BARD1 regulates BRCA1-mediated transactivation of the p21WAF1/CIP1 and Gadd45 promoters.

BRCA1 regulates gene transcription as part of its tumor suppressor function. Prior studies on BRCA1 transactivation did not account for the impact of its binding partner, BARD1. Here we tested the effect of BARD1 on BRCA1 transactivation of the p21 and Gadd45 promoters. We show that BARD1 promoted nuclear accumulation of BRCA1, but repressed BRCA1-mediated transactivation by up to 75% in transfected cells normalized for nuclear BRCA1 levels. The BRCA1 (C61G) RING mutant transactivation function was not regulated by BARD1. We propose that BARD1 reduces BRCA1 transcriptional activity, and that this at least partly involves BRCA1/BARD1 E3 ubiquitin ligase activity, which is disrupted by the C61G mutation.

Cdk1/Erk2- and Plk1-dependent phosphorylation of a centrosome protein, Cep55, is required for its recruitment to midbody and cytokinesis.

Centrosomes in mammalian cells have recently been implicated in cytokinesis; however, their role in this process is poorly defined. Here, we describe a human coiled-coil protein, Cep55 (centrosome protein 55 kDa), that localizes to the mother centriole during interphase. Despite its association with gamma-TuRC anchoring proteins CG-NAP and Kendrin, Cep55 is not required for microtubule nucleation. Upon mitotic entry, centrosome dissociation of Cep55 is triggered by Erk2/Cdk1-dependent phosphorylation at S425 and S428. Furthermore, Cep55 locates to the midbody and plays a role in cytokinesis, as its depletion by siRNA results in failure of this process. S425/428 phosphorylation is required for interaction with Plk1, enabling phosphorylation of Cep55 at S436. Cells expressing phosphorylation-deficient mutant forms of Cep55 undergo cytokinesis failure. These results highlight the centrosome as a site to organize phosphorylation of Cep55, enabling it to relocate to the midbody to function in mitotic exit and cytokinesis.

BARD1 regulates BRCA1 apoptotic function by a mechanism involving nuclear retention.

BRCA1 is involved in maintaining genomic integrity and, as a regulator of the G2/M checkpoint, contributes to DNA repair and cell survival. The overexpression of BRCA1 elicits diverse cellular responses including apoptosis due to the stimulation of specific signaling pathways. BRCA1 is normally regulated by protein turnover, but is stabilized by BARD1 which can recruit BRCA1 to the nucleus to form a ubiquitin E3 ligase complex involved in DNA repair or cell survival. Here, we identify BARD1 as a regulator of BRCA1-dependent apoptosis. Using transfected MCF-7 breast cancer cells, we found that BRCA1-induced apoptosis was independent of p53 and was stimulated by BRCA1 nuclear export. Conversely, BARD1 reduced BRCA1-dependent apoptosis by a mechanism involving nuclear sequestration. Regulation of apoptosis by BARD1 was reduced by BRCA1 cancer mutations that disrupt Ub ligase function. Transfection of BRCA1 N-terminal peptides that disrupted the cellular BRCA1-BARD1 interaction caused a loss of nuclear BRCA1 that correlated with increased apoptosis in single cell assays, but did not alter localization or expression of endogenous BARD1. Reducing BARD1 levels by siRNA caused a small increase in apoptosis. Our findings identify a novel apoptosis inhibitory function of BARD1 and suggest that nuclear retention of BRCA1-BARD1 complexes contributes to both DNA repair and cell survival.

BRCA1-BARD1 complexes are required for p53Ser-15 phosphorylation and a G1/S arrest following ionizing radiation-induced DNA damage.

BRCA1 is a major player in the DNA damage response. This is evident from its loss, which causes cells to become sensitive to a wide variety of DNA damaging agents. The major BRCA1 binding partner, BARD1, is also implicated in the DNA damage response, and recent reports indicate that BRCA1 and BARD1 co-operate in this pathway. In this report, we utilized small interfering RNA to deplete BRCA1 and BARD1 to demonstrate that the BRCA1-BARD1 complex is required for ATM/ATR (ataxia-telangiectasia-mutated/ATM and Rad3-related)-mediated phosphorylation of p53(Ser-15) following IR- and UV radiation-induced DNA damage. In contrast, phosphorylation of a number of other ATM/ATR targets including H2AX, Chk2, Chk1, and c-jun does not depend on the presence of BRCA1-BARD1 complexes. Moreover, prior ATM/ATR-dependent phosphorylation of BRCA1 at Ser-1423 or Ser-1524 regulates the ability of ATM/ATR to phosphorylate p53(Ser-15) efficiently. Phosphorylation of p53(Ser-15) is necessary for an IR-induced G(1)/S arrest via transcriptional induction of the cyclin-dependent kinase inhibitor p21. Consistent with these data, repressing p53(Ser-15) phosphorylation by BRCA1-BARD1 depletion compromises p21 induction and the G(1)/S checkpoint arrest in response to IR but not UV radia-tion. These findings suggest that BRCA1-BARD1 complexes act as an adaptor to mediate ATM/ATR-directed phosphorylation of p53, influencing G(1)/S cell cycle progression after DNA damage.

