Scribble Modulates the MAPK/Fra1 Pathway to Disrupt Luminal and Ductal Integrity and Suppress Tumour Formation in the Mammary Gland
Polarity allows the specialization of cell function and is required to coordinate cell movements, differentiation, proliferation and apoptosis to build and maintain complex tissues such as the mammary gland. Disruption of polarity is a diagnostic criterion of cancer, but exactly how deregulation of core polarity genes contribute to cancer and at which stage polarity loss promotes breast cancer development in vivo is still poorly understood. To address this directly, we deleted the core polarity gene Scrib specifically in the mouse mammary gland. Scrib loss resulted in loss of tissue architecture and duct hyperplasia in mature but not pubescent mice. Onset of hyperplasia was associated with defective spindle orientations, a failure to apoptose and was sustained by high cell turnover and Ras/Erk/Fra1 MAPK pathway activation. Scrib deficiency activated progenitors and resulted in the excess growth of atypical luminal cells and the development of ductal and alveolar hyperplasia. Overall these mice exhibited an increased incidence, onset and grade of mammary tumours. These studies provide a definitive demonstration of the critical role played by core polarity genes in maintaining mammary epithelial integrity in vivo. This mouse model is a valuable tool for understanding the role of polarity in mammary development and the most initial stages of breast cancer.
Published in the journal:
. PLoS Genet 10(5): e32767. doi:10.1371/journal.pgen.1004323
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1004323
Summary
Polarity allows the specialization of cell function and is required to coordinate cell movements, differentiation, proliferation and apoptosis to build and maintain complex tissues such as the mammary gland. Disruption of polarity is a diagnostic criterion of cancer, but exactly how deregulation of core polarity genes contribute to cancer and at which stage polarity loss promotes breast cancer development in vivo is still poorly understood. To address this directly, we deleted the core polarity gene Scrib specifically in the mouse mammary gland. Scrib loss resulted in loss of tissue architecture and duct hyperplasia in mature but not pubescent mice. Onset of hyperplasia was associated with defective spindle orientations, a failure to apoptose and was sustained by high cell turnover and Ras/Erk/Fra1 MAPK pathway activation. Scrib deficiency activated progenitors and resulted in the excess growth of atypical luminal cells and the development of ductal and alveolar hyperplasia. Overall these mice exhibited an increased incidence, onset and grade of mammary tumours. These studies provide a definitive demonstration of the critical role played by core polarity genes in maintaining mammary epithelial integrity in vivo. This mouse model is a valuable tool for understanding the role of polarity in mammary development and the most initial stages of breast cancer.
Introduction
The polarization of cells into distinct asymmetries is a central aspect of developmental cell biology. Through dictating the functional organization of cells within a tissue, polarity coordinates the movement, proliferation, differentiation and death of cells during tissue morphogenesis and homeostasis [1]–[3]. Polarity control is orchestrated by an intimate network of three mutually dependent complexes, the apically defined Par and Crumbs complexes and the basolateral Scribble complex [2]. In mammals, the Scribble complex consists of Discs large 1 through 4 (Dlg1-4), Lethal giant larvae 1 and 2 (Lgl1/2) and a single homologue of Scribble (Scrib) [4]. Scrib is a large (220-kDa) multidomain protein consisting of 16 leucine-rich repeat and 4 PDZ domains. As a critical component of the core polarity network, Scrib is required to establish distinct polarity configurations in response to spatiotemporal cues, but precisely how Scrib coordinates different cellular responses during a developmental program is less defined.
Scribble is likely to act as a signalling scaffold, interacting with various junctional/signalling components such as β catenin [5] and ZO-2 [6], the tumour suppressor APC [7], the ERK MAP kinase [8], polarity proteins VANGL2 and Lgl2 [9], and βPIX, a guanine nucleotide exchange factor for Rac [10]. Scrib modulation of cellular pathways during the development and homeostasis of epithelial organs is not well characterized and models to study how such core polarity genes coordinate key biological activities within a program of mammalian organ morphogenesis in vivo are required.
Postnatal development of the mouse mammary gland offers a unique system in which to study the role of polarity in epithelial organ morphogenesis. Mammary gland development and function requires several distinct polarity states [3]. For example, asymmetric cell divisions are required for stem/progenitor cells within the mammary epithelium to regulate cell diversification and to build balanced hierarchies of cells [3], [11]. Polarity control is also critical during duct morphogenesis where ductal elongation during puberty is driven by collective cell movements characterized by a transient depolarization of epithelial cells coupled to increased proliferation [12], [13]. The establishment of an apical-basal polarity state is then required for epithelial maturation and barrier function. Finally, migratory (front-rear) polarization occurs during wound healing and is also appropriated by breast cancer cells to allow invasion [3]. Despite being implicated in these various aspects of tissue development, our understanding of the role played by core polarity genes such as Scrib within these polarization processes in vivo remains limited. For example, control of symmetric and asymmetric cell divisions have been well characterized in Drosophila models and in other mammalian tissues [14], [15], however direct experimental evidence for asymmetric divisions and their regulation by core polarity genes during mammary gland development remains to be determined, despite several indirect approaches [16], [17].
Polarity control is also essential to maintain tissue integrity and homeostasis. Indeed, there has long been a strong correlation between loss of epithelial organization and malignant progression [18]. Scribble complex genes were originally identified as neoplastic tumour suppressors in Drosophila genetic screens, and studies using Drosophila genetics and 3D mammalian cell culture models suggest that disruption of core polarity regulators may contribute to tumourigenesis [4], [19]. In humans, deregulated expression and mislocalisation of Scribble complex members are associated with several epithelial cancers [20]–[25], including breast cancer [26]–[29], and human SCRIB is targeted by oncogenic viruses for degradation [30]. To date, our understanding of the role of Scrib in mammary tumourigenesis has been limited to cell culture and transplantation models [29], [31]. Whilst transplantation and in vitro studies have rapidly determined a potential role for Scribble in mammary tumourigenesis, transplantation models fail to mimic pre-malignancy or spontaneous tumour development. Our laboratory has therefore established a unique conditional model for Scribble loss. We have recently used this conditional model to show a requirement for Scrib in the prostate and lung where targeted Scrib-loss in the prostate led to prostate intraepithelial neoplasia and in both lung and prostate setting, cooperated with the K-Ras oncogene in tumour progression [25], [32].
In the present study, we have conditionally depleted Scrib in the mammary gland to demonstrate how Scribble plays a tumour suppressive role during mammary gland development and homeostasis. These studies highlight specific roles for Scrib including regulation of spindle orientation, Ras/MAPK signalling and control of basal to luminal transition and establish polarity suppression of Fra1 as an important barrier to the initiation of premalignant lesions in the breast. This mouse model is a valuable tool for understanding the role of cellular polarity in mammary development and breast cancer progression.
Results
Conditional deletion of Scrib in the mammary gland alters branching morphogenesis and causes duct hyperplasia
To specifically delete Scrib in the mammary gland we bred mice carrying Scribflox/+ conditional and germline Scrib+/− deletion alleles [25] with MMTV-Cre transgenic mice [33]. MMTV-Cre directs efficient excision of floxed genes in both luminal (>80%) and basal/myoepithelial (99%) cell types in the mammary gland from day 6 post-partum [34], [35]. Loss of Scribble protein in the mammary glands of MMTV-Cre;Scribflox/− mice was confirmed by immunoblotting and immunohistochemistry (Figures 1A, 1E (d), (h)). Partial loss was observed in mammary glands of mice with genotypes heterozygous for Scrib (MMTV-Cre;Scribflox/+ and No Cre;Scrib+/−) (Figure 1A). Consistent with previous observations in other epithelial tissues, Scribble basolateral localization was detected by IHC in the mammary epithelium of wildtype and MMTV-Cre control mice (Figures 1E (c), (g)) [25], [31].
To investigate the developmental impact of Scrib loss on branching morphogenesis we examined whole-mount preparations of inguinal mammary glands from pubescent (6 week) and mature (12 week) MMTV-Cre, MMTV-Cre;Scribflox/+ and MMTV-Cre;Scribflox/− virgin mice. During puberty, the rudimentary mammary gland branches and elongates throughout the mammary fat pad via highly proliferative terminal end bud (TEB) structures consisting of mammary progenitor populations. At 6 weeks, ductal trees of MMTV-Cre;Scribflox/− virgin mice showed significantly higher numbers of TEB's (Figure 1B, quantitated in 1C). Following maturation at 12 weeks of age, TEBs were absent and the ductal network had extended throughout the fat pad of all mice examined. Excessive branching however was evident in Scrib-deficient mammary glands (Figure 1D), as indicated by the distances between branch points (excluding small side branches). Whilst histological analysis revealed that loss of Scribble in the developing mammary gland did not immediately impact on duct formation in 6 week virgin mice (Figure 1E (a–d)), gross morphological defects were observed in mammary ducts of MMTV-Cre;Scribflox/− virgin mice by 12 weeks. Scrib-deficient hyperplastic lesions displayed a loss of ductal structure, luminal space and concomitant diffuse intraductal hyperplasia which consisted of disorganized epithelial cell layers of at least 3–4 cells with nuclear and cellular pleomorphism (Figures 1E (e–h)). Multilayering was observed in the majority of mammary duct cross sections of MMTV-Cre;Scribflox/− mice and was significantly increased compared to MMTV-Cre control mice (Figure 1E and quantitated in 1F). We did not detect any phenotypes associated with Scrib loss in other tissues and ductal multilayering was not observed in MMTV-Cre;Scribflox/+ or MMTV-Cre;Scrib+/− heterozygous mice (Figure 1F, Figure S1A). Taken together, our data demonstrate that Scrib is essential for late stage ductal morphogenesis, maturation and homeostasis.
