Abstract
Bone morphogenetic proteins (BMPs) have been implicated in the control of proliferation, tissue formation, and differentiation. BMPs regulate the biology of stem and progenitor cells and can promote cellular differentiation, depending on the cell type and context. Although the BMP pathway is known to be involved in early embryonic development of the mammary gland via mesenchymal cells, its role in later epithelial cellular differentiation has not been examined. The majority of the mammary gland development occurs post-natal, and its final functional differentiation is characterized by the emergence of alveolar cells that produce milk proteins. Here, we tested the hypothesis that bone morphogenetic protein receptor 1A (BMPR1A) function was required for mammary epithelial cell differentiation. We found that the BMPR1A-SMAD1/5/8 pathway was predominantly active in undifferentiated mammary epithelial cells, compared with differentiated cells. Reduction of BMPR1A mRNA and protein, using short hairpin RNA, resulted in a reduction of SMAD1/5/8 phosphorylation in undifferentiated cells, indicating an impact on this pathway. When the expression of the BMPR1A gene knocked down in undifferentiated cells, this also prevented beta-casein production during differentiation of the mammary epithelial cells by lactogenic hormone stimulation. Addition of Noggin, a BMP antagonist, also prevented beta-casein expression. Together, this demonstrated that BMP-BMPR1A-SMAD1/5/8 signal transduction is required for beta-casein production, a marker of alveolar cell differentiation. This evidence functionally identifies BMPR1A as a potential new regulator of mammary epithelial alveolar cell differentiation.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
In addition to the roles of the bone morphogenetic protein (BMP) pathway controlling cell fate in embryonic stem cells, it has tissue-specific roles in epithelial stem cell maintenance and progenitor cell differentiation in the hair follicle (Kobielak et al. 2003; Guha et al. 2004; Zhang et al. 2006), prevents premature differentiation of myogenic satellite cells (Ono et al. 2011), and a role in adipocyte lineage determination from stem cells (Huang et al. 2009). Given these roles, we investigated its requirement for mammary epithelial cell differentiation.
BMPs bind to a complex of types 1 (bone morphogenetic protein receptor 1A (BMPR1A) and BMPR1B) and 2 (BMPR2) receptors, leading to phosphorylation of the type 1 receptors by the kinase domain of the type 2 receptors. Activation of the canonical pathway results in phosphorylation of specific SMAD proteins such as SMAD1, SMAD5 and SMAD8 (SMAD1/5/8). These complex with co-SMAD4 and translocate to the nucleus to affect gene regulation. Type 1 receptors dictate the specificity of ligand binding, and in the case of BMPR1A, it is BMP 2, BMP4, and to a lesser extent BMP7 (Botchkarev 2003).
The role of the BMP pathway is implicated in early mammary gland development. BMP4 is known to be important in ductal growth during embryonic mammary gland development, with the BMPR1A (also known as activin-like kinase 3) playing a role in the mammary mesenchyme, as opposed to the epithelium (Hens et al. 2007). BMP4 was also able to potentiate fibroblast growth factor (FGF)-2-, FGF-7-, FGF-10-, epidermal growth factor (EGF)-, or hepatocyte growth factor-induced cellular proliferation in J3B1A mammary epithelial cells, although BMP4 did not affect proliferation on its own (Montesano et al. 2008). In 3D collagen cultures of J3B1A cells, BMP4 disrupted spontaneous cellular morphology of polarized acinar structures in a pathway dependent on mitogen-activated protein kinases (Montesano 2007). The role of the BMP pathway in lactogenic mammary cell differentiation has not yet been examined.
It is believed that lactogenic mammary epithelial cells differentiate from luminal progenitors (Welm et al. 2002; Shackleton et al. 2006; Sleeman et al. 2006; Stingl et al. 2006; Asselin-Labat et al. 2007). HC11 cells, a prolactin responsive clone of the COMMA-1D mouse (Balb/c) mammary epithelial cell line, (Ball et al. 1988) have been used as an in vitro model to study mammary epithelial cell differentiation of the luminal lineage. HC11 cells are a well-known cell line that can be cultured to represent undifferentiated cells (with EGF and insulin), competent to differentiate (EGF), and differentiated (dexamethasone, insulin, and prolactin) cells. Competent cells (cultured in EGF) can be pre-differentiated with the lactogenic hormones dexamethasone and insulin prior to treatment with prolactin, which stimulates HC11 cells to produce markers of alveolar cell differentiation (Desrivieres et al. 2003; Perotti et al. 2009) including beta-casein. Previously, we identified Bmpr1a in a screen designed to identify potential regulators of differentiation, as a gene that was preferentially expressed in undifferentiated HC11 cells compared with differentiated HC11 cells (Perotti et al. 2009). We hypothesize that a reduction in BMPR1A signaling would disturb mammary epithelial progenitor cell differentiation. We now demonstrate that BMPR1A activity in HC11 mammary epithelial cells is required prior to lactogenic signal transduction, for the stage of milk-secretory cell differentiation marked by beta-casein production.
