An amino-terminal motif functions as a second nuclear export sequence in BRCA1

Mutations in the breast cancer susceptibility gene 1 (BRCA1) account for a substantial percentage of familial breast and ovarian cancers. Although BRCA1 is thought to function within the nucleus, it has also been located in the cytoplasm. In addition, BRCA1 accumulates in the nucleus of cells treated with leptomycin B, an inhibitor of chromosome region maintenance 1-mediated nuclear export, indicative of its active nuclear export via this pathway. The nuclear export signal in BRCA1 has been described as consisting of amino acid residues 81-99. However, a number of other tumor suppressors have multiple nuclear export sequences, and we sought to determine whether BRCA1 did also. Here, we report that BRCA1 contains a second nuclear export sequence that comprises amino acid residues 22-30. By use of the human immunodeficiency virus-1 Rev complementation assay, this sequence was shown to confer export capability to an export-defective Rev fusion protein. The level of export activity was comparable with that of residues 81-99 comprising the previously reported nuclear export sequence in BRCA1. Mutation of leucine 28 to an alanine reduced nuclear export by approximately 75%. In MCF-7 cells stably transfected with a BRCA1 cDNA containing mutations in this novel sequence or the previously reported export sequence, BRCA1 accumulated in the nucleus. These data imply that BRCA1 contains at least two leucine-dependent nuclear export sequences.     

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.     

Differential modulation of BRCA1 and BARD1 nuclear localisation and foci assembly by DNA damage

The BRCA1/BARD1 heterodimer regulates genomic maintenance and contributes to the DNA damage checkpoint response. We previously reported that BRCA1 and BARD1 can shuttle between nucleus and cytoplasm. In this study, we evaluated the localisation patterns of BRCA1 and BARD1 in response to different types of DNA damaging agents and chemotherapeutic drugs. In MCF-7 cells, endogenous BRCA1 increased transiently in the nucleus at 2 h after ionising radiation (IR), whereas BARD1 was unaffected. IR treatment did not induce nuclear export of either protein, in contrast to previous reports. DNA damage by UV radiation, etoposide or camptothecin caused a preferential down-regulation of nuclear BARD1 at 6 h post-treatment. The UV-dependent loss of nuclear BARD1 was blocked by the proteasome inhibitor MG132, but not by leptomycin B, indicating a change in BARD1 nuclear degradation rather than nuclear export. MG132 also blocked the dispersal of BARD1/BRCA1 nuclear foci at 6 h after UV, implicating the proteasome in repair foci disassembly. In the cytoplasm, BRCA1 and BARD1 were detected at centrosomes but their distribution was not altered by DNA damage. BARD1 displayed a stronger mitochondria accumulation than BRCA1, and became phosphorylated at mitochondria in response to DNA damage. The mitotic spindle poisons vincristine and paclitaxel had no effect on BRCA1 or BARD1 subcellular distribution. We conclude that BARD1 phosphorylation, expression and localisation patterns are regulated in the nucleus and at mitochondria in response to different forms of DNA damage, contributing to the role of BRCA1/BARD1 in DNA repair and apoptotic responses.     

BRCA1 accumulates in the nucleus in response to hypoxia and TRAIL and enhances TRAIL-induced apoptosis in breast cancer cells

A major contributing factor to the development of breast cancer is decreased functional expression of breast cancer susceptibility gene 1, BRCA1. Another key contributor to tumorigenesis is hypoxia. Here we show that hypoxia increased the nuclear localization of BRCA1 in MCF-7 and MDA-MB-468 human breast cancer cell lines without changing its steady-state expression level. Nuclear accumulation of BRCA1 was not evident in MCF-12A or HMEC (human mammary epithelial cell) nonmalignant mammary epithelial cells under the same conditions. Hypoxia also increased the cell surface expression of TRAIL on MDA-MB-468 cells. Neutralization of TRAIL precluded the hypoxia-induced accumulation of BRCA1 in the nucleus, whereas exogenously administered TRAIL mimicked the effect. Treatment of MDA-MB-468 cells with TRAIL resulted in a dose- and time-dependent increase in apoptosis. Furthermore, TRAIL-induced apoptosis in HCC1937 cells, which harbor a BRCA1 mutation, increased synergistically when wild-type BRCA1 was reconstituted in the cells, and downregulation of BRCA1 expression in MDA-MB-468 cells reduced the apoptotic response to TRAIL. These data provide a novel link between hypoxia, TRAIL and BRCA1, and suggest that this relationship may be especially relevant to the potential use of TRAIL as a chemotherapeutic agent.     

