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BRCA2 Suppresses Cell Proliferation via Stabilizing MAGE-D1

¹ Division of Cancer Biology, Evanston Northwestern Healthcare Research Institute, Department of Medicine, Northwestern University Feinberg School of Medicine, Evanston, Illinois; and ² Department of Radiation Oncology, New England Medical Center, Tufts University School of Medicine, Boston, Massachusetts

Requests for reprints: Qingshen Gao, Division of Cancer Biology, Evanston Northwestern Healthcare Research Institute, Department of Medicine, Northwestern University Feinberg School of Medicine, 1001 University Place, Evanston, IL 60201. Phone: 224-364-7531; Fax: 224-364-7402; E-mail: q-gao{at}northwestern.edu.

	Abstract

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Germ line mutations in BRCA2 gene predispose women to early-onset familial breast and ovarian cancer. BRCA2 is a protein of multiple functions. In addition to its role in DNA double-strand break repair, BRCA2 also plays a role in stabilization of stalled DNA replication forks, cytokinesis, transcription regulation, mammalian gametogenesis, centrosome duplication, and suppression of cell proliferation. However, how BRCA2 mutations predispose women specifically to breast and ovarian cancer remains undefined. Here we found that BRCA2 binds and stabilizes MAGE-D1, a member of the MAGE gene family of proteins. Expression of BRCA2 and MAGE-D1 synergistically suppresses cell proliferation independently of the p53 pathway. Using two MAGE-D1 RNA interferences and two cell lines expressing low or undetectable levels of MAGE-D1, we further showed that the expression of MAGE-D1 is required for BRCA2-mediated suppression of cell proliferation, indicating that MAGE-D1 is a downstream target of BRCA2 and that BRCA2 suppresses cell proliferation via stabilizing MAGE-D1. Importantly, MAGE-D1 protein expression was reduced in 6 of 16 breast carcinoma cell lines tested as compared with untransformed immortal mammary epithelial cell lines, suggesting that suppression of MAGE-D1 expression may be involved in the tumorigenesis of a subset of sporadic breast cancers.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Germ line mutations in the breast cancer susceptibility gene BRCA2 confer susceptibility to familial early-onset breast and ovarian cancers (1–3). However, mutation of the BRCA2 gene in sporadic breast cancer rarely occurs (4). BRCA2 is a large protein of multiple functions. Extensive studies indicate that BRCA2 plays an important role in DNA damage repair by homologous recombination (5–12). BRCA2 also plays an important role in transcription regulation (13), centrosome duplication (14), cytokinesis (15), mammalian gametogenesis (16), and stabilization of stalled DNA replication forks (17). Importantly, BRCA2 inhibits tumor cell proliferation in vitro and tumor growth in vivo (18). However, how BRCA2 mediates the negative regulation of cell proliferation remains undefined.

The MAGE (MAGE for melanoma antigen) family contains a large group of proteins that harbor the MAGE homology domain, a well-conserved domain of about 200 amino acids (19). Members of the hMAGE-A, hMAGE-B, and hMAGE-C subfamilies are completely silent in most normal tissues, the exceptions being male germ cells, and for some members of the subfamilies, the placenta (19). However, many members of the MAGE family are expressed in tumor cells of various histologic types and thus are of particular interest for antitumor immunotherapy. Members of the hMAGE-D, hMAGE-E, hMAGE-F, hMAGE-G, and hMAGE-H subfamilies exhibit a "ubiquitous" expression pattern; that is, they are expressed in many normal tissues at various levels (19). Recent studies indicate that MAGE-D1 is a regulator of apoptosis, transcription, and cell cycle progression (19). MAGE-D1 has been found to interact with Dlx/Msx homeodomain proteins and is required for Dlx5-dependent transcription (20). Recently, it was reported that MAGE-D1 cooperated with Necdin, another MAGE family protein, to regulate the function of Msx homeodomain proteins in cellular differentiation (21). MAGE-D1 also interacts with inhibitors of apoptosis proteins (IAP), ubiquitin ligase praja1, axon guidance receptor UNC5H, and Ror receptor kinases (22–25). MAGE-D1 has also been reported to bind to p75 neurotrophin receptor and to mediate nerve growth factor–dependent apoptosis (26).

