Androgens and mesenchymal factors are essential extracellular signals for the development as well as the functional activity of the prostate epithelium. Little is known of the intraepithelial determinants that are involved in prostatic differentiation. Here we found that hepatocyte nuclear factor-3 alpha (HNF-3 alpha), an endoderm developmental factor, is essential for androgen receptor (AR)-mediated prostatic gene activation. Two HNF-3 cis-regulatory elements were identified in the rat probasin (PB) gene promoter, each immediately adjacent to an androgen response element. Remarkably, similar organization of HNF-3 and AR binding sites was observed in the prostate-specific antigen (PSA) gene core enhancer, suggesting a common functional mechanism. Mutations that disrupt these HNF-3 motifs significantly abolished the maximal androgen induction of PB and PSA activities. Overexpressing a mutant HNF-3 alpha deleted in the C-terminal region inhibited the androgen-induced promoter activity in LNCaP cells where endogenous HNF-3 alpha is expressed. Chromatin immunoprecipitation revealed in vivo that the occupancy of HNF-3 alpha on PSA enhancer can occur in an androgen-depleted condition, and before the recruitment of ligand-bound AR. A physical interaction of HNF-3 alpha and AR was detected through immunoprecipitation and confirmed by glutathione-S-transferase pull-down. This interaction is directly mediated through the DNA-binding domain/hinge region of AR and the forkhead domain of HNF-3 alpha. In addition, strong HNF-3 alpha expression, but not HNF-3 beta or HNF-3 gamma, is detected in both human and mouse prostatic epithelial cells where markers (PSA and PB) of differentiation are expressed. Taken together, these data support a model in which regulatory cues from the cell lineage and the extracellular environment coordinately establish the prostatic differentiated response.
The molecular mechanism(s) for prostate cancer progression to androgen independence are poorly understood. We have recently shown that Foxa1 and Foxa2 proteins are differentially expressed in epithelial cells during murine prostate development, growth, and adult function. Currently, the role of Foxa proteins in prostate cancer development and progression is unknown. Foxa protein expression was investigated in the LPB-Tag LADY mouse prostate cancer models, in human prostate cancer specimens, and various prostate cancer cell lines using Western blot and immunostaining analysis. In vitro transient transfection, studies were performed to investigate Foxa/prostate-specific gene regulation. Foxa1 was strongly expressed in areas of prostatic intraepithelial neoplasia (PIN) in both the androgen dependent 12T-7f and in the metastatic, androgen independent 12T-10 LADY models. Prominent Foxa1 and Foxa2 expression was observed in 12T-10 invasive undifferentiated neuroendocrine carcinomas, in the hormone independent and metastasizing 12T-10 derived, NE-10 allograft tumors, and in all metastatic lesions isolated from 12T-10 mice. Foxa1 protein expression was always observed in human prostate carcinomas, regardless of Gleason grade score, while Foxa2 was only detected in neuroendocrine small cell carcinomas and in some high Gleason score adenocarcinomas. Foxa proteins were also differentially expressed in three prostate cancer cell lines. Importantly, in vitro functional assays demonstrated that Foxa2 could activate androgen-dependent prostate-specific genes in an androgen receptor and ligand-independent manner. These results suggest that Foxa proteins are important in prostate carcinogenesis. In particular, Foxa2 may be involved in progression of prostate cancer to androgen independence. As such, Foxa proteins may represent novel targets for therapeutic intervention.
