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First published online 14 February 2007
doi: 10.1242/dev.000182
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1 Section of Endocrinology and Metabolism, Department of Internal Medicine, Yale
University School of Medicine, New Haven, CT 06520-8020, USA.
2 Department of Periodontics, University of Texas Health Science Center at San
Antonio, San Antonio, TX, USA.
3 Laboratory of Genetics and Physiology, NIDDK, NIH, Bethesda, MD, USA.
* Author for correspondence (e-mail: john.wysolmerski{at}yale.edu)
Accepted 9 January 2007
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SUMMARY |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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Key words: Mammary gland, Breast, Hair follicle, Epidermal appendages, Branching morphogenesis, Parathyroid hormone-related protein (PTHrP), Bone morphogenic proteins
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INTRODUCTION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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;
Veltmaat et al., 2003;
Robinson et al., 1999).
The development of the embryonic mammary gland depends on a series of
reciprocal interactions between epithelial and mesenchymal cells, which guide
the formation of the placodes and buds, establish mammary cell fates and
initiate the three-dimensional morphogenesis necessary for the formation of
the primary ductwork (Hens and
Wysolmerski, 2005; Veltmaat et
al., 2003; Robinson et al.,
1999). Our understanding of the molecular events underpinning
early mammary development remains rudimentary, but recent work has begun to
characterize some of the mediators of these crucial epithelial-mesenchymal
interactions. Like in other organs, members of the FGF, hedgehog, WNT and EGF
growth factor signaling pathways play important roles in the patterning and
formation of the initial mammary placodes
(Chu et al., 2004;
Davenport et al., 2003;
Eblaghie et al., 2004;
Hatsell and Cowin, 2006;
Howard et al., 2005;
Mailleux et al., 2002;
Veltmaat et al., 2004;
Veltmaat et al., 2006). As
discussed below, parathyroid hormone related protein (PTHrP; also known as
parathyroid hormone-like peptide, Pthlh) and its receptor are important to the
formation of the mammary mesenchyme and outgrowth of the nascent mammary ducts
(Hens and Wysolmerski, 2005).
However, little else is known of the signaling pathways mediating the initial
wave of branching morphogenesis that gives rise to the primary duct
system.
PTHrP was originally discovered as the cause of a common paraneoplastic
syndrome known as humoral hypercalcemia of malignancy
(Wysolmerski and Broadus,
1994). PTHrP is structurally related to parathyroid hormone (PTH),
which is the principal regulator of circulating calcium levels in tetrapods
(Philbrick et al., 1996). The
high degree of homology between the amino-termini of the two proteins allows
both PTH and PTHrP to share a common G protein-coupled receptor named the Type
1 PTH/PTHrP receptor (PTH1R, also known as Pthr1)
(Juppner et al., 1991). Thus,
when PTHrP is made by tumors and is secreted into the circulation it mimics
the actions of PTH and causes hypercalcemia. However, with the exception of
lactation, PTHrP normally does not circulate, but rather is secreted locally
to exert autocrine, paracrine and intracrine functions
(Philbrick et al., 1996;
DeMauro and Wysolmerski, 2005;
Dunbar and Wysolmerski, 1999;
Dunbar et al., 1998;
Wysolmerski et al., 1998;
Wysolmerski et al., 1994).
PTHrP and the PTH1R are both expressed widely during embryonic development,
often in adjacent cell types (Lee et al.,
1995). Experiments in genetically manipulated mice have documented
important functions for this signaling pathway during bone, tooth, skin, lung
and mammary gland development (Philbrick
et al., 1996; Wysolmerski and
Stewart, 1998; Hastings,
2004; Foley et al.,
2001; Lanske et al.,
1998). The study of fetuses with loss-of-function mutations in the
PTH1R gene has confirmed the importance of PTHrP signaling to proper bone and
breast development in humans as well
(Wysolmerski et al.,
2001).
PTHrP and the PTH1R are both required for normal mammary gland development.
Disruption of either gene in mice and loss of PTH1R function in humans results
in the complete absence of the mammary epithelium
(Wysolmerski et al., 1998;
Dunbar and Wysolmerski, 1999;
Foley et al., 2001). During
murine development, PTHrP is prominently expressed within mammary epithelial
cells, beginning on day E11 concurrent with the formation of the mammary
placodes. The PTH1R is expressed on immature mesenchymal cells located beneath
the entire epidermis. As the mammary bud is invaginating, PTHrP acts on its
receptor to induce the differentiation of the surrounding mesenchyme into the
specialized condensed mammary mesenchyme. Stimulation by PTHrP is required for
this mesenchyme to perform three vital functions: (1) to maintain the mammary
fate of the epithelial cells; (2) to trigger the overlying epidermis to form
the nipple sheath; and (3) to initiate ductal outgrowth and morphogenesis. In
the absence of PTHrP signaling, mammary epithelial cells differentiate into
skin cells, no nipple is formed and morphogenesis is interrupted
(Wysolmerski et al., 1998;
Dunbar et al., 1999;
Foley et al., 2001).