Materials and Methods
Antibodies.
Goat and rabbit anti BMPR1A antibodies were purchased from Santa Cruz (Santa Cruz, CA) and Abgent (Biolynx, San Diego, CA), respectively. Goat anti beta-casein (M-14) was obtained from Santa Cruz. Mouse anti-GRB2 and anti-phospho-SMAD1/5/8 (SMAD1,5 phospho-Ser 463/465, SMAD8 phospho-Ser 426/428) antibodies were purchased from Cell Signaling Technology (Pickering, ON, Canada), Histone H3 from Millipore (Billerica, MA). Secondary antibodies, HRP conjugated, were obtained from Bio-Rad (Mississauga, ON, Canada) and Pierce (Nepean, ON, Canada), fluorescence conjugated from Invitrogen (Burlington, ON, Canada).
Materials.
RPMI 1640 medium was purchased from Hyclone (Nepean, ON, Canada). Glutamine, penicillin/streptomycin, and trypsin were from Gibco-Invitrogen. Insulin (bovine) and prolactin (ovine) were from Sigma (Oakville, ON, Canada), and EGF (mouse) from BD Biosciences (Mississauga, ON, Canada). The recombinant human Noggin/Fc chimera was purchased from R&D Systems (Minneapolis, MN).
Cell culture.
Mouse HC11 cells (Ball et al. 1988) were grown in RPMI 1640 medium containing 10 % fetal calf serum, 2 mM l-glutamine and 100 units/ml penicillin–streptomycin. For cell maintenance, the medium was supplemented with insulin 5 μg/ml and EGF 0.01 μg/ml.
Differentiation of HC11 cells.
For differentiation, 0.7 × 105 HC11 undifferentiated cells/ml were cultured in 100 mm dishes during 4 d in RPMI media (+5 μg/ml insulin+10 μg/ml EGF). During this time cells reached 100 % confluence. Cells were then washed with PBS three times and media was replaced with competence media (+EGF) and were maintained for 1 d, after which they become responsive to lactogenic hormones. Then cells were washed and pre-differentiation media was added (+insulin + dexamethasone 10−7 M) for 1 d. Finally, cells were cultured for 3 d in differentiation media (+insulin + dexamethasone + prolactin 5 μg/ml) (Perotti et al. 2009). If included in the experiment, Noggin was added at the concentration indicated at the start of the differentiation procedure. Differentiation was monitored by measuring beta-casein production, using western blot and PCR.
Protein extracts.
The cells taken at the appropriate time for undifferentiated, competent and differentiated stages were scraped with a rubber policeman in PBS on ice, centrifuged at 4°C and resuspended in NP40 lysis buffer, containing a set of protease inhibitors, 20 mM Tris-HCl, 150 mM NaCl, 2 mM EDTA, 0.1 % Triton-X, and 1 % SDS (Perotti et al. 2009). From the supernatant, 50 μg of protein was loaded per lane. Detection of fluorophores on the Odyssey (Licor) using fluorescent antibodies or on film with horse-radish peroxidase-labeled secondary antibodies was performed. Nuclear extracts were prepared as follows: soluble cytoplasmic extracts were prepared in a buffer containing 20 mM HEPES at pH 7.9, 10 mM KCl, 1 mM EDTA, 0.2 % NP-40, 10 % glycerol with protease, and phosphatase inhibitors followed by centrifugation (15,000×g). The nuclear pellet was resuspended in a buffer containing 420 mM NaCl, 20 % glycerol, 20 mM HEPES at pH 7.9, 10 mM KCl, 1 mM EDTA with protease, and phosphatase inhibitors for 30 min 4°C before centrifugation (15000×g). For western analysis, 15 μg of soluble nuclear extract was loaded per lane and either actin (Huang et al. 2005; Shitashige et al. 2007; Dai et al. 2009) or histone H3 were used as loading controls.