Ubc9 mediates nuclear localization and growth suppression of BRCA1 and BRCA1a proteins

BRCA1 gene mutations are responsible for hereditary breast and ovarian cancers. In sporadic breast tumors, BRCA1 dysfunction or aberrant subcellular localization is thought to be common. BRCA1 is a nuclear-cytoplasm shuttling protein and the reason for cytoplasmic localization of BRCA1 in young breast cancer patients is not yet known. We have previously reported BRCA1 proteins unlike K109R and cancer-predisposing mutant C61G to bind Ubc9 and modulate ER-α turnover. In the present study, we have examined the consequences of altered Ubc9 binding and knockdown on the subcellular localization and growth inhibitory function of BRCA1 proteins. Our results using live imaging of YFP, GFP, RFP-tagged BRCA1, BRCA1a and BRCA1b proteins show enhanced cytoplasmic localization of K109 R and C61G mutant BRCA1 proteins in normal and cancer cells. Furthermore, down-regulation of Ubc9 in MCF-7 cells using Ubc9 siRNA resulted in enhanced cytoplasmic localization of BRCA1 protein and exclusive cytoplasmic retention of BRCA1a and BRCA1b proteins. These mutant BRCA1 proteins were transforming and impaired in their capacity to inhibit growth of MCF-7 and CAL51 breast cancer cells. Interestingly, cytoplasmic BRCA1a mutants showed more clonogenicity in soft agar and higher levels of expression of Ubc9 than parental MCF7 cells. This is the first report demonstrating the physiological link between cytoplasmic mislocalization of mutant BRCA1 proteins, loss of ER-α repression, loss of ubiquitin ligase activity and loss of growth suppression of BRCA1 proteins. Thus, binding of BRCA1 proteins to nuclear chaperone Ubc9 provides a novel mechanism for nuclear import and control of tumor growth.     

Characterization of BRCA1 protein targeting, dynamics, and function at the centrosome: a role for the nuclear export signal, CRM1, and Aurora A kinase

BRCA1 is a DNA damage response protein and functions in the nucleus to stimulate DNA repair and at the centrosome to inhibit centrosome overduplication in response to DNA damage. The loss or mutation of BRCA1 causes centrosome amplification and abnormal mitotic spindle assembly in breast cancer cells. The BRCA1-BARD1 heterodimer binds and ubiquitinates γ-tubulin to inhibit centrosome amplification and promote microtubule nucleation; however regulation of BRCA1 targeting and function at the centrosome is poorly understood. Here we show that both N and C termini of BRCA1 are required for its centrosomal localization and that BRCA1 moves to the centrosome independently of BARD1 and γ-tubulin. Mutations in the C-terminal phosphoprotein-binding BRCT domain of BRCA1 prevented localization to centrosomes. Photobleaching experiments identified dynamic (60%) and immobilized (40%) pools of ectopic BRCA1 at the centrosome, and these are regulated by the nuclear export receptor CRM1 (chromosome region maintenance 1) and BARD1. CRM1 mediates nuclear export of BRCA1, and mutation of the export sequence blocked BRCA1 regulation of centrosome amplification in irradiated cells. CRM1 binds to undimerized BRCA1 and is displaced by BARD1. Photobleaching assays implicate CRM1 in driving undimerized BRCA1 to the centrosome and revealed that when BRCA1 subsequently binds to BARD1, it is less well retained at centrosomes, suggesting a mechanism to accelerate BRCA1 release after formation of the active heterodimer. Moreover, Aurora A binding and phosphorylation of BRCA1 enhanced its centrosomal retention and regulation of centrosome amplification. Thus, CRM1, BARD1 and Aurora A promote the targeting and function of BRCA1 at centrosomes.     

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.     

Phosphorylated BRCA1 is predominantly located in the nucleus and mitochondria

Multiple copies of the mitochondrial genome in eukaryotic cells are organized into protein-DNA complexes called nucleoids. Mitochondrial genome repair mechanisms have been reported, but they are less well characterized than their nuclear counterparts. To expand our knowledge of mitochondrial genome maintenance, we have studied the localization of the BRCA1 protein, known to be involved in nuclear repair pathways. Our confocal and immunoelectron microscopy results show that BRCA1 is present in mitochondria of several human cancer cell lines and in primary breast and nasal epithelial cells. BRCA1 localization in mitochondria frequently overlapped that of nucleoids. Small interfering RNA-mediated knockdown of BRCA1 in human cancer cells (confirmed by Western blot) results in decreased nuclear, cytoplasmic, and mitochondrial staining after immunofluorescence microscopy, establishing the specificity of the BRCA1 immunolabeling. Furthermore, using cell fractionation, dephosphorylation, and enzyme protection experiments, we show that a 220-kDa phosphorylated isoform of BRCA1 is enriched in mitochondrial and nuclear fractions but reduced in cytoplasmic subcellular fractions. Submitochondrial fractionation confirmed the presence of BRCA1 protein in isolated mitoplasts. Because phosphorylation of BRCA1 and subsequent changes in subcellular localization are known to follow DNA damage, our data support a universal role for BRCA1 in the maintenance of genome integrity in both mitochondria and nucleus.     