Conversely, overexpression of PTHrP in the basal keratinocytes of transgenic
mice using the keratin 14 promoter (K14-PTHrP mice) leads to the conversion of
the subepidermal mesenchyme from dermis into condensed mammary mesenchyme
(Foley et al., 2001). This, in
turn, suppresses hair follicle development and causes the epidermis to acquire
the characteristics of the nipple sheath. However, curiously, the epidermal
phenotype of the K14-PTHrP mice is restricted to the ventral surface of the
mouse between the borders of the original mammary lines, suggesting that this
area represents a specific zone of sensitivity to the effects of PTHrP
(Dunbar et al., 1999;
Foley et al., 2001).
Bone morphogenetic proteins (BMPs) have been shown to be important to the
dorsoventral patterning of early embryos
(Reversade et al., 2005;
Pyati et al., 2005;
De Robertis and Kuroda, 2004).
In addition, Zhang and colleagues have reported the BMP4 gene to be strongly
expressed within the developing ventral epidermis at E13.5
(Zhang et al., 2002). BMPs
constitute a large family of secreted growth factors that are involved in many
aspects of development and that have been implicated as classical morphogens
because of their ability to alter cell fate in a concentration-dependent
fashion (Gurdon and Bourillot,
2001; O'Connor et al.,
2006; Rosen,
2006). BMPs signal through a heteromeric complex of type I and II
receptor serine/threonine kinases
(Massague, 1996). Binding of
BMPs to their cognate receptors induces phosphorylation of members of the
receptorregulated SMAD family (rSMADs). Once phosphorylated, rSMADs associate
with SMAD4, translocate into the nucleus and regulate the transcription of
specific genes (Massague and Chen,
2000; von Bubnoff and Cho,
2001). In addition, BMP signaling is modulated by a complex series
of interacting factors such as secreted inhibitors, specific inhibitory Smads
and interactions between Smads and other transcription factors such as
ß-catenin and LEF1 (Labbe et al.,
2000; Massague and Chen,
2000; von Bubnoff and Cho,
2001; Rosen, 2006;
Hussein et al., 2003;
Sakai et al., 2005).
MSX1 and MSX2 are BMP-responsive homeodomain-containing transcription
factors that have been shown to participate in the relay of signals between
epithelium and mesenchyme during development
(Phippard et al., 1996;
Satoh et al., 2004;
Satokata et al., 2000). Both
are particularly important to the normal development of epidermal appendages,
including the mammary gland. MSX1 and MSX2 are each expressed in the
epithelial cells of the forming mammary bud, and in mice with both genes
deleted, mammary development fails at the placode stage
(Satokata et al., 2000). MSX2,
but not MSX1, is also expressed within the dense mammary mesenchyme
surrounding the mammary epithelial cells, and after E14.5 its expression
becomes restricted to the mesenchymal compartment
(Phippard et al., 1996;
Satokata et al., 2000).
Similar to the phenotype of PTHrP-/- mice, mammary buds are
reported to form in MSX2-/- mice, but their development arrests at
E16.5 and no ductal outgrowth is formed
(Satokata et al., 2000).
Interestingly, activation of the PTH1R modulates Msx2 gene expression
in aortic adventitial cells and in osteoblasts
(Shao et al., 2003;
Shao et al., 2005;
Bidder et al., 1998;
Dodig et al., 1999;
Towler et al., 2006).
In this study, we examined potential interactions between PTHrP and BMP signaling during early embryonic mammary gland development. We demonstrate that PTHrP signaling is permissive for BMP signaling in the mammary mesenchyme. This interaction, in turn, activates Msx2 gene expression within the mesenchymal cells, which enables them to suppress hair follicle formation in the overlying nipple skin. PTHrP and BMP signaling also cooperate to enable the mesenchyme to initiate outgrowth of the mammary epithelial buds.
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MATERIALS AND METHODS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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).
Bmp4-lacZneo, K14-PTHrP, PTHrP-/- and
PTH1R-/- mice were identified as described previously
(Wysolmerski et al., 1998;
Foley et al., 2001;
Zhang et al., 2002).