RNA extractions and reverse transcription.
Total RNA was then extracted using Qiagen (Toronto, ON, Caanda) RNA Easy kit. The first strand cDNA was obtained by reverse transcription of 20 μg RNA using Superscript II reverse transcriptase (Invitrogen), according to manufacturer’s protocol.
PCR reactions.
PCR was carried out in ×1 PCR buffer (200 mM Tris-HCl and 500 mM KCl) plus 3 mM MgCl, 200 nM primers, and 200 μM dNTPs as previously described (Perotti et al. 2009).
Amplification of the SMADs were as follows using a SMAD1 forward primer: 5′CGCTATGAATGTGACCAGCTT3′, SMAD5 forward primer: 5′GAGTGGAGAGTCCAGTCTTACCT3′, SMAD8 forward primer: 5′GTCACAGAGTATACACCAAGAAG3′ in the above conditions for 28 cycles at 55°C.
shRNA preparation, transfection, and transduction.
Four different sequences of shRNA were prepared that targeted different regions of the Bmpr1a mRNA (accession number NM_009758). Sequences for shRNA starting at nucleotide positions 1258, 823, and 348, of the BMPR1A gene were obtained from Oligoengine. RNAi explorer from Gene Link was used to create a shRNA starting at sequence 1124 and lamin sequence design. The siRNA Wizard (InvivoGen) was used to create a scrambled sequence of the target identified from the 1124 start position (shScr). The shRNA sequences were cloned into pSuper.retro vector (Oligoengine) using HindIII sites. HC11 cells were transfected with the shRNA containing constructs or with the empty vector (EV) using Lipofectamine 2000 (Invitrogen), according to manufacturer’s protocols and cells were selected using Geneticin resistance to create several different clones of six cell lines (shBMPR1A-1258, shBMPR1A-1124, shBMPR1A-823, shBMPR1A-348, shEV, shLam, and shScr). Alternatively, cells were transfected using polyethylenimine (PEI). A 1-mg/ml solution of linear PEI MW25K (Polyscience Inc. cat. no. 23966, Woodbridge, ON, Canada) was prepared in water and neutralized with HCL. For each well of a six-well plate with cells at 70–80 % confluence, 2 μg DNA and 8 μl PEI were added to 200 μl serum-free RPMI and mixed by vortexing. PEI/DNA/medium mixture was added to cells after 10–15 min incubation for a total of 2 ml of medium. Geneticin treatment of 500–700 μg/ml started after 24 h with fresh media and continued for 10 d. Alternatively, the vectors were transfected into a 293T-based packaging cell line, Phi-NX, (developed by Dr. Garry Nolan, Stanford University) and the HC11 cells transduced with viral particles according to the pSuper.retro instructions.
shRNA description | Target sequence | |
---|---|---|
1 | shBMPR1A-1258 | 5′-ACCATTTCCAGCCCTACAT-3′ |
2 | shBMPR1A-1124 | 5′-GTTGCTGTATTGCTGACCT-3′ |
3 | shBMPR1A-823 | 5′-AGAAATCTACCAGACGGT-3′ |
4 | shBMPR1A-348 | 5′-AGCTACGCAGGACAATAG-3′ |
5 | shLam | 5′-TGAGGATGACGACGAGGA-3′ |
Results
The BMPR1A pathway is only active in undifferentiated and competent cells.
BMPs are members of the TGF-β superfamily. Activated receptors phosphorylate the DNA-binding proteins SMAD1/5/8, each of which can then heterodimerize with SMAD4 and translocate to the nucleus to regulate transcription of downstream target genes (Itoh et al. 2000). As the activity and function of the BMPR1A pathway in mammary epithelial cells is relatively uncharacterized, we investigated the phosphorylation of SMAD1/5/8 as a read-out of the canonical BMPR1A pathway in the presence of serum.
The activation of the BMPR1A pathway in parental and shBMPR1A-stable cell lines was assessed using an antibody directed against phosphorylated-SMAD1/5/8. We determined that the pathway is active in undifferentiated (treated with EGF and insulin), competent (treated with EGF), and pre-differentiated (treated with dexamethasone and insulin) parental HC11 cells but that the activity is greatly reduced in the differentiated cells, which are those treated additionally with prolactin (Fig. 1A ).
