Chronic inflammation is associated with advanced prostate cancer (PCa), although the mechanisms governing inflammation-mediated PCa progression are not fully understood. PCa progresses to an androgen independent phenotype that is incurable. We previously showed that androgen independent, androgen receptor negative (AR−) PCa cell lines have high p62/SQSTM1 levels required for cell survival. We also showed that factors in the HS-5 bone marrow stromal cell (BMSC) conditioned medium can upregulate p62 in AR+ PCa cell lines, leading us to investigate AR expression under those growth conditions. In this paper, mRNA, protein, and subcellular analyses reveal that HS-5 BMSC conditioned medium represses AR mRNA, protein, and nuclear accumulation in the C4-2 PCa cell line. Using published gene expression data, we identify the inflammatory cytokine, IL-1β, as a candidate BMSC paracrine factor to regulate AR expression and find that IL-1β is sufficient to both repress AR and upregulate p62 in multiple PCa cell lines. Immunostaining demonstrates that, while the C4-2 population shows a primarily homogeneous response to factors in HS-5 BMSC conditioned medium, IL-1β elicits a strikingly heterogeneous response; suggesting that there are other regulatory factors in the conditioned medium. Finally, while we observe concomitant AR loss and p62 upregulation in IL-1β-treated C4-2 cells, silencing of AR or p62 suggests that IL-1β regulates their protein accumulation through independent pathways. Taken together, these in vitro results suggest that IL-1β can drive PCa progression in an inflammatory microenvironment through AR repression and p62 induction to promote the development and survival of androgen independent PCa.
Protein arginine methyltransferases (PRMTs) catalyze the posttranslational methylation of arginine, which is important in a range of biological processes, including epigenetic regulation, signal transduction, and cancer progression. Although previous studies of PRMT1 mutants suggest that the dimerization arm and the N-terminal region of PRMT1 are important for activity, the contributions of these regions to the structural architecture of the protein and its catalytic methylation activity remain elusive. Molecular dynamics (MD) simulations performed in this study showed that both the dimerization arm and the N-terminal region undergo conformational changes upon dimerization. Because a correlation was found between the two regions despite their physical distance, an allosteric pathway mechanism was proposed based on a network topological analysis. The mutation of residues along the allosteric pathways markedly reduced the methylation activity of PRMT1, which may be attributable to the destruction of dimer formation and accordingly reduced S-adenosyl-L-methionine (SAM) binding. This study provides the first demonstration of the use of a combination of MD simulations, network topological analysis, and biochemical assays for the exploration of allosteric regulation upon PRMT1 dimerization. These findings illuminate the results of mechanistic studies of PRMT1, which have revealed that dimer formation facilitates SAM binding and catalytic methylation, and provided direction for further allosteric studies of the PRMT family.
It is well established that prostate cancer (PCa) cells hone to, adapt, and thrive in the bone. Importantly, bone metastases are found in over 80% of PCa deaths. Therefore, it is imperative to elucidate and characterize the molecular mechanisms that enable PCa cells to thrive in the bone and resist conventional PCa therapies, such as hormone ablation or anti-androgens. We found that the HS-5 bone marrow stromal cell (BMSC) line, a secretory BMSC line that can support hematopoietic stem cell growth, secretes paracrine factors that induce apoptosis in PCa cells. However a subpopulation of the PCa cells can survive the BMSC-induced death. The surviving PCa subpopulation differentiates into a neuronal morphology and looses androgen receptor (AR) expression, reminiscent of treatment-resistant neuroendocrine PCa. Ideally, the loss of AR would induce PCa cell death; however we observe a concomitant increase in the autophagy-related cell survival protein, p62/SQSTM1, and induction of cytoprotective autophagy. Furthermore, we find that interleukin-1 beta (IL-1β) and IL-6, inflammatory cytokine secreted by HS-5 BMSCs, are sufficient to promote PCa neuronal morphology, reduce AR accumulation, upregulate p62/SQSTM1 levels, and induce autophagy. In addition, genetic silencing of p62/SQSTM1 causes PCa cell death and pharmacological inhibition of cytokine or autophagy signaling attenuates PCa neuroendocrine differentiation. Thus, our PCa-bone marrow stromal cell model suggests that PCa cells can co-opt the immune system in the bone microenvironment leading to PCa androgen independence, treatment resistance, and survival in the bone. Furthermore, our data suggests that inhibiting inflammatory cytokine signaling and/or the autophagy process are rational strategies to combat PCa bone metastasis. Citation Format: Megan Chang, Micaela Morgado, Viral Patel, Michael Gwede, Mary Cindy Farach-Carson, Nikki Delk. Bone marrow stromal cell-secreted inflammatory cytokines promote treatment resistance and survival of prostate cancer cells. [abstract]. In: Abstracts: AACR Special Conference on Cellular Heterogeneity in the Tumor Microenvironment; 2014 Feb 26-Mar 1; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2015;75(1 Suppl):Abstract nr B15. doi:10.1158/1538-7445.CHTME14-B15
A Kinase Interating Protein 1 (AKIP1) is highly upregulated in prostate cancer and can mislocalize Protein Kinase A (PKA) by translocating it from the cytoplasm to the nucleus. Further, AKIP1 acts as a scaffold to stabilize interactions between PKA and other proteins, thereby influencing PKA‐mediated signaling. PKA also plays an important role in late‐stage, androgen‐independent prostate cancer by promoting androgen‐dependent transcription and nuclear localization of the androgen receptor. While it is apparent that AKIP1 plays an important regulatory role for PKA, the specific changes that are mediated by AKIP1 in prostate cancer remain largely unknown. Therefore, it is of great importance to understand the biological implications of nuclear PKA activity and how this relates to androgen receptor localization and signaling in late‐stage prostate cancer. To address this, we have developed novel peptide‐based chemical biology tools that act to disrupt protein‐protein interactions as a means to interrogate AKIP1 activity in the context of prostate cancer cells. By applying these chemically stabilized compounds, we can elegantly and selectively disrupt interactions between PKA and AKIP1 while leaving the catalytic activity of PKA intact, thereby enabling us to interrogate the role of AKIP1 in prostate cancer as well as uncover its regulatory role on androgen receptor signaling.
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