In this study, using a conserved fragment of BRCA2 as bait, we identified MAGE-D1 as a BRCA2 binding protein and showed that BRCA2 and MAGE-D1 interacted in vivo. Moreover, BRCA2 can stabilize MAGE-D1 and expression of BRCA2 and MAGE-D1 can suppress cell proliferation synergistically independently of p53 pathway. We also found that BRCA2-mediated growth suppression is dependent on the expression of MAGE-D1, suggesting that MAGE-D1 is likely a downstream target of BRCA2. Importantly, MAGE-D1 expression was reduced in 6 of 16 breast carcinoma cell lines tested compared with untransformed immortal mammary epithelial cells, indicating that suppression of MAGE-D1 expression may disrupt the function of BRCA2 and play a role in the tumorigenesis of a subset of sporadic breast cancers.

	Materials and Methods

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Yeast two hybrid constructs and screening. The cDNA encoding the residues 2393 to 2952 of BRCA2 was cloned into pGBT9 (Clontech, Palo Alto, CA) to generate the bait plasmid, pGBT9-BRCA2-C2. Yeast two hybrid screening was done as described previously (27, 28).

Cell culture. Human embryonic kidney cell line 293T was cultured in DMEM supplemented with 10% FCS (Hyclone, Logan, UT). 76NTert, 76R30, 184A1, 184B5, MCF-10A, 21MT-1, and 21MT-2 cells were grown in DFCI (29). HCC2157 cells were cultured in DFCI supplemented with 10% FCS. MCF-7, T47D, ZR-75-30, UACC812, MDAMB134, MDAMB361, MDAMB415, MDAMB453, and BT549 cells were cultured in -MEM (Life Technologies, Gaithersburg, MD) supplemented with 10% FCS. HCC70, HCC1143, HCC 1806, and 21NT cells were cultured in -MEM supplemented with 10% FCS, 1 µg/mL hydrocortisone (Sigma, St. Louis, MO), and 12.5 ng/mL epidermal growth factor (Sigma).

Plasmid constructs and RNA interference. The pCDEF3-Myc-MAGE-D1 construct was generated by cloning Myc-tagged full-length human MAGE-D1 coding sequences into pCDEF3 vector (30). Myc-tagged full-length human MAGE-D1 was generated by PCR using MAGE-D1 EST clone (ATCC no. 6555672) as a template and verified by sequencing. The pCR3.1-4xMyc-MAGE-D1 construct was generated by cloning full-length human MAGE-D1 coding sequences fused with four copies of myc tags at its 5' end into pCR3.1 vector. Two pSuper-MAGE-D1-RNAi constructs were generated to express two MAGE-D1–specific RNA interference (RNAi) target sequences, ACCTGCGCCCTTCTCCCAA and CTACTAAAGTGGGCCCAAA (synthesized by TriLink BioTechnologies, Inc., San Diego, CA). The Flag-tagged BRCA2 and its mutants were generated by PCR and restriction splicing and cloned into pEF6/HisB vector. The details of construction are available upon request.

Polyclonal antibody generation. A DNA fragment encoding amino acids (aa) 36 to 272 of human MAGE-D1 was cloned into pPROEX to produce a His-MAGE-D1 fusion protein. This protein was purified and used to immunize rabbits. The anti-MAGE-D1 antibody was affinity purified using His-tagged MAGE-D1 (36-272 aa).

In vivo binding of MAGE-D1 and BRCA2 or its mutants. The 293T cells were plated at 1 x 10⁶ per 100-mm dish and transfected with 20 µg of pEF6-FLAG-tagged BRCA2 or its mutants and 10 µg of pCDEF3-Myc-MAGE-D1, either alone or in combination, using the calcium phosphate method. Forty-eight hours later, cell lysates were prepared in LSAB buffer [100 mmol/l Tris-HCl (pH. 7.5), 150 mmol/L NaCl, and 1% NP40]. Lysates were subjected to immunoprecipitation using anti-FLAG antibody (M2, Sigma), followed by immunoblotting using anti-Myc (9E10) or anti-FLAG monoclonal antibodies. Enhanced chemiluminescence was used for detection (Amersham, Piscataway, NJ). To examine the binding of endogenous MAGE-D1 with the endogenous BRCA2, 293T cells and Capan-1 cells were harvested in radioimmunoprecipitation assay (RIPA) buffer without SDS [100 mmol/L Tris-HCl (pH. 7.5), 150 mmol/L NaCl, 1% Triton, and 1% sodium deoxycholate]. The cell lysate was subjected to immunoprecipitation using preimmune, anti-BRCA2-C2 (generated by immunizing rabbits with GST-BRCA2-C2), and anti-MAGE-D1 antisera, followed by Western blotting using anti-BRCA2 (BRCA2 ab1, Oncogene Science, Uniondale, NY) and anti-MAGE-D1 antibodies.