BARD1 translocation to mitochondria correlates with Bax oligomerization, loss of mitochondrial membrane potential, and apoptosis

The breast cancer regulatory protein-1 (BRCA1)-associated RING domain 1 (BARD1) gene is mutated in a subset of breast/ovarian cancers. BARD1 functions as a heterodimer with BRCA1 in nuclear DNA repair. BARD1 also has a BRCA1-independent apoptotic activity. Here we investigated the link between cytoplasmic localization and apoptotic function of BARD1. We used immunofluorescence microscopy and deconvolution analysis to resolve BARD1 cytoplasmic staining patterns and detected endogenous BARD1 at mitochondria. BARD1 was also detected in mitochondrial cell fractions by immunoblotting. The targeting of BARD1 to mitochondria was modestly stimulated by DNA damage and did not require BRCA1 as indicated by RNA interference and peptide-competition experiments. Transiently expressed yellow fluorescence protein-BARD1 localized to mitochondria, and the targeting sequences were mapped to both the N and C terminus of BARD1. Ectopic yellow fluorescence protein-BARD1 induced apoptosis and loss of mitochondrial membrane potential in MCF-7 breast tumor cells. BARD1 apoptotic function was associated with stimulation of Bax oligomerization at mitochondria. This distinguishes it from BRCA1, which is pro-apoptotic but did not induce Bax oligomerization. The cancer-associated BARD1 splice-variant DeltaRIN (lacks the BRCA1 binding domain and ankyrin repeats) was recruited to mitochondria but did not stimulate apoptosis or alter membrane permeability. We propose that BARD1 has two main sites of action in its cellular response to DNA damage, the nucleus, where it promotes cell survival through DNA repair, and the mitochondria, where BARD1 regulates apoptosis.     

Nuclear targeting and cell cycle regulatory function of human BARD1

The BARD1 gene is mutated in a subset of breast and ovarian cancers, implicating BARD1 as a potential tumor suppressor. BARD1 gains a ubiquitin E3 ligase activity when heterodimerized with BRCA1, but the only known BRCA1-independent BARD1 function is a p53-dependent proapoptotic activity stimulated by nuclear export to the cytoplasm. We described previously the nuclear-cytoplasmic shuttling of BARD1, and in this study, we identify the transport sequences that target BARD1 to the nucleus and show that they are essential for BARD1 regulation of the cell cycle. We used deletion mapping and mutagenesis to define two active nuclear localization signals (NLSs) present in human BARD1 that are not conserved in rodent BARD1. Site-directed mutagenesis of the primary bipartite NLS abolished BARD1 nuclear import and caused its cytoplasmic accumulation. Using flow cytometry and 5-bromo-2-deoxyuridine incorporation assays, we discovered that transiently expressed BARD1 can elicit a p53-independent cell cycle arrest in G1 phase, and that this was abrogated by mutation of the BARD1 NLS but not by mutation of the nuclear export signal. Thus, BARD1 regulation of the cell cycle is a nuclear event and may be linked to its induced expression during mitosis and its possible involvement in the DNA damage checkpoint.     

Histone deacetylase 6 (HDAC6) deacetylates survivin for its nuclear export in breast cancer

Survivin is an oncogenic protein that is highly expressed in breast cancer and has a dual function that is dependent on its subcellular localization. In the cytosol, survivin blocks programmed cell death by inactivating caspase proteins; however, in the nucleus it facilitates cell division by regulating chromosomal movement and cytokinesis. In prior work, we showed that survivin is acetylated by CREB-binding protein (CBP), which restricts its localization to the nuclear compartment and thereby inhibits its anti-apoptotic function. Here, we identify histone deacetylase 6 (HDAC6) as responsible for abrogating CBP-mediated survivin acetylation in the estrogen receptor (ER)-positive breast cancer cell line, MCF-7. HDAC6 directly binds survivin, an interaction that is enhanced by CBP. In quiescent breast cancer cells in culture and in malignant tissue sections from ER+ breast tumors, HDAC6 localizes to a perinuclear region of the cell, undergoing transport to the nucleus following CBP activation where it then deacetylates survivin. Genetically modified mouse embryonic fibroblasts that lack mhdac6 localize survivin predominantly to the nuclear compartment, whereas wild-type mouse embryonic fibroblasts localize survivin to distinct cytoplasmic structures. Together, these data imply that HDAC6 deacetylates survivin to regulate its nuclear export, a feature that may provide a novel target for patients with ER+ breast cancer.     