Histology and immunohistochemistry
Histology and immunohistochemistry were performed using standard
techniques. Skin samples were fixed overnight in 4% paraformaldehyde or
Bouin's and were embedded in paraffin. Antigen retrieval was performed by
heating sections in 7 mM citrate under pressure, after which incubation with
primary antibody was carried out for 12 hours at 4°C. Antibodies to
filaggrin, K14 and tenascin C (Covance, Berkeley CA) were detected with the
Vector Elite ABC kits (Vector Laboratories, Burlingame. CA) and 3,3'
diaminobenzidine as a chromagen. ß-Catenin antibodies (Transduction
Laboratories, Lexington KY) were detected with a goat anti-mouse
Alexa546-conjugated secondary antibody (Molecular Probes, Eugene, OR).
Western blotting
C3H10T1/2 cells (a gift from Dr Mark Horowitz, New Haven, CT) and C2C12
cells (from ATCC) were cultured in 10% fetal bovine serum (FBS), 0.2 mM
L-glutamine on 100 mm Falcon culture dishes (Becton-Dickinson, Franklin Lakes,
NJ). For BMP2 or BMP4 stimulation, media was changed to 0.1% FBS the day
before treatment. Cells were treated with 0, 10, 50 and 100 ng/ml recombinant
BMP4 or BMP2 (R&D Systems, Minneapolis, MN) with or without
10-7 M PTHrP (Sigma-Aldrich, St Louis, MO) and were harvested after
18-20 hours' exposure. For protein detection, cells were homogenized in PBS
containing a cocktail of protease inhibitors (Complete protease inhibitor
cocktail tablets, Roche Diagnostics, Mannheim, Germany) and phosphatase
inhibitors (Phosphatase Inhibitor Cocktail Set II, Calbiochem, La Jolla CA).
Lysates (50 µg) were run on an 8% SDS-PAGE reducing gel and transferred to
a nitrocellulose membrane. Membranes were blocked for 1 hour in 3% dried milk
in PBS, and then were incubated in the same solution with the following
antibodies: rabbit anti-phospho-SMAD 1,5,8 (Cell Signaling Technology,
Danvers, MA), mouse anti-MSX2 (4G1) (Developmental Studies Hybridoma Bank),
and mouse anti-actin (Sigma-Aldrich). Goat anti-rabbit and goat anti-mouse
secondary antibodies (Sigma-Aldrich) were used at 1/5000 dilution. Proteins
were detected using chemiluminescence (Supersignal, Pierce, Rockford, IL).
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). The probe for MSX2 was a kind gift of Dr Richard Maas and
has been previously described (Satokata et
al., 2000). BMP receptor probes were a generous gift of Dr Vicki
Rosen (Boston, MA). Sense and antisense probes were generated from linearized
fragments using an in vitro transcription kit (Promega, Madison WI) in the
presence of [35S]UTP (1000 Ci/mmol, Amersham, Life Science,
Arlington Heights, IL).
RNA isolation and RT-PCR
Total RNA was isolated from cells or tissue using Trizol reagent (Gibco,
Gaithersville, MD) and samples were treated with DNase as described by the
manufacturer (GenHunter Corp., Nashville, TN). Quantitative RT-PCR (qRT-PCR)
was performed by standard methods using the OpticonII DNA engine (JM Research,
Waltham, MA). The mouse gene expression assay (Applied Biosystems, Foster
City, CA) was used for MSX2 (Mm00442992_m1). We generated the following primer
sets for SYBR-Green-based qRT-PCR: BMPr1a forward primer
5'-GGTATCTGGGTCAAAGCTGTTC-3' and reverse primer
5'-CCTGCTGTCTCACTGGTGTAAG-3', which spans nucleotides 87-244 of
the BMPr1a coding sequence (NM_009758). Probe-based qRT-PCR was performed with
Brilliant qRT-PCR master mix (Stratagene, La Jolla, CA) and SYBR-Green-based
qRT-PCR was performed with Brilliant SYBR-Green qRT-PCR master mix
(Stratagene). Samples were normalized for relative quantification of
expression by the 2-
CT method (Applied Biosystems
1997). Relative quantitation of gene expression: ABI Prism 7700 sequence
detection system, user bulletin 2, revision B. Samples were run in duplicate.
cDNA was prepared using the ABI PRISM as per the manufacturer's
instructions.
Embryo and mammary bud cultures
Freshly harvested E13 embryos were decapitated and placed on PET
track-etched membrane cell culture inserts containing 0.4 µm pores (Becton
Dickinson) in six-well plates. Embryos were cultured in F12/DMEM media
containing 10% FBS and antibiotics. Embryos were treated for 12-16 hours with
or without 10-7 M PTHrP (Sigma) after which ventral and/or dorsal
epidermis was dissected and used to make RNA.
