Project description:RNA was extracted from cells using Aurum Total RNA kit from Bio-Rad Laboratories, Inc., Hercules, CA following the manufacturer’s recommendations. Gene expression profiling was performed using the BeadChip HumanHT-12 v4 Expression kit from Illumina®, which contains 47,231 gene-probes (Illumina® Inc., San Diego, CA). The raw signal intensities were imported and analyzed using the GenomeStudio® data software. After background subtraction and normalization, the signal intensity values were exported to the Partek® genomics expression analysis suite using “Partek's Report Plug-in” option in the GenomeStudio® software. Differentially expressed genes in the dox- versus vehicle-treated samples were identified using the “gene expression” workflow in the Partek® software. T47D cells hoaboring a doxycycline inducible shPIP construct were treated for 24 or 48 hours with 250 ng/mL of doxycycline and their mRNAs analyzed in biological triplicates (a total of 12 samples) using Illumina‘s HumanHT-12 v4 BeadChips. The samples for each time point comprised of three samples each for doxycycline or equal volume of water as vehicle control.

Project description:RNA was extracted from cells using Aurum Total RNA kit from Bio-Rad Laboratories, Inc., Hercules, CA following the manufacturerM-bM-^@M-^Ys recommendations. Gene expression profiling was performed using the BeadChip HumanHT-12 v4 Expression kit from IlluminaM-BM-., which contains 47,231 gene-probes (IlluminaM-BM-. Inc., San Diego, CA). The raw signal intensities were imported and analyzed using the GenomeStudioM-BM-. data software. After background subtraction and normalization, the signal intensity values were exported to the PartekM-BM-. genomics expression analysis suite using M-bM-^@M-^\Partek's Report Plug-inM-bM-^@M-^] option in the GenomeStudioM-BM-. software. Differentially expressed genes in the dox- versus vehicle-treated samples were identified using the M-bM-^@M-^\gene expressionM-bM-^@M-^] workflow in the PartekM-BM-. software. T47D cells hoaboring a doxycycline inducible shPIP construct were treated for 24 or 48 hours with 250 ng/mL of doxycycline and their mRNAs analyzed in biological triplicates (a total of 12 samples) using IlluminaM-bM-^@M-^Xs HumanHT-12 v4 BeadChips. The samples for each time point comprised of three samples each for doxycycline or equal volume of water as vehicle control.

Project description:RNA was extracted from cells using Aurum Total RNA kit from Bio-Rad Laboratories, Inc., Hercules, CA following the manufacturer’s recommendations. Gene expression profiling was performed using the BeadChip HumanHT-12 v4 Expression kit from Illumina®, which contains 47,231 gene-probes (Illumina® Inc., San Diego, CA). The raw signal intensities were imported and analyzed using the GenomeStudio® data software. After background subtraction and normalization, the signal intensity values were exported to the Partek® genomics expression analysis suite using “Partek's Report Plug-in” option in the GenomeStudio® software. Differentially expressed genes in the dox- versus vehicle-treated samples were identified using the “gene expression” workflow in the Partek® software.

Project description:Tumors that express estrogen receptor alpha (ER?+) comprise 75% of breast cancers in women. While treatments directed against this receptor have successfully lowered mortality rates, many primary tumors initially or later exhibit resistance. The paucity of murine models of this "luminal" tumor subtype has hindered studies of factors that promote their pathogenesis and modulate responsiveness to estrogen-directed therapeutics. Since epidemiologic studies closely link prolactin and the development of ER?+ tumors in women, we examined characteristics of the aggressive ER?+ and ER?- carcinomas which develop in response to mammary prolactin in a murine transgenic model (neu-related lipocalin- prolactin (NRL-PRL)). To evaluate their relationship to clinical tumors, we determined phenotypic relationships among these carcinomas, other murine models of breast cancer, and features of luminal tumors in women.We examined a panel of prolactin-induced tumors for characteristics relevant to clinical tumors: histotype, ER?/progesterone receptor (PR) expression and estrogen responsiveness, Activating Protein 1 (AP-1) components, and phosphorylation of signal transducer and activator of transcription 5 (Stat5), extracellular signal regulated kinase (ERK) 1/2 and AKT. We compared levels of transcripts in the ER?-associated "luminal" signature that defines this subtype of tumors in women and transcripts enriched in various mammary epithelial lineages to other well-studied genetically modified murine models of breast cancer. Finally, we used microarray analyses to compare prolactin-induced ER?+ and ER?- tumors, and examined responsiveness to estrogen and the anti-estrogen, Faslodex, in vivo.Prolactin-induced carcinomas were markedly diverse with respect to histotype, ER?/PR expression, and activated signaling cascades. They constituted a heterogeneous, but distinct group of murine mammary tumors, with molecular features of the luminal subtype of human breast cancer. In contrast to morphologically normal and hyperplastic structures in NRL-PRL females, carcinomas were insensitive to ER?-mediated signals. These tumors were distinct from mouse mammary tumor virus (MMTV)-neu tumors, and contained elevated transcripts for factors associated with luminal/alveolar expansion and differentiation, suggesting that they arose from physiologic targets of prolactin. These features were shared by ER?+ and ER?- tumors, suggesting a common origin, although the former exhibited transcript profiles reflecting greater differentiation.Our studies demonstrate that prolactin can promote diverse carcinomas in mice, many of which resemble luminal breast cancers, providing a novel experimental model to examine the pathogenesis, progression and treatment responsiveness of this tumor subtype.