Scribble deficient lesions display loss of polarity and expansion of atypical intraluminal mammary epithelial cells
To identify the key cellular functions mediated by Scribble that are required for proper mammary duct formation, we conducted an extensive analysis of the differentiation, organization, survival and proliferation of developing Scrib-deficient mammary glands.
Fully differentiated luminal epithelial cells that line mammary ducts exhibit apical-basal polarization, and are cuboidal with centralized nuclei, minimal cytoplasm and lateral boundaries in full contact with neighbouring cells [36]. Cells accumulating within the ducts of MMTV-Cre;Scribflox/− mutant mice lacked many of these aspects of epithelial differentiation: cells were poorly differentiated, with a prevalence of loosely packed rounded cells with larger atypical nuclei and increased cytoplasm (Figure 2A). To examine the cell composition of Scrib-deficient mammary ducts, we immunostained for the luminal lineage markers Cytokeratin 8 and 18 (CK8, green; CK18 IHC) and basal/myoepithelial marker Cytokeratin 5 (CK5, red) (Figure 2B). In contrast to the usual bilayered ductal epithelium composed of a luminal cell layer surrounded by a basal myoepithelial layer (MMTV-Cre control mice, Figure 2B), we observed a dramatic expansion of CK8/18 positive luminal cells in Scrib-deficient mammary ducts (Figure 2B). This abnormal increase in CK8/18 positive cells accounts for the bulk of the poorly differentiated intraluminal cells in Scrib-deficient mammary ducts. Similar results were obtained by CK8/CK14 dual staining (Figure S1B).
Mammary epithelial differentiation is characterized by the establishment of apical basal polarity, the formation of mature tight junctions (TJs) and adherens junctions (AJs), and the specification of distinct apical and basolateral membrane identities [3]. Scrib has been implicated in TJ formation [6], [37], [38]. Furthermore, Scribble is known to interact with or regulate the function of key junctional complex components such as E-cadherin and β-catenin [5], [6], [39]. Therefore we determined the impact of Scrib loss on the junctional integrity of mammary epithelial cells and found the apical membrane and junctional localization of ZO-1 was maintained in the absence of Scrib (Figure S1C). Ultrastructural analysis of cell-cell junctions on mammary ducts of Scrib mutant mice confirmed that TJs and desmosomes are still able to form. However a marked decrease in the electron density of TJs and desmosomes in ducts of MMTV-Cre;Scribflox/− mice was observed suggesting minor defects in junction formation (Figure S1D & Procedures S1). Whilst Scrib-deficient mammary epithelial cells were multilayered and varied in cell shape similar to mammary epithelial cells undergoing morphogenesis, electron microscopy did not reveal interdigitating membrane extensions that are characteristic of normal multilayered morphologically active epithelial cells of the terminal end bud [13]. When adherens junctions were examined, in contrast to the lateral enrichment of junctional proteins observed in control mice (Figures 2C (a), (c)). white arrow), hyperplastic ducts of MMTV-Cre;Scribflox/− mutant glands revealed a random distribution of E-cadherin and β-catenin across the membranes of epithelial cells with irregular enrichment at regions of cell-cell contact (Figures 2C (b), (d) white arrowhead). We did not observe increased nuclear β-catenin staining, suggesting that the Wnt pathway is not activated in Scrib-deficient tissue. Consistent with previous RNAi studies of Scribble in cell lines [39], [40], western blot analysis determined that Scrib loss did not significantly impact on the protein levels of E-cadherin or β-catenin (Figure S1E). To further examine apical basal polarity, we evaluated the separation of distinct membrane identities in Scrib-deficient epithelial cells by dual immunofluorescence for E-cadherin and for the apical membrane domain marker p-ezrin(Thr567)/p-radixin(Thr564)/p-moesin(Thr558) (pERM) in ducts of 12 week virgin mice. All Scrib-deficient ducts exhibited highly disorganized aggregated pools of membrane domains where apical and lateral markers were co-localized, suggesting Scrib-deficient mammary cells are unable to respond appropriately to contextual cues and directional cellular processes to establish apical-basal polarity (Figures 2C (e–h), see Movies S1 and S2). Similar staining was also observed using the apical membrane marker and proto-oncogene MUC-1 (Figure S1F). Together these data indicate that loss of Scribble in the mammary gland leads to severe disruptions in apical-basal polarity associated with altered ductal architecture.
We next evaluated proliferation and apoptosis in the mature ducts of 12 week old MMTV-Cre;Scribflox/− and MMTV-Cre;Scribflox+ mutant mice using BrdU and Cleaved Caspase 3 respectively. We detected higher rates of proliferation in Scrib-deficient ducts compared to ducts from MMTV-Cre control mice (Figure 2D), supporting previous work in Scrib-deficient prostate lesions [25]. The development of ductal hyperplasia was also accompanied by increased apoptosis which occurred entirely within the mislocalised intraluminal cell population (Figure 2E). However, we observed no evidence of increased autophagy as measured by lack of autophagosomes by electron microscopy or increase in LC3-II conversion (Figure S1D; Data not shown). Therefore although Scrib-deficient luminal cells initially survive following delamination from contact with the myoepithelial/basement membrane layer, they are unable to persist in the intraluminal space as would be observed in more advanced premalignant lesions such as ductal carcinoma in situ (DCIS). Scrib-deficiency induced hyperplasia therefore recapitulates the most initial stages of pre-malignancy in the breast.
Scrib coordinates early tissue organization and cell division orientation during duct maturation and homeostasis
To address how Scrib depletion leads to hyperplasia and loss of tissue architecture, we first examined cell polarity in Scrib-deficient mammary ducts prior to the onset of multilayering in 6 week old virgin mice. As expected two distinct lateral (E-cadherin, red) and apical (pERM, green) membrane regions were present in ducts of MMTV-Cre control mice (Figure 3A (a)). However ducts of MMTV-Cre;Scribflox/− mutant mice displayed varying degrees of polarity loss in the absence of multilayering, with some individual cells exhibiting expanded apical membrane domain regions (Figure 3A (b)), and others lacking lateral enrichment of E-cadherin (Figure 3A (c)). In some instances, completely disorganized aggregates of membrane domains randomly distributed across cell surfaces were observed in epithelial cells lining the ducts of 6 week virgin MMTV-Cre;Scribflox/− mutant mice (Figure 3A (d)). Therefore, partial loss of polarity and appropriate membrane contextual partitioning precedes cell multilayering in Scrib-deficient mammary ducts.
Strict developmental control of proliferation and apoptosis is necessary for mammary morphogenesis where high cell turnover rates are observed within TEB structures prior to their remodelling into newly formed ducts [12], [41]–[43]. Recent studies have suggested that loss of Scrib can regulate apoptosis to provide a survival advantage within several experimental settings [29], [44], [45]. We speculated that changes in proliferation or apoptosis at a late stage of ductal morphogenesis were responsible for the delayed onset of ductal hyperplasia. Therefore we quantified immunostaining for BrdU and Cleaved Caspase 3 in TEB structures and newly formed ducts of 6 week virgin mice to understand how Scrib loss impacted on distinct phases of ductal morphogenesis and homeostasis. No changes in proliferation or apoptosis rates were observed in TEBs, however, a significant and gene-dosage dependent decrease in apoptosis was observed in immature ducts of 6 week old mice that carried one or two mutated alleles of Scrib (Figure 3C). Together these data indicate that Scrib-deficient mammary epithelial cells fail to respond to apoptotic cues during mammary duct maturation.