In order to prepare bud cultures, individual mammary buds were microdissected from E13 wild-type and PTHrP-/- embryos and placed on Whatman 13 mm nuclepore Track-etched membranes (8 µm pore size; Thomas Scientific, Swedesboro, NJ) on top of a tuft of ventral mesenchyme. All dissections were performed in DMEM at 4°C. The filters were cultured on EC587-40 mesh screen grills (Thomas Scientific, Swedesboro, NJ) in six-well plates containing 10% FBS in DMEM/F12 media with antibiotics. Media was changed every other day for the length of the experiment. Bud cultures were fixed in acid alcohol and stained in carmine alum. Stained tissue was then dehydrated and mounted in Permount (Fisher Scientific, NJ) for viewing.
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RESULTS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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). These
changes in cell fate are restricted to the ventral surface of the embryo,
despite the fact that both the K14-PTHrP transgene and the PTH/PTHrP receptor
are expressed within both the dorsal and ventral surfaces of the embryo.
Therefore, we hypothesized that the effects of PTHrP on mammary mesenchyme and
skin differentiation depend on the cooperation of some other, ventrally
restricted, signaling pathway. Recently, using a mouse in which the
lacZ gene was knocked into the Bmp4 gene locus, Zhang and
colleagues reported that BMP4 expression was strongly expressed within the
ventral surface of E13.5 embryos (Zhang et
al., 2002). Using the same model, we examined the expression of
BMP4 during mammary bud formation. As shown in
Fig. 1, BMP4 was expressed in
mesenchymal cells underlying the ventral epidermis between the four limb buds.
BMP4 was also expressed in epithelial cells of the mammary bud, but was not
expressed within keratinocytes. This pattern of expression was present between
E11.5 and E14.5, after which the lacZ expression became primarily
associated with developing hair follicles.
Because the pattern of BMP4 expression in the subepidermal mesenchyme was
essentially identical to the pattern of ectopic mammary mesenchyme in
K14-PTHrP embryos (Foley et al.,
2001), we next examined the possibility that PTHrP and BMP4
signaling interact during the formation of mammary buds. BMP signaling is
complex, but BMP4 is typically thought to induce the phosphorylation of
rSMADs, which includes SMADs 1, 5 and 8
(Massague and Chen, 2000).
Therefore, we examined the pattern of SMAD phosphorylation in wild-type
mammary buds and in genetic models of loss and gain of PTHrP function using an
antibody specific for the phosphorylated forms of these three SMADs. As
demonstrated in Fig. 2, we
performed immunohistochemistry on mammary buds from wild-type,
PTHrP-/- and PTH1R-/- mammary buds harvested at E15.5.
Wild-type buds were positive for nuclear phospho-SMAD 1, 5, 8 in both the
epithelial and mesenchymal compartments
(Fig. 2B). Furthermore, only
the mammary mesenchyme and not the general dermal mesenchyme stained. By
contrast, in PTHrP-/- and PTH1R-/- buds, phospho-SMAD 1,
5, 8 staining was significantly reduced in the mammary mesenchyme compared
with the wild-type buds (Fig.
2A,C). We also compared phospho-SMAD 1, 5, 8 staining in the
ventral skin of K14-PTHrP mice to that in wild-type ventral skin. As shown in
Fig. 2D, there was little
phospho-SMAD staining in the dermis of wild-type mice at E18.5, but there was
prominent staining in the ectopic mammary mesenchyme beneath the ventral skin
of K14-PTHrP littermates (Fig.
2E). Dorsal skin from wild-type and K14-PTHrP mice showed
phospho-SMAD staining associated with developing hair follicles and their
associated mesenchyme, but there was no significant staining in the
interfollicular dermis of either genotype (data not shown). These results
demonstrate that alterations of PTHrP signaling in embryonic mammary buds and
skin lead to changes in SMAD phosphorylation within mesenchymal cells, but
only within the ventral zone of BMP4 expression in vivo, suggesting that PTHrP
signaling may interact with BMP signaling in these cells.
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PTHrP augments BMP signaling through regulation of BMPR1A expression
We next attempted to define a mechanism by which PTHrP might sensitize the
mammary mesenchyme to the actions of BMP. A previous report had suggested that
PTHrP increased the expression of the BMPR1A in C3H10T1/2 cells as assessed by
Northern blot (Chan et al.,
2003). We confirmed this observation by performing qRT-PCR on RNA
prepared from C3H10T1/2 cells treated with 10-7 M PTHrP for 18-20
hours. As seen in Fig. 3A, this
resulted in an approximate doubling of BMPr1a mRNA levels. We next asked if
PTHrP was able to increase the expression of BMPr1a mRNA in mammary mesenchyme
in vivo. First, we performed in situ hybridization to examine BMPr1a
expression in embryonic mammary buds. Fig.
