionally, tetraploidy emerges predominantly in BRCA2 breast cancers displaying luminal rather than triple-negative phenotypes.

Centriole movements in mammalian epithelial cells during cytokinesis.

BACKGROUND: In cytokinesis, when the cleavage furrow has been formed, the two centrioles in each daughter cell separate. It has been suggested that the centrioles facilitate and regulate cytokinesis to some extent. It has been postulated that termination of cytokinesis (abscission) depends on the migration of a centriole to the intercellular bridge and then back to the cell center. To investigate the involvement of centrioles in cytokinesis, we monitored the movements of centrioles in three mammalian epithelial cell lines, HeLa, MCF 10A, and the p53-deficient mouse mammary tumor cell line KP-7.7, by time-lapse imaging. Centrin1-EGFP and alpha-Tubulin-mCherry were co-expressed in the cells to visualize respectively the centrioles and microtubules. RESULTS: Here we report that separated centrioles that migrate from the cell pole are very mobile during cytokinesis and their movements can be characterized as 1) along the nuclear envelope, 2) irregular, and 3) along microtubules forming the spindle axis. Centriole movement towards the intercellular bridge was only seen occasionally and was highly cell-line dependent. CONCLUSIONS: These findings show that centrioles are highly mobile during cytokinesis and suggest that the repositioning of a centriole to the intercellular bridge is not essential for controlling abscission. We suggest that centriole movements are microtubule dependent and that abscission is more dependent on other mechanisms than positioning of centrioles.

BRCA2 heterozygosity delays cytokinesis in primary human fibroblasts.

BACKGROUND: Inherited mutations in the tumour suppressor gene BRCA2 greatly increase the risk of developing breast, ovarian and other types of cancers. So far, most studies have focused on the role of BRCA-pathways in the maintenance of genomic stability. In this study we investigated the potential role of the BRCA2 protein in cytokinesis in unmodified primary human fibroblast carrying a heterozygous mutation in the BRCA2 gene. METHODS: Cell divisions were monitored with time lapse live-cell imaging. BRCA2 mRNA expression levels in BRCA2+/- and BRCA2+/+ cells were quantified with quantitative real-time polymerase chain reaction (qRT-PCR). To investigate the localization of the BRCA2 protein during cytokinesis, immunofluorescence staining using antibody directed against BRCA2 was carried out. Immunofluorescence staining was performed directly after live-cell imaging and cells with delayed cytokinesis, of which the co-ordinates were saved, were automatically repositioned and visualized. RESULTS: We demonstrate that unmodified primary human fibroblasts derived from heterozygous BRCA2 mutation carriers show significantly prolonged cytokinesis. A Subset of the BRCA2+/- cells had delayed cytokinesis (40 min or longer) making the mean cell division time 6 min longer compared with BRCA2+/+ cells, 33 min versus 27 min, respectively. Lower BRCA2 mRNA expression levels were observed in the BRCA2 heterozygous samples compared with the BRCA2 wild type samples. The BRCA2 protein localizes and accumulates to the midbody during cytokinesis, and no difference was detected in distribution and localization of the protein between BRCA2+/- and BRCA2+/+ samples or cells with delayed cytokinesis and normal division time. CONCLUSIONS: The delayed cytokinesis phenotype of the BRCA2 heterozygous cells and localization of the BRCA2 protein to the midbody confirms that BRCA2 plays a role in cytokinesis. Our observations indicate that in a subset of cells the presence of only one wild type BRCA2 allele is insufficient for efficient cytokinesis.