BRCA1 Downregulation Leads to Premature Inactivation of Spindle Checkpoint and Confers Paclitaxel Resistance

BRCA1 germline mutations predispose women to early onset, familial breast and ovariancancer. BRCA1 has been recently implicated in the cellular response to agents that disruptthe mitotic spindle. In this report, we studied BRCA1 contribution to paclitaxel response inMCF-7 breast cancer cells. We show that MCF-7 cells transfected with BRCA1 siRNAdisplay a significant increase in resistance to paclitaxel compared with the control cells. Wenext demonstrate that down-regulation of BRCA1 reduces the mitotic index and triggerspremature cyclin B1 degradation and decrease in Cdk1 activity following paclitaxel treatment,suggesting that BRCA1 down-regulation results in precocious inactivation of the spindlecheckpoint. These findings were confirmed by showing that BRCA1 down-regulation inducespremature sister–chromatids separation in MCF-7 cells following spindle damage.Furthermore, we show that BRCA1 up-regulates the expression of the protein kinase BubR1,essential component of the functional spindle checkpoint, whose down-regulation is known toresult in paclitaxel resistance in MCF-7 cells. Altogether, our findings support the notion thatdown-regulation of BRCA1 expression mediates paclitaxel resistance through prematureinactivation of spindle checkpoint in MCF-7 breast cancer cells. They link BRCA1 to themitotic checkpoint that plays an essential role in the maintenance of chromosomal stability.     

Expression of cancer related BRCA1 missense variants decreases MMS-induced recombination in Saccharomyces cerevisiae without altering its nuclear localization

BRCA1 tumor suppressor gene is found mutated in familial breast and ovarian cancer. Most cancer related mutations were found located at the RING (Really Interesting New Gene) and at the BRCT (BRca1 C-Terminal) domain. However, 20 y after its identification, the biological role of BRCA1 and which domains are more relevant for tumor suppression are still being elucidated. We previously reported that expression of BRCA1 cancer related variants in the RING and BRCT domain increases spontaneous homologous recombination in yeast indicating that BRCA1 may interact with yeast DNA repair/recombination. To finally demonstrate whether BRCA1 interacts with yeast DNA repair, we exposed yeast cells expressing BRCA1wt, the cancer-related variants C-61G and M1775R to different doses of the alkylating agent methyl methane-sulfonate (MMS) and then evaluated the effect on survival and homologous recombination. Cells expressing BRCA1 cancer variants were more sensitive to MMS and less inducible to recombination as compared to cell expressing BRCA1wt. Moreover, BRCA1-C61G and -M1775R did not change their nuclear localization form as compared to the BRCA1wt or the neutral variant R1751Q indicating a difference in the DNA damage processing. We propose a model where BRCA1 cancer variants interact with the DNA double strand break repair pathways producing DNA recombination intermediates, that maybe less repairable and decrease MMS-induced recombination and survival. Again, this study strengthens the use of yeast as model system to characterize the mechanisms leading to cancer in humans carrying the BRCA1 missense variant.     

Identification of sequences that target BRCA1 to nuclear foci following alkylative DNA damage

BRCA1 is a tumor suppressor involved in the maintenance of genome integrity. BRCA1 co-localizes with DNA repair proteins at nuclear foci in response to DNA double-strand breaks caused by ionizing radiation (IR). The response of BRCA1 to agents that elicit DNA single-strand breaks (SSB) is poorly defined. In this study, we compared chemicals that induce SSB repair and observed the most striking nuclear redistribution of BRCA1 following treatment with the alkylating agent methyl methanethiosulfonate (MMTS). In MCF-7 breast cancer cells, MMTS induced movement of endogenous BRCA1 into distinctive nuclear foci that co-stained with the SSB repair protein XRCC1, but not the DSB repair protein gamma-H2AX. XRCC1 did not accumulate in foci after ionizing radiation. Moreover, we showed by deletion mapping that different sequences target BRCA1 to nuclear foci induced by MMTS or by ionizing radiation. We identified two core MMTS-responsive sequences in BRCA1: the N-terminal BARD1-binding domain (aa1-304) and the C-terminal sequence aa1078-1312. These sequences individually are ineffective, but together they facilitated BRCA1 localization at MMTS-induced foci. Site-directed mutagenesis of two SQ/TQ motif serines (S1143A and S1280A) in the BRCA1 fusion protein reduced, but did not abolish, targeting to MMTS-inducible foci. This is the first report to describe co-localization of BRCA1 with XRCC1 at SSB repair foci. Our results indicate that BRCA1 requires BARD1 for targeting to different types of DNA lesion, and that distinct C-terminal sequences mediate selective recruitment to sites of double- or single-strand DNA damage.     