Immunofluorescence and bromodeoxyuridine labeling. Cells grown on coverslips (Fisher, Pittsburgh, PA) were transfected with pCDEF3, pEF6, pCDEF3-myc-MAGE-D1, and pEF6-Flag-BRCA2, alone or in combination, together with pBB14-GFP (a membrane-localized GFP fusion protein that can be retained after permeabilization; ref. 31), using Fugene 6 (Roche, Nutley, NJ) according to the manufacturer's instructions. Two days after transfection, the cells were incubated with bromodeoxyuridine (BrdUrd) for 1 hour and stained with anti-BrdUrd antibody (Roche) according to the manufacturer's instructions.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Identification of MAGE-D1 as a BRCA2 binding protein and binding of MAGE-D1 to BRCA2 in vivo. In an attempt to identify novel BRCA2 binding proteins, BRCA2 cDNA encoding the most conserved region of BRCA2 (residues 2393-2952) was used as bait to screen a yeast two hybrid library prepared from normal mammary epithelial cells (strain 76N) as described previously (27, 28). Of the positive clones identified, two identical clones encoded the COOH-terminal 116 aa of MAGE-D1, a member of the MAGE family of proteins.

To confirm the interaction between BRCA2 and MAGE-D1 in vivo, full-length Myc-tagged-MAGE-D1 was transfected into 293T cells alone or together with full-length Flag-tagged-BRCA2. Forty-eight hours after transfection, the transfected cells were harvested in LSAB buffer and the BRCA2-MAGE-D1 complex was immunoprecipitated using anti-Flag monoclonal antibody. As shown in Fig. 1B, MAGE-D1 can be specifically coimmunoprecipitated with BRCA2 using anti-Flag antibody (Fig. 1B, lane 8). Importantly, MAGE-D1 can also be coimmunoprecipitated with BRCA2 in RIPA buffer (without SDS), indicating that the interaction of MAGE-D1 and BRCA2 is unusually strong (data not shown). To define the binding domain of MAGE-D1 on BRCA2, one set of Flag-tagged BRCA2 deletion mutants as summarized in Fig. 1A was cotransfected into 293T cells with full-length myc-tagged MAGE-D1 and coimmunoprecipitation was carried out using anti-Flag monoclonal antibody. We found that the only MAGE-D1-binding domain on BRCA2 localizes to a region between residues 2393 and 2952 in the BRCA2 protein (Fig. 1A and B).

View larger version (32K): [in this window] [in a new window] [Download PPT slide]   Figure 1. Binding of MAGE-D1 and BRCA2. A, diagram of BRCA2 mutants. The binding of BRCA2 and its mutants to MAGE-D1 is summarized. B, in vivo binding of BRCA2 and MAGE-D1. 293T cells were transfected with Myc-tagged full-length MAGE-D1 and Flag-tagged BRCA2 and its mutants. The cells were harvested 48 hours after transfection in LSAB. BRCA2 and its mutants were immunoprecipitated using anti-Flag antibody. The immunoprecipitated protein complexes were fractionated and immunoblotted using anti-Myc antibody (9E10) to detect Myc-MAGE-D1. The blot was reprobed using anti-Flag antibody to detect BRCA2 and its mutants. A 4% (right) and a 7.5% (left) PAGE gels were used to fractionate the full-length BRCA2 and its mutants of varied molecular weight (58-380 kDa).