Deregulation of polarity and adhesion proteins can lead to misoriented cell divisions. Accordingly, we reasoned that abnormal oriented cell division might contribute to Scrib-deficient multilayering. Scribble has been implicated in the control of spindle orientation in Drosophila [46], and recent experiments have characterized a role for regulators of polarity, including E-cadherin, Cdc42 and Scribble, in controlling spindle orientation during mammalian symmetric divisions and directed migration [2], [47]–[51]. Because these data indicate a role for Scribble in the control of spindle orientation, we assessed the regulation of planar divisions within the luminal epithelial plane of mammary ducts in wildtype and Scrib-deficient mammary glands (6 week virgin mice). This was achieved through immunofluorescence and confocal measurement of spindle geometries prior to the onset of multilayering. Although more divisions are found in peripubertal ducts compared to mature 12 week ducts, the cell divisions within these ducts remain relatively rare in comparison to that commonly observed in TEB structures. Therefore Phospho-Histone H3 (pH 3) was used to locate luminal cells undergoing mitosis whilst pericentrin labelled centrosomes and CK5 labelled the underlying myoepithelial layer to provide a reference for calculation of spindle alignment (Figure 3D (a)). Three-dimensional reconstructions of each division were generated from 18–22 z-sections spaced at 0.5 µm intervals (Figure 3D (b)). Divisions that did not contain two centrosomes or those not aligned within the ductal cross section were omitted.
Here we demonstrate that two coordinated cell divisions occur within the luminal layer of the peripubescent mammary duct, those aligned parallel (38% 00–200) to the epithelial sheet and those aligned perpendicular (29% 700–900). Parallel divisions are symmetric and are considered to maintain luminal cell expansion within the epithelial plane, whereas perpendicular divisions represent an as yet uncharacterized division, likely to be asymmetric. Importantly, in the context of Scrib-depletion, luminal cell division becomes erratic with almost two-fold less divisions occurring within the epithelial plane (20% 00–200) compared to control mice, associated with a distinct increase in angular cell divisions (Figure 3D (c)). This suggests that Scribble is required to regulate spindle orientations within the mammary ductal epithelium, and that deregulation of division axis may be a contributing factor to the Scrib-deficient multi-layering phenotype.
Scrib loss perturbs murine luminal differentiation but not mammary stem cell turnover in vivo
Given the potential role for Scrib in asymmetric cell division and spindle orientation, we next examined the mammary gland epithelial cell hierarchy to delineate which epithelial subpopulations were affected by Scrib loss and could potentiate the clonal expansion of luminal cells. The basal (CD24+CD29hi) population is enriched for mammary stem cells (MaSCs), basal progenitors and differentiated myoepithelial cells while the luminal (CD24+CD29lo) population consists of luminal progenitors and differentiated ductal cells [11], [52]. To further examine the properties of the different epithelial populations we performed fluorescence-activated cell sorting using freshly dissociated mammary tissue isolated from 10 week old virgin mice and conducted a series of specific functional assays. First, to assess the impact of Scrib loss on MaSC function, we transplanted limiting numbers of cells from the MaSC-enriched population (CD24+CD29hi) isolated from three genetic groups which included MMTV-Cre;Scrib+/+ and Scribflox/+ control mice, MMTV-Cre;Scribflox/+ and MMTV-Cre;Scrib+/− heterozygous mice and MMTV-Cre;Scribflox/− mutant mice into the cleared mammary fat pads of isogenic recipient mice (Figure 4A). No difference in repopulating efficiency was observed between the genetic groups, indicating that Scrib loss does not impact on MaSC function or number. We next evaluated whether targeted deletion of Scrib impacted on progenitor cells by performing colony assays with basal (CD24+CD29hi) and luminal progenitor (CD24+CD29l°CD61+) cell populations. A dramatic increase in the clonogenic potential of Scrib-deficient CD24+CD29hi basal cells was observed on irradiated 3T3 feeder cells (Figure 4B), suggesting an increase in the absolute number of progenitor cell types in this subset. No significant change in the colony forming capacity of Scrib-deficient luminal progenitor subset was observed (data not shown). In addition, Scrib deficient basal (CD24+CD29hi) cell populations embedded in Matrigel yielded higher numbers of organoids (Figure S2B & C). The number of basal and surprisingly luminal populations did not significantly vary in Scrib-deficient mammary glands compared with controls by flow cytometry analysis. Our observation that intraluminal Scrib-deficient cells show increased apoptosis in vivo as measured by Cleaved Caspase-3 (Figure 2E), suggests that these cells are primed for cell death and that the intraluminal proportion on Scrib-deficient cells are likely lost early in the dissociation procedure. Altogether, these findings indicate that Scrib loss alters the clonogenic potential of a distinct mammary progenitor cell population prior to luminal lineage expansion within the epithelial hierarchy suggesting that Scrib is required for the regulation of basal to luminal lineage transition and that the ectopic outgrowth of aberrant luminal cells is initiated within the MaSC/basal compartment.
Scrib loss alters the Notch differentiation pathway and drives MAPK hyperactivation to allow inappropriate luminal filling
To determine the molecular pathways by which Scribble may be regulating basal to luminal transition, we examined the impact of Scrib deficiency on the gene expression signatures of critical growth and differentiation pathways known to regulate cell fate in the mammary gland including Notch and MAPK. Gene expression analysis was performed on 8 week old MMTV-Cre;Scrib+/+ and MMTV-Cre;Scribflox/− mutant mice using unpooled cDNA from freshly sorted basal and luminal mammary epithelial populations (Figure 5A & Procedures S1). The purity of luminal (CD24+CD29lo) and basal (CD24+CD29hi) cell populations was confirmed by determining the expression of CK8 and α-smooth muscle actin (α-SMA) by q-RT-PCR analysis (Figure 5B).
The Notch pathway has been shown to be a critical driver of luminal cell fate specification in mammary development with increased gene expression of Notch targets Hey1 and Hey2, but not Hes6, in luminal progenitors compared to mature luminal ductal cells [53]. We observed a significant and dose dependent reduction in Hey1 and Hey2 (but not Hes6) in Scrib-deficient luminal cells (Figure 5B and Figure S2D), and an increase in GATA3, a master regulator of luminal lineage differentiation which is highly expressed in mature luminal cells [54] (Figure 5B). Given that duct hyperplasia only occurs in mammary ducts homozygous for Scrib-loss and not heterozygous tissue, the gene-dose dependent changes in gene expression in heterozygote tissue indicate they are cell autonomous and do not simply reflect shifts in cell populations. These expression changes were also specific for the luminal compartment as they were not observed within the basal compartment (Figure 5B). We used immunohistochemistry to confirm the suppression of Hey1 and elevation of GATA3 protein levels in Scrib-deficient luminal cells in the mammary glands of 12 week old mice (Figure 5B (a–d)). This is consistent with the notion that Scrib-deficiency drives the formation of more mature luminal cells rather than progenitor cell types. To assess how Scrib-deficiency impacts on the luminal cell program in the mammary epithelium of MMTV-Cre;Scribflox/− virgin mice, we next analyzed the mRNA expression of the ductal and alveolar luminal progenitor markers Kit and Elf5 [55], [56]. Similar to the decrease in CD61+ cells within the luminal population, Kit and Elf5 expression was moderately decreased in Scrib-deficient luminal cells (Figure S2D). To evaluate any impact Scrib loss may have during alveolar development, we performed immuno-histological analysis on cohorts of mice during pregnancy (14.5 days post coital & 16.5 days post coital), lactation (4 days post-partum), Involution (day 4 post weaning), and 12 weeks post-pregnancy (Figure S3 & Procedures S1). No histological changes in the ducts and alveoli were apparent, regardless of Scrib deficiency. Surprisingly, pregnancy led to rescue of the cell polarity and ductal defects observed in MMTV-Cre;Scribflox/− mammary glands in the pre-pregnant state (Figure S3B).
Together these data suggest that Scrib-loss does not impact on alveolar differentiation, but drives the outgrowth of a more mature but atypical ductal cell type via the well documented Notch differentiation pathway [53].
MAPK plays key roles in different aspects of mammary development and Scrib has been characterized as a modulator of the Ras/MAPK pathway previously [25], [31], [37], [57]–[59]. Importantly, expression analysis revealed dose-dependent increases of the MAPK/ERK and MAPK/JNK pathway effector Fra1 but not the MAPK/JNK effector c-Jun in response to Scrib loss in both the basal and luminal cell populations (Figure 5Ca and Figure S2D). Fra1 is therefore hyperactivated via the MAPK/ERK pathway in both basal and luminal compartments of Scrib-deficient mammary epithelium. This is consistent with Scrib-loss modifying basal progenitor function prior to the expansion of aberrant luminal cells. The increased expression of Fra-1, a specific effector of sustained Ras-MAPK signalling [60], [61] in Scrib-deficient cells suggests that ectopic activation of Ras/MAPK in this tissue could be contributing to the multilayering phenotype in mammary ducts. To address this, we examined Ras/MAPK signalling in Scrib-deficient mammary epithelium. We detected a significant increase in nuclear pERK expression (over two fold increase), in the Scrib-deficient ducts of 12 week virgin mice indicating Scrib loss results in activation of MAPK in mature mammary ducts in vivo (Figure 5C b–d). Although the Akt pathway was recently shown to be enhanced in cell lines following Scrib knockdown [62], we could not detect Akt pathway activation in the mouse mammary epithelium in vivo (Figure S4).