Knockdown of Bmpr1a with short-hairpin RNA.
In order to characterize the function of BMPR1A, we knocked down Bmpr1a expression in HC11 cells. We separately transfected four different vector constructs, each encoding a different short hairpin (shRNA) against Bmpr1a (shBMPR1A) that targeted different regions of the gene, creating a minimum of four separate stable HC11-shBMPR1A cell lines (shBMPR1A-348, shBMPR1A-823, shBMPR1A-1124, and shBMPR1A-1258), one with shRNA directed against lamin A (shLam), scrambled-sh1124 (shScr) and one empty vector line (shEV). The four distinct shBMPR1A sequences and six cell lines were generated in order to greatly reduce the chance of off-target effects. In addition, we made several distinct stable cell line clones with each of the constructs as experimental replicates. Overall, the results in the study were consistent across the replicates and each of the different shBMPR1A sequences, providing multiple levels of experimental replication.
Bmpr1a gene expression was analyzed by PCR before and after knockdown. Compared with the control cells, HC11 cells expressing one of the four shBMPR1A constructs had greatly reduced amounts of Bmpr1a mRNA (representative lines, Fig. 1B ). HC11 cells expressing an shRNA directed against the unrelated target gene, lamin, did not have reduced Bmpr1a expression (Fig. 1B ), providing an indication of specificity of the BMPR1A shRNA. The level of knockdown in each stable cell line was confirmed prior to performing additional experiments.
The effect of knockdown on BMPR1A protein levels was also investigated using western blot and portrayed with one representative shRNA sequence, shBMPR1A-1258 (Fig. 1C ). The relative level of BMPR1A protein in shBMPR1A-1258, was considerably reduced compared with the undifferentiated parental cell line or empty vector control line.
The reduction of BMPR1A using shRNA (shBMPR1A-1258 shown as representative of all lines) resulted in loss of SMAD1/5/8 phosphorylation (Fig. 1D ), indicating that this pathway is no longer active and thus not functioning in either the undifferentiated or competent cells, in addition to the differentiated cells that already had reduced BMPR1A pathway activation as compared with the parental cell line or one carrying the empty vector. This was consistent among all four shRNA sequences directed against Bmpr1a. Although the phosphorylation of individual SMADs was not tested, SMAD1, SMAD5 and SMAD8 are each expressed in undifferentiated HC11 cells and their gene expression unaffected by knockdown of BMPR1A (Fig. 1E ). The reduction in BMPR1A mRNA and protein by shRNA therefore results in the abrogation of endogenous canonical SMAD1/5/8 phosphorylation.
BMPR1A is required for mammary epithelial cell differentiation.
The BMP/BMPR1A signalling pathway can influence cell behaviour in many different ways, and BMPs have been identified as important cell fate regulators, required for the differentiation of other epithelial cells such as hair follicle cells.
To determine if the reduction in BMPR1A by shRNA affected mammary epithelial differentiation, total RNA and soluble proteins were extracted from each of the differentiation stages of the BMPR1A knockdown cell lines together with the control HC11 cell lines and we investigated the expression of the terminal alveolar cell differentiation marker, beta-casein. Using PCR analysis, it is apparent that there is little to no beta-casein (Csn2) gene expression in three independent clones of the representative shBMPR1A sequence, shBMPR1A-1258, that were treated with lactogenic hormones, in contrast to the parental cell lines (Fig. 2A ).
Additionally, there is little to no production of beta-casein protein in the shBMPR1A-1258 clones (Fig. 2B ) or in any of the shBMPR1A cell lines and clones upon treatment with lactogenic hormones (Fig. 2C ). Multiple stable cell lines carrying the same shRNA and as well, multiple cell lines each with different shRNA sequences all directed against Bmpr1a expression produced similar results. As a negative control, the level of beta-casein was unaffected by stable presence of the empty vector as compared with parental or the shBMPR1A-1258 cells (Fig. 2D ). These results indicate the requirement of BMPR1A and SMAD1/5/8 activation, prior to differentiation, for the ultimate differentiation of mammary epithelial cells into milk-secreting alveolar cells.
Noggin antagonizes mammary epithelial cell differentiation.