View larger version (16K): [in this window] [in a new window] [Download PPT slide]   Figure 2. Endogenous binding of MAGE-D1 and BRCA2 in vivo. A, characterization of anti-MAGE-D1 antibody. Cell lysates (50 µg of total protein) from 76NTert, 76R30, MCF-7, HeLa, 293T, and 293T cells transfected with 5 µg of pCR3.1 or 4x Myc-MAGE-D1 were fractionated by SDS-PAGE and immunoblotted using affinity-purified anti-MAGE-D1 or anti-Myc antibodies. B, in vivo binding of endogenous MAGE-D1 and endogenous BRCA2. 293T cells and CAPAN-1 cells were harvested in RIPA buffer (without SDS). The cell lysates were immunoprecipitated using preimmune, anti-BRCA2-C2 and anti-MAGE-D1 antisera. The immunoprecipitated protein complexes were fractionated and immunoblotted using anti-BRCA2 (BRCA2 ab1, Oncogene Science) and anti-MAGE-D1 antibodies.

BRCA2 stabilizes MAGE-D1. We found that the MAGE-D1 protein level was always much higher when MAGE-D1 was coexpressed with BRCA2 than when it was expressed alone. To investigate this observation further, a constant amount of MAGE-D1 was cotransfected with increasing amounts of BRCA2 into 293T cells, the MAGE-D1 protein level was examined by Western blotting using anti-Myc antibody. As shown in Fig. 3A, the MAGE-D1 protein level increased significantly and dose dependently with increased amounts of transfected BRCA2, although BRCA2 was detectable only when >10 µg of DNA was transfected. Furthermore, the level of MAGE-D1 did not increase when it was coexpressed with a BRCA2 mutant devoid of the MAGE-D1 binding domain (BRCA2C2), indicating that the effect of BRCA2 on the MAGE-D1 protein level is due to their specific interaction (Fig. 3B). To delineate the mechanism of the elevated MAGE-D1 protein level upon BRCA2 coexpression, we examined the half-life of MAGE-D1 in 293T cells transfected with MAGE-D1 alone or with MAGE-D1 and BRCA2 together, using cycloheximide. As shown in Fig. 3C, the half-life of MAGE-D1 was significantly increased up to >12 hours in the presence of BRCA2 coexpression compared with about 2 hours in the absence of BRCA2 coexpression. This result clearly indicates that BRCA2 stabilizes MAGE-D1 protein.

View larger version (40K): [in this window] [in a new window] [Download PPT slide]   Figure 3. BRCA2 expression stabilizes MAGE-D1. A, MAGE-D1 protein levels when cotransfected with increasing amounts of BRCA2. 293T cells were transfected with 0.2 µg pBB14-GFP and 0.2 µg Myc-tagged MAGE-D1 alone or with increasing amounts of Flag-tagged BRCA2, as indicated. Cell lysates were prepared 48 hours after transfection and analyzed for Myc-MAGE-D1 and Flag-BRCA2 protein levels by immunoblotting using anti-Myc or anti-Flag antibodies. Immunoblotting using anti-GFP antibody was used to control transfection efficiency. B, MAGE-D1 protein level when cotransfected with wild-type BRCA2 or BRCA2C2 (BRCA2 mutant devoid of the MAGE-D1 binding domain). C, half-life of MAGE-D1. 293T cells were transfected with Myc-tagged MAGE-D1 alone (top) or with Flag-tagged BRCA2 (bottom). Cycloheximide (final concentration 100 µg/mL) was added 48 hours after transfection to inhibit nascent protein synthesis. Cell lysates were prepared at the indicated time points after the addition of cycloheximide, followed by immunoblotting using anti-Myc and anti--tubulin antibodies to determine the turnover of MAGE-D1 protein. The numbers under the panels are quantification analyses of the signals as obtained by use of LabWorks software (UVP, Inc., Upland, CA).

To examine the effect of coexpression of MAGE-D1 and BRCA2 on cell cycle progression, 76NTert cells (an hTERT immortalized human mammary epithelial cell line derived from 76N cells) were transfected with MAGE-D1 and BRCA2, alone or in combination, together with pBB14/GFP to indicate the transfected cells. The cells were pulse labeled for 1 hour with BrdUrd at 48 hours after transfection and analyzed for BrdUrd incorporation by immunostaining using anti-BrdUrd antibody. As expected, expression of p53 suppressed 76Ntert cell proliferation, validating our cell proliferation assay. About 30% of cells transfected with MAGE-D1 or BRCA2 incorporated BrdUrd, whereas about 40% of vector-transfected cells incorporated BrdUrd, indicating that both MAGE-D1 and BRCA2 can inhibit progression of the cell cycle to a similar extent as can p53 (Fig. 4A and B). It is important to note that only 11% of cells overexpressing both MAGE-D1 and BRCA2 incorporated BrdUrd, indicating that BRCA2 and MAGE-D1 can synergistically suppress cell proliferation.