3E,F demonstrates the results for wild-type buds at E15.5. As one
can see, BMPr1a mRNA was expressed at low levels throughout the entire
subepidermal mesenchyme, including the dense mammary mesenchyme. It was
difficult to determine if there was specific expression within the epidermis,
but the gene was not expressed within mammary epithelial cells at this stage
of development. We did not detect clear differences in expression of BMPr1a
within the mammary mesenchyme of PTHrP-/- buds or within the
ectopic mammary mesenchyme beneath the ventral epidermis of K14-PTHrP mice by
in situ hybridization (data not shown). Because this receptor appeared to be
expressed at low levels in the mesenchyme and because in situ hybridization is
not a sensitive quantitative technique, we also addressed this question by
performing qRT-PCR on samples of skin and mammary buds microdissected from
pharmacologically and genetically manipulated embryos. Wild-type E13.5 embryos
were cultured for 18-20 hours in the presence or absence of 10-7 M
PTHrP. The ventral epidermis and its associated mesenchyme were then removed
and assayed for BMPr1a mRNA expression by qRT-PCR. As seen in
Fig. 3B, PTHrP treatment
resulted in an approximate doubling of BMPr1a gene expression in the
ventral epidermis, a result similar to its effects on BMPr1a gene
expression in C3H10T1/2 cells. BMPr1a mRNA expression also was
increased in ventral skin isolated from K14-PTHrP embryos at day E18
(Fig. 3C). Finally, we examined
the relative levels of BMPr1a mRNA in freshly isolated mammary buds
from E15.5 wild-type and PTHrP-/- embryos. As seen in
Fig. 3D, BMPr1a mRNA
levels were reduced by 75% in the PTHrP-/- buds compared with
wild-type buds. As the Pth1r and BMPr1a genes are expressed
on mesenchymal cells in embryonic skin and mammary buds, these data suggest
that PTHrP secreted by the embryonic mammary buds regulates expression of the
BMPr1a gene in mammary mesenchyme.
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),
mammary buds were isolated from wild-type and PTHrP-/- embryos and
were cultured with extra tufts of ventral mesenchyme on nucleopore filters.
After 7 days in the presence or absence of 10-7 M PTHrP, or 5 ng/ml
or 10 ng/ml BMP4, cultures were scored for bud outgrowth. A bud was considered
to have grown out normally if the length of the initial sprout was more then
the length of the bud itself and if at least one branch point had formed.
Fig. 4A-D demonstrate the
typical appearance of the cultures, and
Fig. 4E shows the
quantification of outgrowth from multiple bud cultures. As can be seen, after
7 days in culture, wild-type buds produced an elongated sprout with several
primary branches in approximately 70% of the cultures
(Fig. 4A,E). The degree of
branching of the outgrowths was variable but reminiscent of the normal
embryonic duct system at E18.5 (Hens and
Wysolmerski, 2005). By contrast, as depicted in
Fig. 4B, the majority of
PTHrP-/- buds failed to sprout, with only 10% of the buds showing
outgrowth (Fig. 4E). Growth of
PTHrP-/- buds was restored by the addition of PTHrP to the media
(45% of cultures sprouted, Fig.
4C,E). In addition, treatment of PTHrP-/- bud cultures
with BMP4 also rescued bud outgrowth so that 56% of buds met our sprouting
criteria (Fig. 4D,E). The
addition of equivalent concentrations of PTHrP or BMP4 to wild-type buds had
no effect on bud outgrowths (data not shown). Finally, we examined the effects
of inhibiting BMP signaling on the growth of wild-type buds by using the
soluble BMP inhibitor, noggin (Rosen,
2006; Botchkarev et al.,
1999). As shown in Fig.
4E, the addition of noggin, a secreted BMP inhibitor, to wild-type
buds reduced the likelihood of outgrowth by half so that only 33% of
noggin-treated wild-type buds sprouted compared with the 68% of control buds
that sprouted. These data demonstrate that both PTHrP and BMP signaling are
important to the initiation of normal bud outgrowth. Furthermore, the ability
of BMP4 to complement the loss of PTHrP in mammary bud cultures strongly
suggests that BMP4 signaling acts downstream of PTHrP to initiate ductal
branching morphogenesis from embryonic mammary buds.
|
). In fact, mammary development in MSX2-/-
mice has been reported to arrest after the formation of an apparently normal
bud, a phenotype remarkably similar to that seen in PTHrP-/-
embryos (Satokata et al.,
2000). Furthermore, in vascular cells, MSX2 expression is
regulated by both BMPs and parathyroid hormone
(Shao et al., 2003;
Shao et al., 2005). For these
reasons, we hypothesized that MSX2 might mediate the effects of combined PTHrP
and BMP signaling in the mammary bud.