Anterior Gradient Homolog 2 (AGR2) is expressed by the normal intestine and by most human adenocarcinomas, including those derived from the esophagus, pancreas, lung, breast, ovary, and prostate. Xenografts of human adenocarcinoma cell lines in nude mice previously demonstrated that AGR2 supports tumor growth. In addition, AGR2 is able to induce in vitro a transformed phenotype in fibroblast and epithelial cell lines. The mechanism underlying the growth promoting effects of AGR2 is unknown. The present study shows that AGR2 induces expression of amphiregulin (AREG), a growth promoting EGFR ligand. Induced AREG expression in adenocarcinoma cells is able to rescue the transformed phenotype that is lost when AGR2 expression is reduced. Additional experiments demonstrate that AGR2 induction of AREG is mediated by activation of the Hippo signaling pathway co-activator, YAP1. Thus AGR2 promotes growth by regulating the Hippo and EGF receptor signaling pathways. Anterior Gradient Homolog 2 (AGR2)2 encodes a 17 kDa protein that is highly conserved in vertebrates. AGR2 was first described in Xenopus laevis, where its expression is responsible for the development of a glandular organ called the cement gland (1). A significant role in tissue regeneration was established for AGR2 in salamanders where it functions in nerve-dependent limb regeneration (2). AGR2 is also expressed by secretory cells in the normal murine intestine (3). In humans, enhanced AGR2 expression was first described in breast cancer, which was followed by similar observations in most human adenocarcinomas, including those derived from the esophagus, pancreas, lung, ovary, and prostate (4 -11). Both in vitro and in vivo studies demonstrated that AGR2 promotes tumor growth and metastasis (3,6,12). In adenocarcinoma cell lines and nontransformed fibroblasts, AGR2 induces cell proliferation and anchorage-independent growth in soft agar. Human adenocarcinoma cell lines grown in vivo as mouse xenografts result in smaller tumors when AGR2 expression is reduced (3, 6). In vitro studies examining cell migration suggested that AGR2 may function in a non-cell autonomous fashion (3).The mechanisms responsible for AGR2 effects on growth and transformation are unknown. AGR2 expression in humans is restricted to epithelial cells, for which the EGF signaling pathway serves a regulatory role in controlling cell growth. The present study tested the hypothesis that AGR2 affects cell signaling, and potentially that of the EGFR pathway, which has established significance in epithelial cancers. EXPERIMENTAL PROCEDURESCell Lines-H460 lung adenocarcinoma cells obtained from Dr. David Beer (University of Michigan, Ann Arbor, MI) were previously known as SEG-1 and was the focus of a previous publication (3). A recent report revealed that SEG-1 cells are actually H460 lung adenocarcinoma cells (13). The H460 cells used in this study were reassessed by Winand Dinjens, Erasmus Medical Center, Rotterdam, the Netherlands using the Powerplex 16 TM system (Promega Corp., Madison, WI) to...
Background: Whether AGR2 promotes adenocarcinoma growth as a secreted or ER-localized protein is not known. Results: A unique carboxyl-terminal motif, KTEL, is required for AGR2 ER localization and function. Conclusion: Not all ER localization motifs are interchangeable. Significance: Specific ER localization signals may be required for protein function. AGR2's tumor-promoting effects are mediated from the ER and not as a secreted protein.
The glucocorticoid receptor (NR3C1, also known as GR) binds to specific DNA sequences and directly induces transcription of anti-inflammatory genes that contribute to cytokine repression, frequently in cooperation with NF-kB. Whether inflammatory repression also occurs through local interactions between GR and inflammatory gene regulatory elements has been controversial. Here, using global run-on sequencing (GRO-seq) in human airway epithelial cells, we show that glucocorticoid signaling represses transcription within 10 min. Many repressed regulatory regions reside within “hyper-ChIPable” genomic regions that are subject to dynamic, yet nonspecific, interactions with some antibodies. When this artifact was accounted for, we determined that transcriptional repression does not require local GR occupancy. Instead, widespread transcriptional induction through canonical GR binding sites is associated with reciprocal repression of distal TNF-regulated enhancers through a chromatin-dependent process, as evidenced by chromatin accessibility and motif displacement analysis. Simultaneously, transcriptional induction of key anti-inflammatory effectors is decoupled from primary repression through cooperation between GR and NF-kB at a subset of regulatory regions. Thus, glucocorticoids exert bimodal restraints on inflammation characterized by rapid primary transcriptional repression without local GR occupancy and secondary anti-inflammatory effects resulting from transcriptional cooperation between GR and NF-kB.
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