To validate our observations, we also tested the effect of the BMP antagonist, Noggin, on HC11 cell differentiation. Noggin antagonizes BMP-2, BMP-4, and BMP-7, preventing their interaction with the receptor (for review, see Botchkarev 2003). Treatment of undifferentiated cells with increasing doses of Noggin results in a severe decrease of phospho-SMAD1/5/8 (Fig. 3A ). When these cells were induced to differentiate, there was no beta-casein production compared with the control cells (Fig. 3B , C). Together, this indicates that the BMP-BMPR1A pathway is important for the phase of mammary epithelial cell differentiation characterized by beta-casein production.
Discussion
We determined that in mouse HC11 cells, differentiation into milk-producing cells was blocked with the loss the BMPR1A pathway prior to differentiation. Our investigation into the function of BMPR1A in the differentiation of mammary epithelial cells is the first indication that it could function later in mammary gland development in addition to its role in embryonic mammary gland formation.
The present analysis was based upon our previous screen to identify differentially expressed genes upon lactogenic hormone stimulation that could potentially have a role in regulating differentiation (Perotti et al. 2009). The gene for BMPR1A was preferentially expressed in undifferentiated cells, although the BMPR1A protein was present at all stages of HC11 differentiation. In this report, we determined that the BMPR1A-SMAD1/5/8 pathway is active in undifferentiated and pre-differentiated cells, but not, or is greatly reduced, in differentiated cells. It was previously reported that the activity of the estrogen receptor differs during HC11 differentiation although the estrogen receptor is expressed at all phases, potentially reflecting corepressor levels (Faulds et al. 2004). Therefore differential regulation of signal transduction pathways is possible across HC11 differentiation.
We demonstrated that the BMPR1A-SMAD1/5/8 pathway is greatly reduced upon treatment with prolactin. Prolactin is essential for lobuloalveolar differentiation (Horseman et al. 1997; Brisken et al. 1999) and may negatively affect the upstream BMPR1A-SMAD1/5/8 pathway. Prolactin inhibition of upstream pathways has been previously reported for cross-talk of the prolactin pathway with that of EGF (Haines et al. 2009). Disruption of BMPR1A expression prior to differentiation, in undifferentiated mammary epithelial cells and/or competence phases where extracellular matrix proteins are produced (Chammas et al. 1994), prevented cellular differentiation and beta-casein production. This demonstrates a requirement of the BMPR1A receptor for differentiation that is upstream of lactogenic signaling, potentially that of insulin, dexamethasone and/or prolactin. BMPR1A is required for the functional differentiation of mammary epithelial cells into milk-producing cells. Additional studies are required to explore the intricate cross-talk regulating these pathways.
Previous studies examined the phenotype of the conditional Keratin-14-Cre-BMPR1A null mouse, which targeted expression in the epithelial cells. The conditional nulls had normal mammary glands at the embryonic stage (Andl et al. 2004), indicating that the deletion of BMPR1A in Keratin-14 expressing cells has little effect on early mammary gland development. The effects of conditional deletion of BMPR1A at later stages of mammary gland development were not examined. Keratin-14 expression is essentially restricted to the basal cell layer of the mammary epithelium. It is possible, however, that BMR1A functions in the luminal cell compartment to permit alveolar cell differentiation. Our results are consistent with what is known about the role of BMPR1A in other epithelial cells, such as hair follicles. In mice, BMPR1A is required for differentiation of the inner root sheath (Andl et al. 2004) and hair shaft (Kobielak et al. 2003; Andl et al. 2004).
Transgenic doxycycline-induced expression of a conditional dominant-negative BMPR2 receptor in the mammary carcinoma model, mouse mammary tumor virus polyoma middle T antigen, did not result in disruption of mammary gland formation, at least in adult mice. The glands were not examined during pregnancy, and the endogenous BMPR2 receptors were still expressed in this mouse system. The study did indicate a tumor-suppressive role for BMPR2 (Owens et al. 2012).