To ascertain the relative contribution of elevated Ras/MAPK levels to ductal hyperplasia in Scrib-deficient ducts, we treated 6 week old mice (prior to the development of hyperplasia) with the MEK inhibitor PD0325901 for two weeks (n = 7–9). Multilayering of mammary ducts in vehicle-treated MMTV-Cre;Scribflox/− mice was readily detectable at 8 weeks, although less severe than that in 12 week-old mice (Compare Figure 1E (f) to Figure 5D (c)). Importantly, histological analysis revealed PD0325901 treatment blocked the early onset of multilayering in Scrib-deficient mammary ducts compared with vehicle (Figure 5E)(P = 0.0002). Treatment with PD0325901 also suppressed the hyperproliferation associated with Scrib-loss in the mature duct epithelium (Figure S5A). Effective MEK inhibition by PD0325901 was confirmed by immunostaining for pERK (Figure 5F (a–d)). Strikingly, we also observed a more organized and tightly packed mammary epithelium with restoration of laterally enriched E-cadherin and a clearly defined pERM positive apical membrane region in ducts of PD0325901 treated MMTV-Cre;Scribflox/− mice compared to ducts from vehicle treated mice (Figure 5G (a–d)). Thus, hyperactivation of MAPK as a consequence of Scribble loss of function is largely responsible for the loss of cell polarity and tissue organization observed in Scrib deficient mammary tissue.
Our findings show that hyperactivation of the Ras/MAPK pathway induced by Scrib-loss is necessary to allow the accumulation of intraluminal mammary epithelial cells. Altogether we show that Scrib-deficiency and Ras/MAPK pathway activation results in the over growth of unpolarised but mature ductal luminal cells with elevated Fra1 expression.
Scrib loss enhances mammary tumour progression
Deletion of Scrib in the mammary epithelium is characterized by differentiation defects, persistent Ras/MAPK hyperactivation, increased cell turnover, altered directional divisions and compromised tissue integrity. We predicted that these defects coupled with disruption to normal cell polarity signalling would act in concert to promote several aspects of mammary tumourigenesis. We therefore aged cohorts of virgin wildtype, Scrib+/−, MMTV-Cre;Scrib+/+, MMTV-Cre;Scribflox/+ and MMTV-Cre;Scribflox/− mice up to 75 weeks. Upon histological examination, we discovered widespread patterns of hyperplastic alveolar nodules (HAN) in the mammary glands of MMTV-Cre;Scribflox/− virgin mice (Figure 6A (c–d)). These preneoplastic lesions show increased tumourigenic potential compared to ductal hyperplastic lesions when assayed by transplantation [63]. HAN can be characterized by focal disorganized alveolar ringlets with lipid droplets, increased proliferation and STAT5 hyperphosphorylation [63], [64]. We observed significantly increased regions of HAN and lipid droplets in mammary glands of MMTV-Cre;Scribflox/− mutant mice compared to control mammary glands (Figure 6B). These HAN lacked Scrib expression and in comparison to adjacent ducts exhibited a dramatic increase in proliferation and hyperactivation of STAT5 as expected (Figure 6C (a–f)).
To determine whether the HAN lesions indicated a greater sensitivity to tumour progression in Scrib-deficient mammary tissue, we monitored aged cohorts for tumour occurrence and survival. Although MMTV-Cre;Scribflox/− mice showed reduction in survival (475 days) compared to 525 days in MMTV-Cre control mice this was not statistically significant (Figure S6A). Many mice exhibited mammary tumours and to a lesser extent ovarian and lung tumours at endpoint. Spontaneous mammary tumours are a common event in FVB/n mice and exhibit a broad spectrum of lesions that encompasses the natural history of mammary tumour progression [65]. We therefore also monitored MMTV-Cre;Scrib+/+, MMTV-Cre;Scribflox/+ and MMTV-Cre;Scribflox/− mice for mammary tumour onset. Both MMTV-Cre;Scribflox/− and MMTV-Cre;Scribflox/+ mice developed mammary tumours earlier (median tumour initiation at 449 and 492 days respectively) than MMTV-Cre control mice (586 days) (Figure 6D). All tumours that arose from MMTV-Cre;Scribflox/− mice were shown to have a clear absence of Scrib compared to tumours from MMTV-Cre mice as determined by IHC (Figure 6D). The incidence of stochastic mammary tumours increased significantly in MMTV-Cre;Scribflox/− mice compared to MMTV-Cre control mice (Figure 6E). Similar to our earlier observations within Scrib-deficient hyperplastic mammary ducts we identified a trend for higher cell turnover in conjunction with Scrib loss in mammary lesions (Figure 6F). To understand the impact of Scrib loss on the progression of mammary tumourigenesis, we compared the histopathological grading of tumours from MMTV-Cre;Scrib+/+ and MMTV-Cre;Scribflox/− mice at endpoint (1200 mm3 tumour volume) using a broadly accepted nomenclature and morphologic classification system [66]. Briefly, low grade lesions are characterized by the presence of residual structures such as glandular/acinar patterning, hyperchromatic nuclei and reduced cytoplasm without pleomorphism whereas high grade lesions have less differentiated solid masses of neoplastic cells with nuclear pleomorphism and invasion into adjacent mammary tissue [66]. Tumours from control mice exhibited a similar range of mammary tumour phenotypes to that previously reported, from well-structured adenocarcinomas to solid sheets of carcinoma cells and spindleoid mammary tumours which are reminiscent of an epithelial to mesenchymal transition [65]. We observed an absence of low grade mammary tumours in MMTV-Cre;Scribflox/− animals indicating that Scrib loss further promotes loss of architecture and differentiation in the context of a tumour (Figure 6G). In addition, we immunostained a subset of these tumours using the basal-like tumour marker CK14 and found more tumours from MMTV-Cre;Scribflox/− mice stained positive for CK14 expression (4/5), compared to those from control mice (0/5)(Figure S6B). Overall, tumours from MMTV-Cre;Scribflox/− mice size and age matched to low grade control tumours were either spindleoid EMT type or solid carcinomas. Therefore loss of Scribble function not only replicates the most initial phase of pre-malignancy in the breast but can accelerate tumour progression and promote the development of basal-like less differentiated tumours.
Taken together these data have not only defined a distinct role for Scrib in mammary duct morphogenesis, luminal differentiation and tissue homeostasis in vivo, but also demonstrates that Scrib tumour suppressor function is a critical modulator of multiple steps in mammary tumourigenesis from premalignancy to the evolution and progression of sporadic mammary tumours.
Discussion
Role of cell polarity in breast development
We have demonstrated a requirement for Scrib in the homeostasis of the mammary ductal luminal epithelium. In particular, we show that Scrib plays an essential role mediating the correct modelling of newly formed mammary ducts during the final phase of duct morphogenesis, a process that involves the clearance of apoptotic cells and the maintenance of multiple aspects of cell polarity, including the resolution of apical and basolateral identity and correct spindle positioning. Whilst the initial stages of mammary duct formation are well characterized and are known to involve high proliferation and collective movements of depolarized cells within the TEB followed by apoptosis [12], [41], much less is known of any late stage or redundant mechanisms regulating mammary lumen formation and maintenance. One example of this involves the pro-apoptotic protein BIM, a key driver of apoptosis during lumen formation in vitro and in vivo [67], [68]. BIM loss in the mouse mammary gland results in defects in apoptosis and lumen clearing resulting in multilayered ducts during puberty. These ducts bear remarkable morphological similarity to Scrib-deficient ducts however the multilayering arises directly from the TEB and is rescued by unknown late stage mechanisms after 5 weeks of age [67]. WAP-Bcl-2 transgenic mice exhibit a similar delay in lumen formation [41]. These findings suggest a late-phase of duct maturation occurs which utilizes additional mechanisms of tubulogenesis. A role for lumen formation via remodelling has been demonstrated in Matrigel cultures of primary mammary epithelial cells [69] and has been proposed previously [3], [42], [43]. Such a phase of duct maturation likely involves residual apoptosis, proliferation, cell movements and the reinforcement of apical-basal polarization in newly formed mammary ducts prior to a more quiescent stage at maturity. Our findings support this model and implicate cell polarity control as an essential driver of mammary duct maturation in vivo. We show loss of polarity control does not impair lumen formation at the TEB, but results in insufficient apical-basal polarization, aberrantly orientated cell divisions, sustained activation of the MAPK pathway and the evasion of a late phase of apoptosis associated with duct maturation. These findings confirm and extend the observations by Mailleux, et. al. (2007) and Humphreys, et. al. (1996), that in addition to apoptosis, control of cell polarity is one of the key mechanisms required for duct formation.
Interestingly, Scrib loss results in several morphological defects in the mouse mammary epithelium which cannot be recapitulated by growing the same Scrib deficient mammary epithelial cells in Matrigel cultures (Figure S2). Luminal-myoepithelial cell and epithelial-stromal interactions are often absent in 3D cultures and epithelial cells are instead saturated by growth factor signals and basement membrane contextual cues which we suggest override polarity defects. These findings highlight the need to use appropriate mouse models to definitively describe the role of polarity genes in mammary morphogenesis.