BRCA1-induced apoptosis involves inactivation of ERK1/2 activities

Mutation in the BRCA1 gene is associated with an increased risk of breast and ovarian cancer. Recent studies have shown that the BRCA1 gene product may be important in mediating responses to DNA damage and genomic instability. Previous studies have indicated that overexpression of BRCA1 can induce apoptosis or cell cycle arrest at the G(2)/M border in various cell types. Although the activation of JNK kinase has been implicated in BRCA1-induced apoptosis, the role of other members of the mitogen-activated protein kinase family in mediating the cellular response to BRCA1 has not yet been examined. In this study, we monitored the activities of three members of the MAPK family (ERK1/2, JNK, p38) in MCF-7 breast cancer cells and U2OS osteosarcoma cells after their exposure to a recombinant adenovirus expressing wild type BRCA1 (Ad.BRCA1). Overexpression of BRCA1 in MCF-7 cells resulted in arrest at the G(2)/M border; however, BRCA1 expression in U2OS cells induced apoptosis. Although BRCA1 induced JNK activation in both cell lines, there were marked differences in ERK1/2 activation in response to BRCA1 expression in these two cell lines. BRCA1-induced apoptosis in U2OS cells was associated with no activation of ERK1/2. In contrast, BRCA1 expression in MCF-7 cells resulted in the activation of both ERK1/2 and JNK. To directly assess the role of ERK1/2 in determining the cellular response to BRCA1, we used dominant negative mutants of MEK1 as well as MEK1/2 inhibitor PD98059. Our results indicate that inhibition of ERK1/2 activation resulted in increased apoptosis after BRCA1 expression in MCF-7 cells. Furthermore, BRCA1-induced apoptosis involved activation of JNK, induction of Fas-L/Fas interaction, and activation of caspases 8 and 9. The studies presented in this report indicate that the response to BRCA1 expression is determined by the regulation of both the JNK and ERK1/2 signaling pathways in cells.     

Nuclear thioredoxin-1 is required to suppress cisplatin-mediated apoptosis of MCF-7 cells

Different cell line with increased thioredoxin-1 (Trx-1) showed a decreased or increased sensitivity to cell killing by cisplatin. Recently, several studies found that the subcellular localization of Trx-1 is closely associated with its functions. In this study, we explored the association of the nuclear Trx-1 with the cisplatin-mediated apoptosis of breast cancer cells MCF-7. Firstly, we found that higher total Trx-1 accompanied by no change of nuclear Trx-1 can not influence apoptosis induced by cisplatin in MCF-7 cells transferred with Trx-1 cDNA. Secondly, higher nuclear Trx-1 accompanied by no change of total Trx-1 can protect cells from apoptosis induced by cisplatin. Thirdly, high nuclear Trx-1 involves in the cisplatin-resistance in cisplatin-resistive cells. Meanwhile, we found that the mRNA level of p53 is closely correlated with the level of nuclear Trx-1. In summary, we concluded that the nuclear Trx-1 is required to resist apoptosis of MCF-7 cells induced by cisplatin, probably through up-regulating the anti-apoptotic gene, p53.     

Prolactin-dependent up-regulation of BRCA1 expression in human breast cancer cell lines.

We report experimental evidence that BRCA1, a breast and ovarian cancer susceptibility gene, is up-regulated in response to prolactin (PRL) stimulation. Expression of the BRCA1 gene was monitored in 2 human breast cancer cell lines (MCF-7 and T-47D) and in the normal mammary epithelial cell line MCF10a. Using competitive RT-PCR, we have shown that PRL induced an increase in BRCA1 mRNA level in MCF-7 and T-47D cell lines at a dose resulting in the maximal enhancement of cell proliferation. The up-regulation was 12-fold in MCF-7 cells and 2-fold in T-47D cells. No increase in BRCA1 mRNA level was observed in the MCF10a cell line. The level of BRCA1 protein was quantified using an affinity chromatography strategy. At the protein level, PRL treatment induced a 4-fold increase of BRCA1 protein expression in MCF-7 and a 6-fold increase in T-47D cells, whereas BRCA1 protein expression was not affected by PRL in MCF10a.