Recent studies have demonstrated that mutational inactivation of BMP signaling pathways is critical to the pathogenesis of sporadic and inherited human cancer. Inherited inactivating mutations of both the Bmpr1-a/Alk3 type I receptor and the SMAD4 signaling molecule cause familial juvenile polyposis, an inherited gastrointestinal cancer predisposition syndrome (Howe et al. 1998; Howe et al. 2001) (Zhou et al. 2001; Waite and Eng 2003). There is currently little knowledge about BMP ligand and receptor function in breast cancer. BMP6 has been detected in some breast cancer cells and primary tumors (Clement et al. 1999) and BMP7 has been reported to be present in different primary breast cancers (Schwalbe et al. 2003). The mRNA levels of BMP receptor and ligand are greater in cells with high metastasic potential (Arnold et al. 1999). However, BMP2 has been shown to inhibit proliferation in breast cancer cell lines that express SMAD1 and SMAD4 (Ghosh-Choudhury et al. 2000; Pouliot and Labrie 2002). BMP2 has also been shown to enhance the migration of MCF7 breast cancer cell line and its over-expression promotes tumor formation in a breast cancer xenograft model (Clement et al. 2005). Clearly, more research is required to understand the role of BMPR1A in the normal and diseased mammary gland.
Conclusions
Our results suggest that the BMP-BMPR1A pathway, possibly via SMAD1/5/8, is required in undifferentiated and/or competent HC11 cells to allow the proper differentiation of mammary milk-secretory cells. This is the first analysis of BMPR1A function in mammary epithelial cell differentiation, and our results indicate that the pathway is required before lactogenic hormone signalling for the production of beta-casein.
References
Andl T.; Ahn K.; Kairo A.; Chu E. Y.; Wine-Lee L.; Reddy S. T.; Croft N. J.; Cebra-Thomas J. A.; Metzger D.; Chambon P. et al. Epithelial Bmpr1a regulates differentiation and proliferation in postnatal hair follicles and is essential for tooth development. Development 131(10): 2257–68; 2004.
Arnold S. F.; Tims E.; McGrath B. E. Identification of bone morphogenetic proteins and their receptors in human breast cancer cell lines: importance of BMP2. Cytokine 11(12): 1031–7; 1999.
Asselin-Labat M. L.; Sutherland K. D.; Barker H.; Thomas R.; Shackleton M.; Forrest N. C.; Hartley L.; Robb L.; Grosveld F. G.; van der Wees J. et al. Gata-3 is an essential regulator of mammary-gland morphogenesis and luminal-cell differentiation. Nat Cell Biol 9(2): 201–9; 2007.
Ball R. K.; Friis R. R.; Schoenenberger C. A.; Doppler W.; Groner B. Prolactin regulation of beta-casein gene expression and of a cytosolic 120-kd protein in a cloned mouse mammary epithelial cell line. Embo J 7(7): 2089–95; 1988.
Botchkarev V. A. Bone morphogenetic proteins and their antagonists in skin and hair follicle biology. J Investig Dermatol 120(1): 36–47; 2003.
Brisken C.; Kaur S.; Chavarria T. E.; Binart N.; Sutherland R. L.; Weinberg R. A.; Kelly P. A.; Ormandy C. J. Prolactin controls mammary gland development via direct and indirect mechanisms. Dev Biol 210(1): 96–106; 1999.
Chammas R.; Taverna D.; Cella N.; Santos C.; Hynes N. E. Laminin and tenascin assembly and expression regulate HC11 mouse mammary cell differentiation. J Cell Sci 107(Pt 4): 1031–40; 1994.
Clement J. H.; Raida M.; Sanger J.; Bicknell R.; Liu J.; Naumann A.; Geyer A.; Waldau A.; Hortschansky P.; Schmidt A. et al. Bone morphogenetic protein 2 (BMP-2) induces in vitro invasion and in vivo hormone independent growth of breast carcinoma cells. Int J Oncol 27(2): 401–7; 2005.
Clement J. H.; Sanger J.; Hoffken K. Expression of bone morphogenetic protein 6 in normal mammary tissue and breast cancer cell lines and its regulation by epidermal growth factor. Int J Cancer 80(2): 250–6; 1999.
Dai R.; Phillips R. A.; Karpuzoglu E.; Khan D.; Ahmed S. A. Estrogen regulates transcription factors STAT-1 and NF-kappaB to promote inducible nitric oxide synthase and inflammatory responses. Journal of immunology 183(11): 6998–7005; 2009.
Desrivieres S.; Prinz T.; Castro-Palmomino Laria N.; Meyer M.; Boehm G.; Bauer U.; Schäfer J.; Neumann T.; Groner B.; Shemanko C. S. Comparative proteomic analysis of proliferating and functionally differentiated mammary epithelial cells. Mol Cell Proteomics 2(10): 1039–1054; 2003.