In addition to the influence of the ECM on cell polarity defects, we found Scrib modulation of the Ras/MAPK pathway to be critical in maintaining epithelial tissue polarity, as inhibition of the Ras/MAPK was able to prevent the onset of duct hyperplasia and restore apical-basal polarity. Altogether these observations suggest that intact tissue polarity cues can correct defects in core cell polarity signalling in some contexts.
Previously Scrib has been implicated in the control of mitotic spindle asymmetry during Drosophila neuroblast divisions [46]. We show for the first time that Scrib coordinates spindle orientation in a mammalian developmental context in vivo. We have characterized the distribution of mitotic spindle angles in the luminal layer of the mammary duct in vivo and demonstrate a requirement for Scrib in the regulation of distinct parallel and perpendicular divisions of luminal epithelial cells. Loss of Scrib leads to deregulation of spindle positioning during planar divisions which can give rise to a multilayered epithelium. Indeed mitotic spindle misorientation has been proposed to contribute to several aspects of cancer progression [70]. Supporting our studies of spindle orientations in the luminal layer of Scrib-deficient ducts and the mammary duct branching defects observed in these mice, mice lacking β1 integrin in basal cells exhibit similar spindle orientation defects coupled with an abnormal ductal branching pattern [71]. This suggests spindle orientation defects may also impact on branching morphogenesis and that in addition to polarity mechanisms, cell-ECM interactions also play an important role in directing spindle orientations in mammary ducts. Interestingly, modulation of the Ras/MAPK pathway itself can control spindle orientation during lung branching morphogenesis to drive epithelial tube morphogenesis [72]. It is therefore likely a similar process exists in the developing mammary gland. Indeed Scrib loss results in Ras/MAPK signalling, spindle orientation and branching morphogenesis defects. Further studies will be required to elucidate the relationship between Rash/MAPK pathway and spindle orientation and branching in the mammary gland.
Scribble is a critical modulator of MAPK activity during breast development and homeostasis
The Ras/MAPK pathway is strongly implicated in morphogenesis of branched epithelial tissues such as salivary gland [73], kidney [74], and lung [72], but less is known about the role of Ras/MAPK flux in mammary morphogenesis. We now reveal that modulation of MAPK by cell polarity mechanisms is required during mammary development, specifically to limit the activity of basal progenitors and to allow the terminal differentiation and homeostasis of the ductal luminal epithelium (Figure 7).
We observed dose-dependent increases in Fra1 expression associated with Scrib loss in both basal and luminal mammary epithelial cell populations. This suggests a critical role for Scrib suppression of Ras/MAPK within the mammary cell hierarchy and is consistent with our findings in vitro where Scribble knock down elicits a heightened and sustained MAPK response concomitant with elevated Fra1 [37]. Fra1 levels are strongly associated with sustained Erk1/2 signalling kinetics [75], [76], and sustained compared to transient MAPK/ERK responses drive different morphological responses in mammary epithelial cells. In cultures of primary mouse mammary organoids, sustained MAPK/ERK activation elicits branching morphogenesis and an expansion of cells positive for K6, a marker of hyperproliferative progenitor cells, whereas transient MAPK/ERK activation elicits growth without branching [77]. More recently, human organoids in culture were treated with EGFR ligands AREG or EGF. Both ligands induced ductal outgrowth however EGF, which results in a more sustained MAPK/ERK activation [78], resulted in the initial expansion of dual-positive K8+/K14+ progenitor cells followed by ectopic expansion of myoepithelial cells [79]. These findings suggest differences in MAPK/ERK signalling kinetics impact on duct morphogenesis and lineage specification. Previous studies investigating the distinct roles of growth factors and ErbB receptors during mammary development also support the notion that different MAPK kinetics result in alternate differentiation outcomes [58], [80].
We have demonstrated that polarity control is a key modulator of MAPK flux during mammary duct morphogenesis as Scrib-deficient mature mammary ducts exhibit ectopic hyperactivation of the Ras/MAPK/Fra1 pathway. A number of studies have shown persistent Ras/MAPK pathway activation undermines mammary epithelial organization. Transformed mammary epithelial cells fail to form lumens in Matrigel cultures [81]. Such breast cancer cell lines exhibit persistent Ras/MAPK activation and suppression of the Ras/MAPK pathway and β1 integrin inhibition induces phenotypic reversion [82]. Furthermore, oncogenes that act on the Ras/MAPK pathway disrupt apical-basal polarity in epithelial organoids [83]–[85]. Activation of ErbB2 in mice can result in HAN similar to those that develop in MMTV-Cre;Scribflox/− mice and conversely the specific deletion of ErbB2 impairs duct elongation and branching morphogenesis [86], [87]. Altogether these findings suggest that deregulation of normal MAPK and cell polarity signalling are concomitant processes in mammary tumourgenesis.
We have now characterized Scribble as a modifier of MAPK/ERK signalling kinetics in mammary cell line models [31], [37] and in multiple tissues in vivo [25], [57]. Our mouse model of Scrib loss will therefore be an important tool to understand the impact of sustained Ras/MAPK activation in mammary ducts in vivo.
Disruption of cell polarity can contribute to the initiation and progression of breast cancer
Multilayering, loss of polarity and luminal filling can define premalignant breast lesions such as breast ductal hyperplasia and DCIS. However the molecular mechanisms that initiate these events are unknown. In addition to polarity loss, oncogenes that drive proliferation and survival such as HER-2, Cyclin D1 and C-MYC are frequently activated in pre-invasive breast lesions of high malignant potential such as DCIS and allow survival in the luminal space [88], [89]. We have found that disruption to the core polarity network and activation of MAPK may participate together in early events prior to DCIS and breast cancer development. We have recently found that many polarity genes suppress sustained activation of MAPK (Smith et al, manuscript in preparation), and deregulation of Scrib in human breast cancer has been reported previously [27]–[29]. Furthermore, several common molecular lesions in DCIS promote Ras/MAPK signalling [90]–[93]. In particular, Fra1 is highly expressed in breast ductal hyperplasia and DCIS and is therefore associated with early events in breast carcinogenesis [94]–[97]. Therefore, disruption of tissue polarity, high cell turnover and hyperactivation of a MAPK/Fra1 oncogenic pathway is likely to lead to a more rapid accumulation of genetic abnormalities and escalate mammary tumour progression. Accordingly, Scrib loss leads to the increased incidence of mammary tumours which are less histologically differentiated. Poorly differentiated human breast tumours are characterized by a loss of polarity, elevated Fra1 levels and worse outcomes [96], [98], [99].
We have also observed that pregnancy can rescue the Scrib-hyperplastic phenotype and associated polarity defects. In humans, cancer risk is dramatically decreased with early pregnancy [100]. Our observations support the notion that pregnancy is likely to drive the alveolar differentiation of uncommitted luminal epithelial cells which may be more prone to tumourigenesis [101].
We have used a definitive conditional mouse model of Scrib-loss in the mammary gland to show a requirement for Scrib in the control of basal progenitor function and luminal cell maturation during mammary duct morphogenesis. Our findings provide new insights into how loss of polarity impacts on tissue homeostasis and can contribute to the etiology and pathogenesis of breast cancer.
Materials and Methods
Experimental animals
Both null and conditional floxed mutant alleles of Scrib were generated in mice as described previously [25].The Scrib null allele was produced by crossing Scribflox/+ mice to a germline Cre-deleter mouse. To generate MMTV_Cre;Scribflox/− mice, we crossed female heterozygous Scrib null mice to male.
Tg(MMTV-cre)1Mam (line A) mice were a kind gift from K Wagner [33]. Male MMTV_Cre;Scrib+/− mice were then finally crossed to female Scribflox/+ mice to produce experimental cohorts. Mice were genotyped from genomic DNA derived from toe biopsies using primers for Scrib alleles and conditions as described previously [25].
Ethics statement
All mice were maintained on a pure FVB/n background (Backcrosses onto pure FVB/n, N>10). All animal use was approved by the Peter MacCallum Cancer Centre Animal Experimental Ethics Committee Ethics Committee and in compliance with National Health and Medical Research Council (Australia) guidelines.
PD0325901 administration
The treatment regime was similar to that previously reported [25] where MEK inhibitor PD0325901 (JS Research Chemicals Trading) was dissolved in 0.5% hydroxypropyl-methylcellulose; 0.2% Tween 80 at 8 mg/ml and delivered by oral gavage at 20 mg/kg 5 days on and 2 days off from 6 to 8 weeks of age. Mice were weighed daily to monitor drug tolerance and showed no significant reduction in weight (>10% loss).