Exocytosis of a complement component C3-like protein by tunicate hemocytes.

This study investigates the exocytic responses of invertebrate hemocytes to pathogen-associated antigens. It demonstrates that a homologue of complement component C3, a key defensive protein of the innate immune system, is expressed by phagocytic hemocytes (non-refractile vacuolated cells) of the tunicate, Styela plicata. C3-like molecules are localized in sub-cellular vesicles and are rapidly exocytosed after stimulation with bacterial, fungal or algal cell surface molecules. Signal transduction analysis indicated that the induced secretion of C3-like molecules is mediated by a G-protein dependent signaling pathway, which modulates tubulin microtubules. All of this evidence indicates that hemocytes can contribute to host defense responses by rapidly exocytosing C3-like proteins at sites of infection.

Nuclear-cytoplasmic shuttling of BARD1 contributes to its proapoptotic activity and is regulated by dimerization with BRCA1.

The breast cancer-associated protein, BARD1, colocalizes with BRCA1 in nuclear foci in the S phase and after DNA damage, and the two proteins form a stable heterodimer implicated in DNA repair, protein ubiquitination, and control of mRNA processing. BARD1 has a BRCA1-independent proapoptotic activity; however, little is known about its regulation. Here, we show that BARD1 localization and apoptotic activity are regulated by nuclear-cytoplasmic shuttling. We identified a functional CRM1-dependent nuclear export sequence (NES) near the N-terminal RING domain of BARD1. The NES forms part of the BRCA1 dimerization domain, and coexpression of BRCA1 resulted in masking of the NES and nuclear retention of BARD1. In transient expression assays, BARD1 apoptotic activity was stimulated by nuclear export, and both apoptotic function and nuclear export were markedly reduced by BRCA1. Similar findings were obtained for endogenous BARD1. Silencing BRCA1 expression by siRNA, or disrupting the endogenous BARD1/BRCA1 interaction by peptide competition caused a reduction in BARD1 nuclear localization and foci formation, and increased the level of cytoplasmic BARD1 correlating with increased apoptosis. Our findings suggest that BRCA1/BARD1 heterodimer formation is important for optimal nuclear targeting of BARD1 and its role in DNA repair and cell survival.

Regulation of tumor suppressors by nuclear-cytoplasmic shuttling.

Tumor suppressor proteins control the proliferation and survival of normal cells; consequently, their inactivation by gene mutations can initiate or drive cancer progression. Most tumor suppressors have been identified by genetic screening, and in many cases their function and regulation are poorly understood. Ten such proteins were recently shown to contain nuclear transport signals that facilitate their "shuttling" between the nucleus and cytoplasm. This type of dynamic intracellular movement not only regulates protein localization, but also often impacts on function. Here, we review the pathways by which tumor suppressors such as APC, p53, VHL, and BRCA1 cross the nuclear envelope and the impact of regulated nuclear import/export on protein function.

BARD1 induces BRCA1 intranuclear foci formation by increasing RING-dependent BRCA1 nuclear import and inhibiting BRCA1 nuclear export.

BRCA1 is a tumor suppressor with several important nuclear functions. BRCA1 has no known cytoplasmic functions. We show here that the two previously identified nuclear localization signals (NLSs) are insufficient for nuclear localization of BRCA1 due to the opposing action of an NH2-terminal nuclear export signal. In transfected breast cancer cells, BRCA1 nuclear localization requires both the NLSs and NH2-terminal RING domain region; mutating either of these sequences shifts BRCA1 to the cytoplasm. The BRCA1 RING element mediates nuclear import via association with BARD1, and this is not affected by cancer-associated RING mutations. Moreover, BARD1 directly masks the BRCA1 nuclear export signal, and the resulting block to nuclear export is requisite for efficient import and nuclear localization of ectopic and endogenous BRCA1. Our results explain why BRCA1 exon 11 splice variants, which lack the NLSs but retain the RING domain, are frequently detected in the nucleus and in nuclear foci in vivo. In fact, co-expression of BARD1 promoted formation of DNA damage-induced nuclear foci comprising ectopic wild-type or NLS-deficient BRCA1, implicating BARD1 in nuclear targeting of BRCA1 for DNA repair. Our identification of BARD1 as a BRCA1 nuclear chaperone has regulatory implications for its reported effects on BRCA1 protein stability, ubiquitin ligase activity, and DNA repair.