Faulds M. H.; Olsen H.; Helguero L. A.; Gustafsson J. A.; Haldosen L. A. Estrogen receptor functional activity changes during differentiation of mammary epithelial cells. Mol Endocrinol 18(2): 412–21; 2004.
Ghosh-Choudhury N.; Ghosh-Choudhury G.; Celeste A.; Ghosh P. M.; Moyer M.; Abboud S. L.; Kreisberg J. Bone morphogenetic protein-2 induces cyclin kinase inhibitor p21 and hypophosphorylation of retinoblastoma protein in estradiol-treated MCF-7 human breast cancer cells. Biochim Biophys Acta 1497(2): 186–96; 2000.
Guha U.; Mecklenburg L.; Cowin P.; Kan L.; O'Guin W. M.; D'Vizio D.; Pestell R. G.; Paus R.; Kessler J. A. Bone morphogenetic protein signaling regulates postnatal hair follicle differentiation and cycling. Am J Pathol 165(3): 729–40; 2004.
Haines E.; Minoo P.; Feng Z.; Resalatpanah N.; Nie X. M.; Campiglio M.; Alvarez L.; Cocolakis E.; Ridha M.; Di Fulvio M. et al. Tyrosine phosphorylation of Grb2: role in prolactin/epidermal growth factor cross talk in mammary epithelial cell growth and differentiation. Mol Cell Biol 29(10): 2505–20; 2009.
Hens J. R.; Dann P.; Zhang J. P.; Harris S.; Robinson G. W.; Wysolmerski J. BMP4 and PTHrP interact to stimulate ductal outgrowth during embryonic mammary development and to inhibit hair follicle induction. Development 134(6): 1221–30; 2007.
Horseman N. D.; Zhao W.; Montecino-Rodriguez E.; Tanaka M.; Nakashima K.; Engle S. J.; Smith F.; Markoff E.; Dorshkind K. Defective mammopoiesis, but normal hematopoiesis, in mice with a targeted disruption of the prolactin gene. Embo J 16(23): 6926–35; 1997.
Howe J. R.; Bair J. L.; Sayed M. G.; Anderson M. E.; Mitros F. A.; Petersen G. M.; Velculescu V. E.; Traverso G.; Vogelstein B. Germline mutations of the gene encoding bone morphogenetic protein receptor 1A in juvenile polyposis. Nat Genet 28(2): 184–7; 2001.
Howe J. R.; Mitros F. A.; Summers R. W. The risk of gastrointestinal carcinoma in familial juvenile polyposis. Ann Surg Oncol 5(8): 751–6; 1998.
Huang H.; Song T. J.; Li X.; Hu L.; He Q.; Liu M.; Lane M. D.; Tang Q. Q. BMP signaling pathway is required for commitment of C3H10T1/2 pluripotent stem cells to the adipocyte lineage. Proc Natl Acad Sci U S A 106(31): 12670–5; 2009.
Huang W.; Ochs H. D.; Dupont B.; Vyas Y. M. The Wiskott-Aldrich syndrome protein regulates nuclear translocation of NFAT2 and NF-kappa B (RelA) independently of its role in filamentous actin polymerization and actin cytoskeletal rearrangement. J Immunol 174(5): 2602–11; 2005.
Itoh S.; Itoh F.; Goumans M. J.; Ten Dijke P. Signaling of transforming growth factor-beta family members through Smad proteins. Eur J Biochem 267(24): 6954–67; 2000.
Kobielak K.; Pasolli H. A.; Alonso L.; Polak L.; Fuchs E. Defining BMP functions in the hair follicle by conditional ablation of BMP receptor IA. J Cell Biol 163(3): 609–23; 2003.
Montesano R. Bone morphogenetic protein-4 abrogates lumen formation by mammary epithelial cells and promotes invasive growth. Biochem Biophys Res Commun 353(3): 817–22; 2007.
Montesano R.; Sarkozi R.; Schramek H. Bone morphogenetic protein-4 strongly potentiates growth factor-induced proliferation of mammary epithelial cells. Biochem Biophys Res Commun 374(1): 164–8; 2008.
Ono Y.; Calhabeu F.; Morgan J. E.; Katagiri T.; Amthor H.; Zammit P. S. BMP signalling permits population expansion by preventing premature myogenic differentiation in muscle satellite cells. Cell Death Differ 18(2): 222–34; 2011.