Whole mount, immunohistochemistry and immunoblotting analysis
Inguinal mammary fat pads were fixed overnight in Carnoy's fixative solution and immersed in Acetone for at least 3×2 hr before hydration from 70% ethanol. Whole mounts were then stained in carmine alumn overnight, dehydrated through series of ethanol solutions and cleared in Xylene followed by Methyl Salicylate. Analysis of ductal trees was performed by scanning entire slides using an Olympus IX81 microscope and counting distal TEBs or measuring the distance between branch points (>50 measurements/mouse whole mount, 3–6 mice/experimental group). For Histology, formalin-fixed paraffin-embedded (FFPE) sections were stained with H&E and assessed by a trained pathologist. For IF or IHC staining, antigen retrieval was performed on frozen or FFPE sections of inguinal mammary fat pads (>3 mice/experimental group) in 1× citrate buffer (Thermo Scientific) or Tris-EDTA pH 9 (DAKO) in a pressure cooker (125°C 15 psi). IHC samples were blocked in 2% BSA in TBST solution and endogenous peroxidise activity was inactivated in 1.5% H2O2. Biotinylated species specific secondary antibodies were used at 1∶300 (DAKO) followed by the Avidin Biotin Complex (ABC) Method prior to visualisation with 3,3- Diaminobenzidine chromagen (DAKO). IF samples were blocked in 1X PBS/5% normal donkey serum/0.3% Triton X-100 and Alexa Fluor antibodies (Invitrogen) where used at 1∶300 before mounting in ProLong Gold with DAPI (Invitrogen). Primary antibodies other than those recently reported [25], included Caspase 3 (9661, Cell Signalling Technology), Brdu (347580, BD Biosciences), p-Histone 3 (641001, Biolegend), pericentrin (ab64448, Abcam), Cytokeratin 5 (PRB-160P, covance), Cytokeratin 8 (ab14053, Abcam), β-catenin (610153, BD Biosciences), GATA3 (sc-268 SantaCruz), Hey1 (ab22614, Abcam), p-STAT5 (9331, Cell Signalling Technologies), ZO-1 (clone R40.76, Millipore). Additional antibodies used for Supplemental data see Procedures S1. Wholemount analysis and IHC scoring was carried out using MetaMorph 6.3 software (Molecular Devices). Immunofluorescence and bright field microscopy was performed on an Olympus BX-51 microscope. Immuno blotting was performed on mammary tissue snap frozen in liquid nitrogen as described [54] using anti-Scribble (clone 7C6.D10) [102], α-tubulin (T5168, Sigma).
Confocal microscopy and analysis of spindle orientation in ductal epithelium
Confocal microscopy was performed on a NIKON eclipse 90i C2 confocal microscope. For spindle analysis, dividing cells were identified by pHistone3 immunostaining and 18–22x 0.5 µm z-section stacks where captured with 60× objective at 2.5× zoom. 3D reconstructions were assessed using NIS-Elements software and evaluated as outlined in results section.
Mammary epithelial cell isolation cell sorting and mammary epithelial cell assays
Isolation and cell sorting of primary mammary epithelial cell populations was performed on 8–10 week old mice (n = 6) using fluorescently conjugated antibodies to CD45, TER119, CD31, CD29, CD24, CD61 (BD Biosciences) using a FACS DIVA or FACS Aria [52], [54]. Mammary stem cell limiting dilution reconstitution assays and colony formation assays were also as described [52], [54].
Gene expression analysis
RNA was isolated and reverse transcribed from freshly prepared FACS sorted primary mammary epithelial cell populations using TRizol and superscript III reagents (Invitrogen). cDNA amplification was performed using the stepOnePlus Real-Time PCR system (Applied Biosystems) Samples were normalised to GAPDH and expression levels calculated using the 2−dCt method [103]. Real-time primers listed in Procedures S1.
Supporting Information
Zdroje
1. BryantDM, MostovKE (2008) From cells to organs: building polarized tissue. Nat Rev Mol Cell Biol 9: 887–901.
2. DowLE, HumbertPO (2007) Polarity regulators and the control of epithelial architecture, cell migration, and tumorigenesis. Int Rev Cytol 262: 253–302.
3. GoddeNJ, GaleaRC, ElsumIA, HumbertPO (2010) Cell polarity in motion: redefining mammary tissue organization through EMT and cell polarity transitions. J Mammary Gland Biol Neoplasia 15: 149–168.
4. HumbertPO, GrzeschikNA, BrumbyAM, GaleaR, ElsumI, et al. (2008) Control of tumourigenesis by the Scribble/Dlg/Lgl polarity module. Oncogene 27: 6888–6907.
5. SunY, AigaM, YoshidaE, HumbertPO, BamjiSX (2009) Scribble interacts with beta-catenin to localize synaptic vesicles to synapses. Mol Biol Cell 20: 3390–3400.
6. MetaisJY, NavarroC, SantoniMJ, AudebertS, BorgJP (2005) hScrib interacts with ZO-2 at the cell-cell junctions of epithelial cells. FEBS Lett 579: 3725–3730.
7. TakizawaS, NagasakaK, NakagawaS, YanoT, NakagawaK, et al. (2006) Human scribble, a novel tumor suppressor identified as a target of high-risk HPV E6 for ubiquitin-mediated degradation, interacts with adenomatous polyposis coli. Genes Cells 11: 453–464.
8. NagasakaK, PimD, MassimiP, ThomasM, TomaicV, et al. (2010) The cell polarity regulator hScrib controls ERK activation through a KIM site-dependent interaction. Oncogene 29: 5311–5321.
9. KallayLM, McNickleA, BrennwaldPJ, HubbardAL, BraitermanLT (2006) Scribble associates with two polarity proteins, Lgl2 and Vangl2, via distinct molecular domains. J Cell Biochem 99: 647–664.
10. AudebertS, NavarroC, NourryC, Chasserot-GolazS, LecineP, et al. (2004) Mammalian Scribble forms a tight complex with the betaPIX exchange factor. Curr Biol 14: 987–995.
11. VisvaderJE (2009) Keeping abreast of the mammary epithelial hierarchy and breast tumorigenesis. Genes Dev 23: 2563–2577.
12. EwaldAJ, BrenotA, DuongM, ChanBS, WerbZ (2008) Collective epithelial migration and cell rearrangements drive mammary branching morphogenesis. Dev Cell 14: 570–581.
13. EwaldAJ, HuebnerRJ, PalsdottirH, LeeJK, PerezMJ, et al. (2012) Mammary collective cell migration involves transient loss of epithelial features and individual cell migration within the epithelium. J Cell Sci
14. JanuschkeJ, GonzalezC (2008) Drosophila asymmetric division, polarity and cancer. Oncogene 27: 6994–7002.
15. MorinX, BellaicheY (2011) Mitotic spindle orientation in asymmetric and symmetric cell divisions during animal development. Dev Cell 21: 102–119.
16. CicaleseA, BonizziG, PasiCE, FarettaM, RonzoniS, et al. (2009) The tumor suppressor p53 regulates polarity of self-renewing divisions in mammary stem cells. Cell 138: 1083–1095.
17. McCaffreyLM, MacaraIG (2009) The Par3/aPKC interaction is essential for end bud remodeling and progenitor differentiation during mammary gland morphogenesis. Genes Dev 23: 1450–1460.
18. BissellMJ, RadiskyD (2001) Putting tumours in context. Nat Rev Cancer 1: 46–54.
19. BilderD, LiM, PerrimonN (2000) Cooperative Regulation of Cell Polarity and Growth by Drosophila Tumor Suppressors. Science 289: 113–116.
20. GardiolD, ZacchiA, PetreraF, StantaG, BanksL (2006) Human discs large and scrib are localized at the same regions in colon mucosa and changes in their expression patterns are correlated with loss of tissue architecture during malignant progression. Int J Cancer 119: 1285–1290.
21. KameiY, KitoK, TakeuchiT, ImaiY, MuraseR, et al. (2007) Human scribble accumulates in colorectal neoplasia in association with an altered distribution of beta-catenin. Hum Pathol 38: 1273–1281.
22. LisovskyM, DresserK, BakerS, FisherA, WodaB, et al. (2009) Cell polarity protein Lgl2 is lost or aberrantly localized in gastric dysplasia and adenocarcinoma: an immunohistochemical study. Mod Pathol 22: 977–984.
23. LisovskyM, OgawaF, DresserK, WodaB, LauwersGY (2010) Loss of cell polarity protein Lgl2 in foveolar-type gastric dysplasia: correlation with expression of the apical marker aPKC-zeta. Virchows Arch 457: 635–642.
24. OuyangZ, ZhanW, DanL (2010) hScrib, a human homolog of Drosophila neoplastic tumor suppressor, is involved in the progress of endometrial cancer. Oncol Res 18: 593–599.
25. PearsonHB, Perez-ManceraPA, DowLE, RyanA, TennstedtP, et al. (2011) SCRIB expression is deregulated in human prostate cancer, and its deficiency in mice promotes prostate neoplasia. J Clin Invest 121: 4257–67.