Project description:Estrogen Receptor alpha (ER?) activation by estrogenic hormones induces luminal breast cancer cell proliferation. However, ER? plays also important hormone-independent functions to maintain breast tumor cells epithelial phenotype. We reported previously by RNA-Seq that in MCF-7 cells in absence of hormones ER? down-regulation changes the expression of several genes linked to cellular development, representing a specific subset of estrogen-induced genes. Here, we report regulation of long non-coding RNAs from the same experimental settings. A list of 133 Apo-ER?-Regulated lncRNAs (AER-lncRNAs) was identified and extensively characterized using published data from cancer cell lines and tumor tissues, or experiments on MCF-7 cells. For several features, we ran validation using cell cultures or fresh tumor biopsies. AER-lncRNAs represent a specific subset, only marginally overlapping estrogen-induced transcripts, whose expression is largely restricted to luminal cells and which is able to perfectly classify breast tumor subtypes. The most abundant AER-lncRNA, DSCAM-AS1, is expressed in ER?+ breast carcinoma, but not in pre-neoplastic lesions, and correlates inversely with EMT markers. Down-regulation of DSCAM-AS1 recapitulated, in part, the effect of silencing ER?, i.e. growth arrest and induction of EMT markers. In conclusion, we report an ER?-dependent lncRNA set representing a novel luminal signature in breast cancer cells.

Project description:Breast cancer is one of the most common malignancies and the leading cause of cancer-associated death among women. Anterior gradient 3 (AGR3) is a cancer-associated gene and is similar to its homologous oncogene AGR2. However, whether AGR3 participates in breast cancer progression remains unclear. The present study aimed to investigate the function of AGR3 in ER-positive breast cancer. In the present study, reverse transcription-quantitative PCR was used to detect AGR3 mRNA expression in breast cancer tissues and cell lines; linear correlation analysis was used to investigate the correlation between AGR3 and estrogen receptor 1 (ESR1) expression in breast cancer via GEO dataset analysis; western blotting was used to assess the levels of AGR3, ER and GAPDH; small interfering (si)RNA transfection was used to knock down AGR3 and ESR1 expression; and finally the Cell Counting Kit-8 assay was used to evaluate cell viability. In the present study, AGR3 expression was markedly increased in estrogen receptor (ER)-positive breast cancer tissues and cell lines compared with that in ER-negative breast cancer. AGR3 expression was upregulated in estrogen-treated T47D cells, whereas 4-hydroxytamoxifen, an inhibitor of estrogen-ER activity in breast cancer cells, downregulated AGR3 expression in T47D cells. Functional assays demonstrated that knockdown of AGR3 using siRNAs inhibited T47D cell proliferation compared with that of the negative control group. Additionally, AGR3 expression was decreased after knocking down ESR1. The present results suggested that AGR3 may serve an important role in estrogen-mediated cell proliferation in breast cancer and that AGR3 knockdown may be a potential therapeutic strategy for ER-positive breast cancer.

Project description:Estrogen receptor-? (ER?) is a ligand-inducible protein which mediates estrogenic hormones signaling and defines the luminal BC phenotype. Recently, we demonstrated that even in absence of ligands ER? (apoER?) binds chromatin sites where it regulates transcription of several protein-coding and lncRNA genes. Noteworthy, apoER?-regulated lncRNAs marginally overlap estrogen-induced transcripts, thus representing a new signature of luminal BC genes. By the analysis of H3K27ac enrichment in hormone-deprived MCF-7 cells, we defined a set of Super Enhancers (SEs) occupied by apoER?, including one mapped in proximity of the DSCAM-AS1 lncRNA gene. This represents a paradigm of apoER? activity since its expression is largely unaffected by estrogenic treatment, despite the fact that E2 increases ER? binding on DSCAM-AS1 promoter. We validated the enrichment of apoER?, p300, GATA3, FoxM1 and CTCF at both DSCAM-AS1 TSS and at its associated SE by ChIP-qPCR. Furthermore, by analyzing MCF-7 ChIA-PET data and by 3C assays, we confirmed long range chromatin interaction between the SE and the DSCAM-AS1 TSS. Interestingly, CTCF and p300 binding showed an enrichment in hormone-depleted medium and in the presence of ER?, elucidating the dynamics of the estrogen-independent regulation of DSCAM-AS1 expression. The analysis of this lncRNA provides a paradigm of transcriptional regulation of a luminal specific apoER? regulated lncRNA.