View larger version (22K): [in this window] [in a new window] [Download PPT slide]   Figure 4. BRCA2 and MAGE-D1 synergistically suppress cell proliferation. A, BrdUrd incorporation assay in 76NTert cells. 76NTert cells plated on coverslips in 24-well plate were transfected with 0.5 µg MAGE-D1 and 1.5 µg BRCA2, alone or in combination, together with pBB14-GFP (0.2 µg). The cells were incubated for 48 hours after transfection and labeled with BrdUrd for 1 hour. The cells were fixed and stained using an anti-BrdUrd antibody. The DNA was stained with DAPI. Note that most of BRCA2- or MAGE-D1–transfected cells (GFP-positive cells) are negative for BrdUrd staining, while many vector-transfected cells (GFP-positive) or untransfected cells (GFP-negative) are positive for BrdUrd staining. B and C, BRCA2 and MAGE-D1 synergistically suppress cell proliferation. 76NTert or 76R30 cells were transfected with MAGE-D1 and BRCA2, alone or in combination, as indicated and assayed for BrdUrd incorporation as described in (A). The percentage of cells positive for BrdUrd staining was quantified in at least 300 transfected cells (GFP-positive cells). Columns, averages from three independent experiments; bars, SD. The percentage of cells positive for BrdUrd staining was significantly lower in cells transfected with BRCA2, MAGE-D1, or MAGE-D1 + BRCA2 than in cells transfected with vector alone (P < 0.05).

BRCA2-mediated suppression of cell proliferation is dependent on the expression of MAGE-D1. Because BRCA2 can stabilize MAGE-D1 and function synergistically with MAGE-D1 to suppress cell proliferation, it is likely that MAGE-D1 is a downstream target of BRCA2 and BRCA2 suppresses cell proliferation by stabilizing MAGE-D1. For this purpose, we used two RNAi constructs targeting the coding region of MAGE-D1 to silence the expression of MAGE-D1. As shown in Fig. 5A, the endogenous MAGE-D1 level in 293T cells was markedly reduced when these cells were transfected with both MAGE-D1 RNAi constructs (designated as D1 RNAi #1 and D1 RNAi #2). Densitometry analysis of Western blots indicated that >90% of MAGE-D1 was reproducibly depleted with use of these MAGE-D1 RNAi constructs. To determine whether MAGE-D1 is a downstream target of BRCA2, 76Ntert, and 76R30 cells were cotransfected with BRCA2 and the two MAGE-D1 RNAi constructs (Fig. 5B). The proliferation of the transfected cells was analyzed by BrdUrd incorporation as described earlier. As shown in Fig. 5B, both MAGE-D1 RNAi constructs significantly attenuated the effect of BRCA2 expression on cell proliferation (P < 0.05), indicating that BRCA2-mediated suppression of cell proliferation is dependent on the expression of MAGE-D1 and that MAGE-D1 acts downstream of BRCA2.

View larger version (17K): [in this window] [in a new window] [Download PPT slide]   Figure 5. BRCA2-mediated suppression of cell proliferation is dependent on the expression of MAGE-D1. A, Western blotting analysis of 293T cells transfected with vector or MAGE-D1 RNAi constructs. 293T cells were transfected with vector or two MAGE-D1 RNAi constructs. After 48 hours, cells were harvested and fractionated through a SDS-PAGE gel and blotted using anti-MAGE-D1 and anti--tubulin antibodies. B, silencing of MAGE-D1 expression by MAGE-D1 RNAi attenuated BRCA2 expression–mediated suppression of cell proliferation. 76NTert and 76R30 cells were transfected with 1.5 µg BRCA2 alone or in combination with 0.5 µg MAGE-D1 RNAi, together with pBB14-GFP (0.2 µg), and BrdUrd incorporation was quantified as described in Fig. 4B. The percentage of cells positive for BrdUrd staining was significantly lower in cells transfected with BRCA2 than in cells transfected with vector alone or BRCA2 plus MAGE-D1 RNAi (P < 0.05). C, BRCA2 expression does not suppress cell proliferation in cells with a low level of MAGE-D1. HeLa and MCF-7 cells were transfected with BRCA2 and MAGE-D1 alone or in combination. BrdUrd incorporation was quantified as described in Fig. 4B. The percentage of cells positive for BrdUrd staining was not lower in cells transfected with BRCA2 than in cells transfected with vector alone. However, the percentage of cells positive for BrdUrd staining was significantly lower in cells transfected with MAGE-D1 or BRCA2 + MAGE-D1 than in cells transfected with vector alone. (P < 0.05).