In order to explore this hypothesis, we first examined Msx2 expression in
wild-type, PTHrP-/- and PTH1R-/- mammary buds in vivo by
in situ hybridization. As previously described, we found the Msx2
gene to be expressed within the mammary mesenchyme in wild-type buds at E15.5
(Fig. 5B,E)
(Satokata et al., 2000;
Phippard et al., 1996).
Interruption of PTHrP signaling through disruption of either the
Pthrp or Pth1r genes resulted in a significantly reduced
level of Msx2 mRNA in the mammary mesenchyme
(Fig. 5A,D,C,F). Furthermore,
Msx2 gene expression was prominently and ectopically induced in the
ventral dermis by expression of PTHrP in the basal keratinocytes of K14-PTHrP
transgenic mice (compare Fig. 5G,H with
5I,J). Thus, in vivo, MSX2 expression correlates with alterations
in PTHrP signaling as well as the parallel alterations of BMP signaling
demonstrated in Fig. 2.
We next examined changes in Msx2 mRNA levels in response to PTHrP and BMP signaling in C3H10T1/2 cells in order to test directly if PTHrP and BMP signaling interact to regulate Msx2 expression. As shown in Fig. 6, treatment of the cells with either PTHrP or BMP4 alone modestly stimulated Msx2 mRNA expression. However, the combination of PTHrP and BMP4 augmented Msx2 expression to a much greater extent. These data again demonstrate that PTHrP and BMP signaling interact and identify the Msx2 gene as a target of the cooperative interaction between the two.
|
). As a
result, the ventral epidermis of K14-PTHrP mice is thickened, lacks hair
follicles and displays characteristic alterations in keratin and filaggrin
expression. In addition, the dermis in these mice is hypercellular and
expresses markers usually restricted to the mammary mesenchyme
(Foley et al., 2001). As is
evident from Fig. 7, disruption
of the Msx2 gene mitigated the K14-PTHrP phenotype but did not
completely reverse it. The most striking finding was the recovery of hair
follicle development in the K14-PTHrP/MSX2-/- embryos
(Fig. 7C). Although deletion of
MSX2 has been reported to cause abnormal hair cycling, the initial development
of follicles in the embryo is normal
(Satokata et al., 2000;
Ma et al., 2003). As one can
see, removing MSX2 from the K14-PTHrP epidermis led to the recovery of hair
follicle induction in the ventral skin. In addition, there was some resolution
of the epidermal thickening and the dermis was less compact in
K14-PTHrP/MSX2-/- embryos compared with K14-PTHrP controls.
However, there was no change in epidermal expression of keratin 14 or
filaggrin in the ventral skin of K14-PTHrP/MSX2-/- embryos compared
with the changes in the expression of these markers previously documented in
the ventral mesenchyme of K14-PTHrP embryos (data not shown). Furthermore,
K14-PTHrP/MSX2-/- embryos continued to express ectopic markers of
the mammary mesenchyme such as LEF1, ß-catenin, androgen receptor and
tenascin C in the ventral dermis, despite the clear morphological changes
noted above (data not shown). These data identify MSX2 as a crucial
mesenchymal factor that allows PTHrP and BMP4 to suppress hair follicle
induction in the vicinity of the developing mammary bud and nipple.
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|
DISCUSSION |
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|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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;
Dunbar et al., 1998;
Foley et al., 2001). The
current study suggests that PTHrP acts, at least in part, by modulating BMP
signaling in mammary mesenchyme cells. We show that during the formation of
the mammary buds, BMP4 is expressed by mesenchymal cells on the ventral
surface of the embryo. PTHrP signaling sensitizes mesenchymal cells to BMP in
vitro and in vivo, by increasing the expression of the BMP1A receptor. The
interaction between PTHrP and BMP4 is important for mammary bud sprouting and
BMP4 treatment can rescue outgrowth of PTHrP-/- mammary buds in
organ culture. Finally, we demonstrate that the combination of PTHrP and BMP
signaling increases the expression of the homeobox gene, MSX2, in the mammary
mesenchyme, which, in turn, allows PTHrP to suppress hair follicle formation
in the vicinity of the developing mammary bud and nipple.