Owens P.; Pickup M. W.; Novitskiy S. V.; Chytil A.; Gorska A. E.; Aakre M. E.; West J.; Moses H. L. Disruption of bone morphogenetic protein receptor 2 (BMPR2) in mammary tumors promotes metastases through cell autonomous and paracrine mediators. Proc Natl Acad Sci U S A 109(8): 2814–9; 2012.
Perotti C.; Wiedl T.; Florin L.; Reuter H.; Moffat S.; Silbermann M.; Hahn M.; Angel P.; Shemanko C. S. Characterization of mammary epithelial cell line HC11 using the NIA 15k gene array reveals potential regulators of the undifferentiated and differentiated phenotypes. Differentiation 78: 269–282; 2009.
Pouliot F.; Labrie C. Role of Smad1 and Smad4 proteins in the induction of p21WAF1, Cip1 during bone morphogenetic protein-induced growth arrest in human breast cancer cells. J Endocrinol 172(1): 187–98; 2002.
Schwalbe M.; Sanger J.; Eggers R.; Naumann A.; Schmidt A.; Hoffken K.; Clement J. H. Differential expression and regulation of bone morphogenetic protein 7 in breast cancer. Int J Oncol 23(1): 89–95; 2003.
Shackleton M.; Vaillant F.; Simpson K. J.; Stingl J.; Smyth G. K.; Asselin-Labat M. L.; Wu L.; Lindeman G. J.; Visvader J. E. Generation of a functional mammary gland from a single stem cell. Nature 439(7072): 84–8; 2006.
Shitashige M.; Naishiro Y.; Idogawa M.; Honda K.; Ono M.; Hirohashi S.; Yamada T. Involvement of splicing factor-1 in beta-catenin/T-cell factor-4-mediated gene transactivation and pre-mRNA splicing. Gastroenterology 132(3): 1039–54; 2007.
Sleeman K. E.; Kendrick H.; Ashworth A.; Isacke C. M.; Smalley M. J. CD24 staining of mouse mammary gland cells defines luminal epithelial, myoepithelial/basal and non-epithelial cells. Breast Cancer Res 8(1): R7; 2006.
Stingl J.; Eirew P.; Ricketson I.; Shackleton M.; Vaillant F.; Choi D.; Li H. I.; Eaves C. J. Purification and unique properties of mammary epithelial stem cells. Nature 439(7079): 993–7; 2006.
Waite K. A.; Eng C. BMP2 exposure results in decreased PTEN protein degradation and increased PTEN levels. Hum Mol Genet 12(6): 679–84; 2003.
Welm B. E.; Tepera S. B.; Venezia T.; Graubert T. A.; Rosen J. M.; Goodell M. A. Sca-1(pos) cells in the mouse mammary gland represent an enriched progenitor cell population. Dev Biol 245(1): 42–56; 2002.
Zhang J.; He X. C.; Tong W. G.; Johnson T.; Wiedemann L. M.; Mishina Y.; Feng J. Q.; Li L. Bone morphogenetic protein signaling inhibits hair follicle anagen induction by restricting epithelial stem/progenitor cell activation and expansion. Stem Cells 24(12): 2826–39; 2006.
Zhou X. P.; Woodford-Richens K.; Lehtonen R.; Kurose K.; Aldred M.; Hampel H.; Launonen V.; Virta S.; Pilarski R.; Salovaara R. et al. Germline mutations in BMPR1A/ALK3 cause a subset of cases of juvenile polyposis syndrome and of Cowden and Bannayan–Riley–Ruvalcaba syndromes. Am J Hum Genet 69(4): 704–11; 2001.
Acknowledgments
In memory of Nadia Widmann, undergraduate researcher. This research was supported by the Natural Sciences and Engineering Research Council of Canada.
Open Access
This article is distributed under the terms of the Creative Commons Attribution License which permits any use, distribution, and reproduction in any medium, provided the original author(s) and the source are credited.
Author information
Authors and Affiliations
Corresponding author
Additional information
Editor: T. Okamoto
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 2.0 International License (https://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
About this article
Cite this article
Perotti, C., Karayazi, Ö., Moffat, S. et al. The bone morphogenetic protein receptor-1A pathway is required for lactogenic differentiation of mammary epithelial cells in vitro. In Vitro Cell.Dev.Biol.-Animal 48, 377–384 (2012). https://doi.org/10.1007/s11626-012-9522-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11626-012-9522-z