MAGE-D1 protein expression in breast carcinoma cell lines. Because the expression of MAGE-D1 is required for BRCA2-mediated suppression of cell proliferation, MAGE-D1 gene mutation or deletion, or suppression of its expression should also abrogate the function of BRCA2, which may be directly linked to tumorigenesis. To investigate if MAGE-D1 expression is altered in breast cancer, we examined the expression of MAGE-D1 in a large panel of breast cancer cell lines and four untransformed immortal mammary epithelial cell lines (76NTert, MCF-10A, 184A1, and 184B5). As shown in Fig. 6, similar levels of MAGE-D1 were readily detectable in the four untransformed mammary epithelial cell lines. However, in four breast carcinoma cell lines (HCC70, HCC1143, HCC1806, and MCF7), the MAGE-D1 protein level was significantly reduced compared with levels in the untransformed immortal mammary epithelial cell lines (Fig. 6). In 21NT and 21MT-2 cells, the MAGE-D1 level was also reduced, although to a lesser extent. This finding suggests that suppression of MAGE-D1 expression may be involved in the tumorigenesis of a subset of sporadic breast cancers.

View larger version (24K): [in this window] [in a new window] [Download PPT slide]   Figure 6. MAGE-D1 protein expression in untransformed immortal mammary epithelial cell lines and breast carcinoma cell lines. Lysates prepared in sample buffer from the cell lines indicated were fractionated on a SDS-PAGE gel and blotted with anti-MAGE-D1 and anti–-tubulin antibodies (loading control). 76NTert, MCF-10A, 184A1, and 184B5 are untransformed immortal mammary epithelial cell lines; the others are breast carcinoma cell lines.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Using a set of BRCA2 mutants, we determined that the only MAGE-D1-binding domain on BRCA2 localizes to a region between residues 2393 and 2952 in the BRCA2 protein. It is notable that this region of BRCA2 encompasses almost the entire DSS1 binding domain (aa 2472-2957), the major part of BRCA2DBD (the DNA/DSS1-binding domain), and one of the FANCG binding domains (aa 2350-2545; refs. 12, 37, 38). This region has been reported to play an important role in double-strand DNA breaks repair via homologous recombination and activation of the Fanconi anemia pathway (12, 37, 38). However, the functional implication of BRCA2 binding to MAGE-D1, DSS1, and FANCG at this region remains to be determined.

How BRCA2 stabilizes MAGE-D1 remains to be elucidated. It has recently been reported that BRCA2 can be copurified with a ubiquitin E3 ligase complex, a holoenzyme complex termed BRCC that contains BRCA1, BARD1, BRCC36, and BRCC45. BRCA1 and BARD1 are proteins with a ring domain and exhibit ubiquitin ligase activities (18). Both BRCC36 and BRCC45 harbor sequence homologous to a subunit of the signalosome and proteasome complexes. A reconstituted complex containing BRCA1/BARD1/BRCC45/BRCC36 exhibits strong ubiquitin ligase activity (18). However, the way in which BRCA2 affects the ubiquitin ligase activity of BRCC holoenzyme has not been defined. Another recent study found that BRCA2 also interacts with a deubiquitinating enzyme, USP11 (39). An important BRCA2 binding protein, DSS1, was also found to be a component of the lid complex of the 26S proteasome (40, 41). The relationships among these BRCA2-containing complexes and their functions need to be elucidated. However, because all these BRCA2-containing complexes are likely to regulate protein degradation, it is reasonable to hypothesize that they regulate the stability of many target proteins. MAGE-D1 may be one of these target proteins and its stability may be regulated by these BRCA2-containing complexes.