Our data showing that PTHrP signaling upregulates the expression of the
BMPR1A in the mammary mesenchyme are similar to those of Chan and colleagues
(Chan et al., 2003), who
demonstrated an increase in the expression of this receptor in response to
PTHrP in the pluripotent mesenchymal cell line, C3H10T1/2. Using qRT-PCR, we
showed an approximate doubling of Bmpr1a expression in these same
cells when they were treated with PTHrP. In addition, we saw a doubling of
Bmpr1a mRNA expression in the skin of embryos treated with PTHrP ex
vivo as well as in the epidermis of K14-PTHrP embryos overexpressing PTHrP in
basal keratinocytes. We also noted a 75% reduction in the level of
Bmpr1a mRNA in mammary buds microdissected from PTHrP-/-
embryos compared with buds derived from wild-type littermates, demonstrating
that PTHrP expression by mammary epithelial cells is important to the native
level of BMPR1A expression surrounding the buds. Although we could not detect
a difference in Bmpr1a gene expression by in situ hybridization,
these experiments did demonstrate that the receptor is expressed in
mesenchymal cells and not in mammary epithelial cells during early bud
development, suggesting that the alterations in expression noted above are
likely to be in the mammary mesenchyme surrounding the developing bud and in
the ectopic mammary mesenchyme that forms under the epidermis in K14-PTHrP
embryos. This conclusion is also consistent with the localization of PTH1R
expression in mesenchymal cells at this stage of development
(Dunbar et al., 1998).
Finally, results from a model of transgenic overexpression of PTHrP in
developing lung also demonstrate upregulation of Bmpr1a gene
expression in response to PTHrP (W. Philbrick, personal communication). Thus,
PTHrP may regulate BMP receptor expression in several organs and modulation of
BMP signaling may be a more general feature of the actions of PTHrP during
development.
|
). Interestingly, these changes occur only on the ventral
surface of the embryo, despite the fact that the K14-PTHrP transgene is
expressed in both ventral and dorsal keratinocytes and that the PTH1R is
expressed on mesenchymal cells in the dermis on both surfaces. In addition, it
has been shown that dermal mesenchyme harvested from the ventral surface of
the embryo responds to the mammary epithelial bud by upregulating expression
of the androgen receptor (a marker of the mammary mesenchyme), whereas
mesenchyme from the dorsal skin does not
(Heuberger et al., 1982)
(G.W.R. and K. Kratochwil, unpublished). Our findings offer a potential
explanation for these observations. We propose that PTHrP acts to promote
mammary mesenchyme differentiation and bud outgrowth by modulating mesenchymal
cell responsiveness to BMPs. Therefore, the presence of a specific BMP is
needed for the full expression of the effects of PTHrP. In essence, the
pattern of BMP4 expression creates a ventrally restricted zone of
responsiveness to the effects of PTHrP. In the case of normal mammary
development, the expression of BMP4 in the ventral mesenchyme coincides with
the formation of the mammary buds, which express PTHrP and allows both
signaling pathways to interact to form the mammary-specific mesenchyme. In the
setting of the K14-PTHrP transgene, ectopic formation of mammary mesenchyme is
restricted to the ventral area of BMP 4 expression.
Deletion of the PTHrP gene in mice and humans leads to a failure of the
mammary bud to initiate branching morphogenesis
(Wysolmerski et al., 1998;
Wysolmerski et al., 2001).
Culture of PTHrP-/- mammary buds ex vivo recapitulates the failure
of bud outgrowth in vivo. While 70% of wild-type mammary buds initiated
branching growth in culture, only 10% of PTHrP-/- buds did so, a
defect rescued by the addition of PTHrP to the culture media. Significantly,
the addition of BMP4 to the bud cultures was able to complement the loss of
PTHrP and also rescue outgrowth of PTHrP-/- buds. Furthermore,
noggin treatment was able to inhibit the growth of wild-type buds. These
experiments suggest that BMP4 acts downstream of PTHrP to initiate outgrowth
of the mammary buds. BMP4 has been shown to regulate branching morphogenesis
in several other organs including the lung, submandibular gland, prostate,
kidney and ureter (Eblaghie et al.,
2006; Shao et al.,
2005; Martinez et al.,
2002; Miyazaki et al.,
2000; Bellusci et al.,
1996; Bragg et al.,
2001; Weaver et al.,
2000; Lamm et al.,
2001; Dean et al.,
2004; Shi et al.,
2001). Its role has been best studied in the lung, where it
appears either to stimulate or inhibit branching, depending on the
experimental context (Eblaghie et al.,
2006; Shao et al.,
2005; Bellusci et al.,
1996; Bragg et al.,
2001; Weaver et al.,
2000; Shi et al.,
2001). Some of these conflicting effects may be related to the
level of BMP signaling or to differing effects on epithelial cells versus
mesenchymal cells. In the mammary bud, our results suggest that PTHrP-mediated
upregulation of BMPR1A expression allows for spatially restricted, autocrine
or paracrine BMP signaling within the mesenchyme. We believe that this BMP
signal, in turn, enables mammary mesenchyme cells to trigger and/or support
outgrowth of the bud epithelium.