Project description:Prolactin-induced protein (PIP) is a small secreted glycoprotein carrying several N-linked carbohydrate chains. The expression of PIP is generally restricted to cells with apocrine properties. It was found in apocrine glands of the axilla, vulva, eyelid, ear canal, and seminal vesicle. Being a secretory protein, PIP is present in seminal plasma, saliva, lacrimal fluid, tears, sweat gland secretion. Little is known about the biological role of PIP. It binds to numerous proteins, however, in most cases the biological role of such interactions is poorly understood. A notable exception is its binding to CD4 receptors present on the surface of T lymphocytes, macrophages, and spermatozoa. The available data suggest that PIP can have immunomodulatory functions and plays an important role in cell-mediate adoptive immunity. PIP binds to bacteria from several genera, which suggests that this glycoprotein may participate also in innate immunity and protection of hosts against microbial infections. Increased levels of PIP were found in several types of human cancer (prostate, sweat and salivary gland cancers). It is especially common in breast cancer, however, data on the expression of PIP in normal and cancerous breast cancer tissues are to some degree conflicting. In early studies, it was shown that PIP is absent or its expression is very low in normal breast epithelium, whereas in breast cancers PIP is frequently expressed and present in large amounts. On the other hand, later study showed that expression of PIP is lower in advanced apocrine carcinomas and invasive carcinomas than in, respectively, in situ carcinomas and adjacent normal tissue. The most recent study revealed that PIP gene expression decreased gradually along with higher stage and grade of breast cancer. In agreement with these data, it was shown that that low levels or the lack of PIP expression are associated with a worse response of breast cancer cells to chemotherapy. It was proposed that PIP plays important role in the development and progression of breast cancer. However, its role in these processes is both unclear and controversial. In this review, the role of PIP in both physiological processes and carcinogenesis is discussed.

Project description:Molecular apocrine is a subtype of estrogen receptor (ER)-negative breast cancer that is characterized by a steroid-response gene signature. We have recently identified a positive feedback loop between androgen receptor (AR) and extracellular signal-regulated kinase (ERK) signaling in this subtype. In this study, we investigated the transcriptional regulation of molecular apocrine genes by the AR-ERK feedback loop.The transcriptional effects of AR and ERK inhibition on molecular apocrine genes were assessed in cell lines. The most regulated gene in this process, prolactin-induced protein (PIP), was further studied using immunohistochemistry of breast tumors and xenograft models. The transcriptional regulation of PIP was assessed by luciferase reporter assay and chromatin immunoprecipitation. The functional significance of PIP in cell invasion and viability was assessed using siRNA knockdown experiments and the mechanism of PIP effect on integrin-?1 signaling was studied using immunoblotting and immunoprecipitation.We found that PIP is the most regulated molecular apocrine gene by the AR-ERK feedback loop and is overexpressed in ER-/AR+ breast tumors. In addition, PIP expression is regulated by AR-ERK signaling in xenograft models. These observations are explained by the fact that PIP is a target gene of the ERK-CREB1 pathway and is also induced by AR activation. Furthermore, we demonstrated that PIP has a significant functional role in maintaining cell invasion and viability of molecular apocrine cells because of a positive regulatory effect on the Integrin-ERK and Integrin-Akt signaling pathways. In fact, PIP-knockdown markedly decreases the phosphorylation of ERK, Akt, and CREB1. Importantly, PIP knockdown leads to a marked reduction of integrin-?1 binding to ILK1 and ErbB2 that can be reversed by the addition of fibronectin fragments.We have identified a novel feedback loop between PIP and CREB1 mediated through the Integrin signaling pathway. In this process, PIP cleaves fibronectin to release fragments that activate integrin signaling, which in turn increases PIP expression through the ERK-CREB1 pathway. In addition, we demonstrated that PIP expression has a profound effect on cell invasion and the viability of molecular apocrine cells. Therefore, PIP signaling may be a potential therapeutic target in molecular apocrine breast cancer.

Project description:In prostate and breast cancer, the androgen receptor and estrogen receptor (ER) mediate induction of androgen- and estrogen-responsive genes respectively and stimulate cell proliferation in response to the binding of their cognate steroid hormones. Sirtuin 1 (SIRT1) is a NAD+-dependent class III histone deacetylase that has been linked to gene silencing, control of the cell cycle, apoptosis, and energy homeostasis. In prostate cancer, SIRT1 is required for androgen antagonist-mediated transcriptional repression and growth suppression of prostate cancer cells. Whether SIRT1 plays a similar role in the actions of estrogen or antagonists had not been determined. We report here that SIRT1 represses the transcriptional and proliferative response of breast cancer cells to estrogens, and this repression is ER? dependent. Inhibition of SIRT1 activity results in the phosphorylation of ER? in an AKT-dependent manner, and this activation requires phosphoinositide 3-kinase activity. Phosphorylated ER? subsequently accumulates in the nucleus, where ER? binds DNA ER-responsive elements and activates transcription of estrogen-responsive genes. This ER-dependent transcriptional activation augments estrogen-induced signaling, but also activates ER signaling in the absence of estrogen, thus defining a novel and unexpected mechanism of ligand-independent ER?-mediated activation and target gene transcription. Like ligand-dependent activation of ER?, SIRT1 inhibition-mediated ER? activation in the absence of estrogen also results in breast cancer cell proliferation. Together, these data demonstrate that SIRT1 regulates the most important cell signaling pathway for the growth of breast cancer cells, both in the presence and the absence of estrogen.