It has been reported that expression of BRCA2 suppresses cell growth in vitro and tumor growth in vivo (18). However, the mechanism that BRCA2 suppresses cell proliferation remains undefined. Our finding that BRCA2 is able to suppress cell proliferation only in the presence of MAGE-D1 expression strongly indicates that BRCA2 exerts its function via stabilizing MAGE-D1. MAGE-D1 has been reported to suppress cell proliferation in several cell lines, including 293 cells, MEF cells, U2OS cells, and HepG2 cells (26, 35). Using p53 null MEF cells, it was found that MAGE-D1–mediated suppression of cell proliferation occurs via the p53 pathway. However, our demonstration that MAGE-D1 can suppress cell proliferation in a p53 null mammary epithelial cell line, 76R30 cells (36), indicates that in mammary epithelial cells MAGE-D1 suppresses cell proliferation independently of the p53 pathway (Fig. 4). In corroboration of this finding, we found that MAGE-D1 is also capable of inhibiting the proliferation of HeLa cells, which express only a very low level of p53 due to the presence of human papillomavirus 16 E6 (Fig. 5C). Furthermore, the previous report that MAGE-D1 can suppress the proliferation of 293 cells further supports our finding because the p53 in 293 cells is inactive due to the presence of E1B (26). This discrepancy may represent a cell type–specific function of MAGE-D1.

At present, we can only speculate about how MAGE-D1 inhibits cell proliferation independently of the p53 pathway. Many MAGE-D1 partners have been identified recently, including homeodomain transcription factors Dlx5, Dlx7, Msx1, and Msx2, p75 neurotrophin receptor, axon guidance receptor UNC5H, IAPs, ubiquitin ligase praja1, and Ror receptor kinases (19–26). Some of these MAGE-D1 binding partners may mediate the growth-suppressing function of MAGE-D1. Kuwajima et al. recently reported that Necdin interacts with Msx homeodomain proteins via MAGE-D1 and promotes muscle differentiation by repressing cellular proliferation (21). It is likely that MAGE-D1 cooperates with Necdin to suppress cell proliferation via Msx in mammary epithelial cells. Further studies are required to elucidate the proliferation-suppressing pathway used by MAGE-D1.

Multiple functions have been ascribed to BRCA2, linking it to pathways that inhibit progression to neoplasia. Heterozygous germ line BRCA2 mutations predispose humans specifically to breast and ovarian cancers (1–3). However, BRCA2 is rarely mutated in sporadic breast and ovarian cancers (4). It is possible that distinct mechanisms targeting the BRCA2 pathways operate in sporadic cases. Recently, Hughes-Davies et al. showed that EMSY, a BRCA2 interaction protein, was amplified in 13% of sporadic breast carcinomas and in 17% of sporadic ovarian carcinomas (42). These investigators suggested that overexpression of EMSY in sporadic breast and ovarian cancers may be functionally equivalent to BRCA2 mutation in familial cases (42). In this study, we found that BRCA2 can stabilize MAGE-D1 and suppress cell proliferation via MAGE-D1. MAGE-D1 acts downstream of BRCA2 and mediates the growth-suppressing function of BRCA2. Disruption of the function of MAGE-D1 by mutation, deletion, or suppression of expression should be functionally equivalent to BRCA2 mutations in disrupting BRCA2 function. Consistent with this hypothesis is our finding that, as compared with MAGE-D1 expression in untransformed immortal cell lines, the expression level of MAGE-D1 was reduced in 6 of the 16 breast carcinoma cell lines we examined. This suggests that suppression of MAGE-D1 expression may be involved in the tumorigenesis of a subset of sporadic breast cancers. Biochemical and genetic analyses of MAGE-D1, a BRCA2 binding partner, would provide important insights into a pathway that is likely to be disrupted in human breast and ovarian carcinomas.

	Acknowledgments

 
Grant support: NIH grant 1 R01 CA095221-01A1 and 1 R01 CA96986-01A1 and the American Cancer Society grant RSG-03-048-01 (Q. Gao).

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

We thank Drs. Wen-Hwa Lee, Phang-Lang Chen, and Inder M. Verma for providing us with the full-length BRCA2 constructs.

Received 1/ 4/05. Revised 3/ 8/05. Accepted 3/24/05.

	References

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