In addition to promoting bud outgrowth, the mammary-specific mesenchyme
instructs the overlying epidermis to form the nipple sheath, an activity that
is also dependent on PTHrP signaling. A prominent feature of the nipple sheath
is its lack of hair, which is probably the result of lateral inhibition of
hair follicle formation by PTHrP secreted by the epithelial bud. In the
absence of PTHrP or the PTH1R, hair follicles develop too close to the mammary
bud, and in the presence of PTHrP misexpression by basal keratinocytes, hair
follicle development is suppressed throughout the entire ventral epidermis
(Foley et al., 2001;
Wysolmerski et al., 1994). We
now find that the ability of PTHrP to suppress hair follicle development
depends on the actions of the homeobox transcription factor MSX2. Confirming
previous reports, using in situ hybridization we found that MSX2 was expressed
within the mammary mesenchyme (Phippard et
al., 1996; Satokata et al.,
2000). Furthermore, mesenchymal expression of MSX2 requires PTHrP
signaling, because MSX2 levels were reduced around PTHrP-/- buds
and MSX2 expression was induced within the ectopic mammary mesenchyme formed
beneath the ventral epidermis in K14-PTHrP transgenic mice. The ventral
restriction of MSX2 induction in these mice suggests that this transcription
factor is a specific target of the interaction between PTHrP and BMP signaling
discussed previously. This is not surprising, given the fact that MSX2 is
known to be regulated by BMPs in several sites during development
(Kratochwil et al., 1996;
Andl et al., 2004;
Towler et al., 2006;
Hussein et al., 2003). It is
also consistent with our data in vitro showing that while PTHrP or BMP4 alone
have only a modest effect on MSX2 expression in C3H10T1/2 cells, the
combination has a robust inductive effect on its expression. Given these
results, it will be interesting to determine whether PTHrP might potentiate
the effects of BMPs on MSX2 expression in other developing organs as well.
BMPs are known to suppress hair follicle formation, and antagonism of BMP
signaling in the mesenchyme by secreted BMP inhibitors is thought to be
important for the induction of at least some classes of hair follicles
(Kobielak et al., 2003;
Botchkarev et al., 2002;
Andl et al., 2004;
Botchkarev et al., 1999).
Furthermore, BMP signaling is thought to be important for lateral inhibition
and spacing of hair follicles and feathers
(Jung et al., 1998;
Noramly et al., 1999;
Mou et al., 2006). Therefore,
the sensitization of mesenchymal cells to BMP4 signaling by PTHrP might be
expected to suppress hair follicle formation, as happens on the ventral
surface of K14-PTHrP mice and around the mammary buds and nipple. Because
crossing the K14-PTHrP transgene onto an MSX2-/- background led to
the recovery of hair follicle formation in the ventral surface of
K14-PTHrP/MSX2-/- mice, it would also appear that PTHrP and BMP4
interact to suppress hair development by inducing Msx2 in the mammary
mesenchyme. Like mammary glands, hair follicle induction requires reciprocal
interactions between epithelial and mesenchymal cells. Our findings suggest
that MSX2 is able to interfere with the ability of the mesenchyme to induce
the formation of hair placodes. While MSX2 has previously been reported to be
necessary for the outgrowth of the mammary bud in mice, in our hands
MSX2-/- mice are able to form normal mammary ducts
(Satokata et al., 2000).
Furthermore, the expression of several markers of mammary mesenchyme
differentiation was also normal in MSX2-/- mammary buds (J.R.H. and
J.W., unpublished). Thus, MSX2 appears to be relatively specific for mediating
the hair-suppressing effects of PTHrP.
In closing, the experiments detailed in this report demonstrate an important interaction between PTHrP and BMP4 during the development of the embryonic mammary bud. As illustrated in Fig. 8, PTHrP is secreted by the mammary epithelial cells in the bud and interacts with its receptor on surrounding mesenchymal cells. In response, these cells upregulate BMPR1A expression and become able to respond in an autocrine and/or paracrine fashion to mesenchymal BMP4 found within the ventral epidermis. As a result of this cooperation between PTHrP and BMP signaling, the mammary-specific mesenchyme forms and exerts its actions on promoting outgrowth of the primary mammary ducts and instructing nipple sheath development. The suppression of hair follicle formation in the epidermis immediately surrounding the nipple is mediated by the induction of MSX2 expression in mesenchymal cells. It is likely that other growth factors and/or transcription factors will also be regulated by these pathways in the mammary mesenchyme, and it will be particularly interesting to define which factor(s) allows the mesenchyme to initiate outgrowth of the epithelial bud.
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ACKNOWLEDGMENTS |
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REFERENCES |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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C. J. Watson and W. T. Khaled Mammary development in the embryo and adult: a journey of morphogenesis and commitment Development, March 15, 2008; 135(6): 995 - 1003. [Abstract] [Full Text] [PDF]
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