26. FujaTJ, LinF, OsannKE, BryantPJ (2004) Somatic mutations and altered expression of the candidate tumor suppressors CSNK1 epsilon, DLG1, and EDD/hHYD in mammary ductal carcinoma. Cancer Res 64: 942–951.
27. MetodievaG, Nogueira-de-SouzaNC, GreenwoodC, Al-JanabiK, LengL, et al. (2013) CD74-dependent Deregulation of the Tumor Suppressor Scribble in Human Epithelial and Breast Cancer Cells. Neoplasia 15: 660–668.
28. NavarroC, NolaS, AudebertS, SantoniMJ, ArsantoJP, et al. (2005) Junctional recruitment of mammalian Scribble relies on E-cadherin engagement. Oncogene 24: 4330–4339.
29. ZhanL, RosenbergA, BergamiKC, YuM, XuanZ, et al. (2008) Deregulation of scribble promotes mammary tumorigenesis and reveals a role for cell polarity in carcinoma. Cell 135: 865–878.
30. NakagawaS, YanoT, NakagawaK, TakizawaS, SuzukiY, et al. (2004) Analysis of the expression and localisation of a LAP protein, human scribble, in the normal and neoplastic epithelium of uterine cervix. Br J Cancer 90: 194–199.
31. DowLE, ElsumIA, KingCL, KinrossKM, RichardsonHE, et al. (2008) Loss of human Scribble cooperates with H-Ras to promote cell invasion through deregulation of MAPK signalling. Oncogene 27: 5988–6001.
32. YatesLL, SchnatwinkelC, HazelwoodL, ChessumL, PaudyalA, et al. (2013) Scribble is required for normal epithelial cell-cell contacts and lumen morphogenesis in the mammalian lung. Dev Biol 373: 267–280.
33. WagnerKU, WallRJ, St-OngeL, GrussP, Wynshaw-BorisA, et al. (1997) Cre-mediated gene deletion in the mammary gland. Nucleic Acids Res 25: 4323–4330.
34. PalB, BourasT, ShiW, VaillantF, SheridanJM, et al. (2013) Global changes in the mammary epigenome are induced by hormonal cues and coordinated by Ezh2. Cell Rep 3: 411–426.
35. WagnerKU, McAllisterK, WardT, DavisB, WisemanR, et al. (2001) Spatial and temporal expression of the Cre gene under the control of the MMTV-LTR in different lines of transgenic mice. Transgenic Res 10: 545–553.
36. PitelkaDR, HamamotoST, DuafalaJG, NemanicMK (2009) Cell contacts in the mouse mammary gland: i. Normal gland in postnatal development and the secretory cycle. 1973. J Mammary Gland Biol Neoplasia 14: 295–316.
37. ElsumIA, MartinC, HumbertPO (2013) Scribble regulates an EMT-polarity pathway through modulation of MAPK-ERK signaling to mediate junction formation. J Cell Sci 126: 3990–9.
38. IvanovAI, YoungC, Den BesteK, CapaldoCT, HumbertPO, et al. (2010) Tumor suppressor scribble regulates assembly of tight junctions in the intestinal epithelium. Am J Pathol 176: 134–145.
39. QinY, CapaldoC, GumbinerBM, MacaraIG (2005) The mammalian Scribble polarity protein regulates epithelial cell adhesion and migration through E-cadherin. J Cell Biol 171: 1061–1071.
40. DowLE, KauffmanJS, CaddyJ, ZarbalisK, PetersonAS, et al. (2007) The tumour-suppressor Scribble dictates cell polarity during directed epithelial migration: regulation of Rho GTPase recruitment to the leading edge. Oncogene 26: 2272–2282.
41. HumphreysRC, KrajewskaM, KrnacikS, JaegerR, WeiherH, et al. (1996) Apoptosis in the terminal endbud of the murine mammary gland: a mechanism of ductal morphogenesis. Development 122: 4013–4022.
42. MailleuxAA, OverholtzerM, BruggeJS (2008) Lumen formation during mammary epithelial morphogenesis: insights from in vitro and in vivo models. Cell Cycle 7: 57–62.
43. ReginatoMJ, MuthuswamySK (2006) Illuminating the center: mechanisms regulating lumen formation and maintenance in mammary morphogenesis. J Mammary Gland Biol Neoplasia 11: 205–211.
44. FrankSR, BellJH, FrodinM, HansenSH (2012) A betaPIX-PAK2 Complex Confers Protection against Scrib-Dependent and Cadherin-Mediated Apoptosis. Curr Biol 22: 1747–54.
45. LiuH, GolebiewskiL, DowEC, KrugRM, JavierRT, et al. (2010) The ESEV PDZ-binding motif of the avian influenza A virus NS1 protein protects infected cells from apoptosis by directly targeting Scribble. J Virol 84: 11164–11174.
46. AlbertsonR, DoeCQ (2003) Dlg, Scrib and Lgl regulate neuroblast cell size and mitotic spindle asymmetry. Nat Cell Biol 5: 166–170.
47. den ElzenN, ButteryCV, MaddugodaMP, RenG, YapAS (2009) Cadherin adhesion receptors orient the mitotic spindle during symmetric cell division in mammalian epithelia. Mol Biol Cell 20: 3740–3750.
48. DurganJ, KajiN, JinD, HallA (2011) Par6B and atypical PKC (aPKC) regulate mitotic spindle orientation during epithelial morphogenesis. J Biol Chem 286: 12461–74.
49. ToyoshimaF, MatsumuraS, MorimotoH, MitsushimaM, NishidaE (2007) PtdIns(3,4,5)P3 regulates spindle orientation in adherent cells. Dev Cell 13: 796–811.
50. MitsushimaM, ToyoshimaF, NishidaE (2009) Dual role of Cdc42 in spindle orientation control of adherent cells. Mol Cell Biol 29: 2816–2827.
51. OsmaniN, VitaleN, BorgJP, Etienne-MannevilleS (2006) Scrib controls Cdc42 localization and activity to promote cell polarization during astrocyte migration. Curr Biol 16: 2395–2405.
52. ShackletonM, VaillantF, SimpsonKJ, StinglJ, SmythGK, et al. (2006) Generation of a functional mammary gland from a single stem cell. Nature 439: 84–88.
53. BourasT, PalB, VaillantF, HarburgG, Asselin-LabatML, et al. (2008) Notch signaling regulates mammary stem cell function and luminal cell-fate commitment. Cell Stem Cell 3: 429–441.
54. Asselin-LabatML, SutherlandKD, BarkerH, ThomasR, ShackletonM, et al. (2007) Gata-3 is an essential regulator of mammary-gland morphogenesis and luminal-cell differentiation. Nat Cell Biol 9: 201–209.
55. LimE, VaillantF, WuD, ForrestNC, PalB, et al. (2009) Aberrant luminal progenitors as the candidate target population for basal tumor development in BRCA1 mutation carriers. Nat Med 15: 907–913.
56. OakesSR, NaylorMJ, Asselin-LabatML, BlazekKD, Gardiner-GardenM, et al. (2008) The Ets transcription factor Elf5 specifies mammary alveolar cell fate. Genes Dev 22: 581–586.
57. ElsumIA, YatesLL, PearsonHB, PhesseTJ, LongF, et al. (2013) Scrib heterozygosity predisposes to lung cancer and cooperates with KRas hyperactivation to accelerate lung cancer progression in vivo. Oncogene doi: 10.1038/onc.2013.498
58. WhyteJ, BerginO, BianchiA, McNallyS, MartinF (2009) Key signalling nodes in mammary gland development and cancer. Mitogen-activated protein kinase signalling in experimental models of breast cancer progression and in mammary gland development. Breast Cancer Res 11: 209.
59. YoungLC, HartigN, Munoz-AlegreM, Oses-PrietoJA, DurduS, et al. (2013) An MRAS, SHOC2, and SCRIB Complex Coordinates ERK Pathway Activation with Polarity and Tumorigenic Growth. Mol Cell 52: 679–692.
60. LuoYP, ZhouH, KruegerJ, KaplanC, LiaoD, et al. (2010) The role of proto-oncogene Fra-1 in remodeling the tumor microenvironment in support of breast tumor cell invasion and progression. Oncogene 29: 662–673.
61. XuKP, DingY, LingJ, DongZ, YuFS (2004) Wound-induced HB-EGF ectodomain shedding and EGFR activation in corneal epithelial cells. Invest Ophthalmol Vis Sci 45: 813–820.
62. LiX, YangH, LiuJ, SchmidtMD, GaoT (2011) Scribble-mediated membrane targeting of PHLPP1 is required for its negative regulation of Akt. EMBO Rep 12: 818–824.
63. MedinaD (2000) The preneoplastic phenotype in murine mammary tumorigenesis. J Mammary Gland Biol Neoplasia 5: 393–407.
64. MiermontAM, ParrishAR, FurthPA (2010) Role of ERalpha in the differential response of Stat5a loss in susceptibility to mammary preneoplasia and DMBA-induced carcinogenesis. Carcinogenesis 31: 1124–1131.
65. RadaelliE, ArnoldA, PapanikolaouA, Garcia-FernandezRA, MattielloS, et al. (2009) Mammary tumor phenotypes in wild-type aging female FVB/N mice with pituitary prolactinomas. Vet Pathol 46: 736–745.
66. CardiffRD, AnverMR, GustersonBA, HennighausenL, JensenRA, et al. (2000) The mammary pathology of genetically engineered mice: the consensus report and recommendations from the Annapolis meeting. Oncogene 19: 968–988.
67. MailleuxAA, OverholtzerM, SchmelzleT, BouilletP, StrasserA, et al. (2007) BIM regulates apoptosis during mammary ductal morphogenesis, and its absence reveals alternative cell death mechanisms. Dev Cell 12: 221–234.
68. ReginatoMJ, MillsKR, BeckerEB, LynchDK, BonniA, et al. (2005) Bim regulation of lumen formation in cultured mammary epithelial acini is targeted by oncogenes. Mol Cell Biol 25: 4591–4601.
69. JechlingerM, PodsypaninaK, VarmusH (2009) Regulation of transgenes in three-dimensional cultures of primary mouse mammary cells demonstrates oncogene dependence and identifies cells that survive deinduction. Genes Dev 23: 1677–1688.
70. PeaseJC, TirnauerJS (2011) Mitotic spindle misorientation in cancer - out of alignment and into the fire. J Cell Sci 124: 1007–1016.
71. TaddeiI, DeugnierMA, FaraldoMM, PetitV, BouvardD, et al. (2008) Beta1 integrin deletion from the basal compartment of the mammary epithelium affects stem cells. Nat Cell Biol 10: 716–722.
72. TangN, MarshallWF, McMahonM, MetzgerRJ, MartinGR (2011) Control of mitotic spindle angle by the RAS-regulated ERK1/2 pathway determines lung tube shape. Science 333: 342–345.
73. KashimataM, SayeedS, KaA, Onetti-MudaA, SakagamiH, et al. (2000) The ERK-1/2 signaling pathway is involved in the stimulation of branching morphogenesis of fetal mouse submandibular glands by EGF. Dev Biol 220: 183–196.
74. FisherCE, MichaelL, BarnettMW, DaviesJA (2001) Erk MAP kinase regulates branching morphogenesis in the developing mouse kidney. Development 128: 4329–4338.
75. BalmannoK, CookSJ (1999) Sustained MAP kinase activation is required for the expression of cyclin D1, p21Cip1 and a subset of AP-1 proteins in CCL39 cells. Oncogene 18: 3085–3097.
76. ChalmersCJ, GilleyR, MarchHN, BalmannoK, CookSJ (2007) The duration of ERK1/2 activity determines the activation of c-Fos and Fra-1 and the composition and quantitative transcriptional output of AP-1. Cell Signal 19: 695–704.
77. FataJE, MoriH, EwaldAJ, ZhangH, YaoE, et al. (2007) The MAPK(ERK-1,2) pathway integrates distinct and antagonistic signals from TGFalpha and FGF7 in morphogenesis of mouse mammary epithelium. Dev Biol 306: 193–207.
78. BaldysA, GoozM, MorinelliTA, LeeMH, RaymondJRJr, et al. (2009) Essential role of c-Cbl in amphiregulin-induced recycling and signaling of the endogenous epidermal growth factor receptor. Biochemistry 48: 1462–1473.
79. PasicL, Eisinger-MathasonTS, VelayudhanBT, MoskalukCA, BreninDR, et al. (2011) Sustained activation of the HER1-ERK1/2-RSK signaling pathway controls myoepithelial cell fate in human mammary tissue. Genes Dev 25: 1641–1653.
80. EcclesSA (2011) The epidermal growth factor receptor/Erb-B/HER family in normal and malignant breast biology. Int J Dev Biol 55: 685–696.
81. PetersenOW, Ronnov-JessenL, HowlettAR, BissellMJ (1992) Interaction with basement membrane serves to rapidly distinguish growth and differentiation pattern of normal and malignant human breast epithelial cells. Proc Natl Acad Sci U S A 89: 9064–9068.
82. WangF, HansenRK, RadiskyD, YonedaT, Barcellos-HoffMH, et al. (2002) Phenotypic reversion or death of cancer cells by altering signaling pathways in three-dimensional contexts. J Natl Cancer Inst 94: 1494–1503.
83. BeliveauA, MottJD, LoA, ChenEI, KollerAA, et al. (2010) Raf-induced MMP9 disrupts tissue architecture of human breast cells in three-dimensional culture and is necessary for tumor growth in vivo. Genes Dev 24: 2800–2811.
84. MuthuswamySK, LiD, LelievreS, BissellMJ, BruggeJS (2001) ErbB2, but not ErbB1, reinitiates proliferation and induces luminal repopulation in epithelial acini. Nat Cell Biol 3: 785–792.
85. WarrenSL, HandelLM, NelsonWJ (1988) Elevated expression of pp60c-src alters a selective morphogenetic property of epithelial cells in vitro without a mitogenic effect. Mol Cell Biol 8: 632–646.
86. AndrechekER, WhiteD, MullerWJ (2005) Targeted disruption of ErbB2/Neu in the mammary epithelium results in impaired ductal outgrowth. Oncogene 24: 932–937.
87. GuyCT, CardiffRD, MullerWJ (1996) Activated neu induces rapid tumor progression. J Biol Chem 271: 7673–7678.
88. EspinaV, LiottaLA (2010) What is the malignant nature of human ductal carcinoma in situ? Nat Rev Cancer 11: 68–75.
89. van de VijverMJ (2005) Biological variables and prognosis of DCIS. Breast 14: 509–519.
90. LiuE, ThorA, HeM, BarcosM, LjungBM, et al. (1992) The HER2 (c-erbB-2) oncogene is frequently amplified in in situ carcinomas of the breast. Oncogene 7: 1027–1032.
91. MittalS, SubramanyamD, DeyD, KumarRV, RangarajanA (2009) Cooperation of Notch and Ras/MAPK signaling pathways in human breast carcinogenesis. Mol Cancer 8: 128.
92. van de VijverMJ, PeterseJL, MooiWJ, WismanP, LomansJ, et al. (1988) Neu-protein overexpression in breast cancer. Association with comedo-type ductal carcinoma in situ and limited prognostic value in stage II breast cancer. N Engl J Med 319: 1239–1245.
93. VosCB, ter HaarNT, RosenbergC, PeterseJL, Cleton-JansenAM, et al. (1999) Genetic alterations on chromosome 16 and 17 are important features of ductal carcinoma in situ of the breast and are associated with histologic type. Br J Cancer 81: 1410–1418.
94. SongY, SongS, ZhangD, ZhangY, ChenL, et al. (2006) An association of a simultaneous nuclear and cytoplasmic localization of Fra-1 with breast malignancy. BMC Cancer 6: 298.
95. ChiappettaG, FerraroA, BottiG, MonacoM, PasquinelliR, et al. (2007) FRA-1 protein overexpression is a feature of hyperplastic and neoplastic breast disorders. BMC Cancer 7: 17.
96. ZajchowskiDA, BartholdiMF, GongY, WebsterL, LiuHL, et al. (2001) Identification of gene expression profiles that predict the aggressive behavior of breast cancer cells. Cancer Res 61: 5168–5178.
97. LogulloAF, StiepcichMM, OsorioCA, NonogakiS, PasiniFS, et al. (2011) Role of Fos-related antigen 1 in the progression and prognosis of ductal breast carcinoma. Histopathology 58: 617–625.
98. PhilipsA, ChalbosD, RochefortH (1993) Estradiol increases and anti-estrogens antagonize the growth factor-induced activator protein-1 activity in MCF7 breast cancer cells without affecting c-fos and c-jun synthesis. J Biol Chem 268: 14103–14108.
99. BelguiseK, KersualN, GaltierF, ChalbosD (2005) FRA-1 expression level regulates proliferation and invasiveness of breast cancer cells. Oncogene 24: 1434–1444.
100. LambeM, HsiehCC, ChanHW, EkbomA, TrichopoulosD, et al. (1996) Parity, age at first and last birth, and risk of breast cancer: a population-based study in Sweden. Breast Cancer Res Treat 38: 305–311.
101. RussoIH, RussoJ (2011) Pregnancy-induced changes in breast cancer risk. J Mammary Gland Biol Neoplasia 16: 221–233.
102. DowLE, BrumbyAM, MuratoreR, CoombeML, SedeliesKA, et al. (2003) hScrib is a functional homologue of the Drosophila tumour suppressor Scribble. Oncogene 22: 9225–9230.
103. LivakKJ, SchmittgenTD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2(−Delta Delta C(T)) Method. Methods 25: 402–408.
Štítky
Genetika Reprodukční medicínaČlánek vyšel v časopise
PLOS Genetics
2014 Číslo 5
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