Prostate cancer (PCa) cells display abnormal expression of cytoskeletal proteins resulting in an augmented capacity to resist chemotherapy and colonize distant organs. We have previously shown that heme oxygenase 1 (HO-1) is implicated in cell morphology regulation in PCa. Here, through a multi 'omics' approach we define the HO-1 interactome in PCa, identifying HO-1 molecular partners associated with the integrity of the cellular cytoskeleton. The bioinformatics screening for these cytoskeletal-related partners reveal that they are highly misregulated in prostate adenocarcinoma compared with normal prostate tissue. Under HO-1 induction, PCa cells present reduced frequency in migration events, trajectory and cell velocity and, a significant higher proportion of filopodia-like protrusions favoring zippering among neighboring cells. Moreover forced expression of HO-1 was also capable of altering cell protrusions in transwell co-culture systems of PCa cells with MC3T3 cells (pre-osteoblastic cell line). Accordingly, these effects were reversed under siHO. Transcriptomics profiling evidenced significant modulation of key markers related to cell adhesion and cell–cell communication under HO-1 induction. The integration from our omics-based research provides a four molecular pathway foundation (ANXA2/HMGA1/POU3F1; NFRSF13/GSN; TMOD3/RAI14/VWF; and PLAT/PLAU) behind HO-1 regulation of tumor cytoskeletal cell compartments. The complementary proteomics and transcriptomics approaches presented here promise to move us closer to unravel the molecular framework underpinning HO-1 involvement in the modulation of cytoskeleton pathways, pushing toward a less aggressive phenotype in PCa.
An abrupt increase in metastatic growth as a consequence of the removal of primary tumors suggests that the concomitant resistance (CR) phenomenon might occur in human cancer. CR occurs in murine tumors and ROS-damaged phenylalanine, meta-tyrosine (m-Tyr), was proposed as the serum anti-tumor factor primarily responsible for CR. Herein, we demonstrate for the first time that CR happens in different experimental human solid tumors (prostate, lung anaplastic, and nasopharyngeal carcinoma). Moreover, m-Tyr was detected in the serum of mice bearing prostate cancer (PCa) xenografts. Primary tumor growth was inhibited in animals injected with m-Tyr. Further, the CR phenomenon was reversed when secondary implants were injected into mice with phenylalanine (Phe), a protective amino acid highly present in primary tumors. PCa cells exposed to m-Tyr in vitro showed reduced cell viability, downregulated NFκB/STAT3/Notch axis, and induced autophagy; effects reversed by Phe. Strikingly, m-Tyr administration also impaired both, spontaneous metastasis derived from murine mammary carcinomas (4T1, C7HI, and LMM3) and PCa experimental metastases. Altogether, our findings propose m-Tyr delivery as a novel approach to boost the therapeutic efficacy of the current treatment for metastasis preventing the escape from tumor dormancy.
Conditioning strategies constitute a relatively unexplored and exciting opportunity to shape tumor fate by targeting the tumor microenvironment. In this study, we assessed how hemin, a pharmacologic inducer of heme oxygenase-1 (HO-1), has an impact on prostate cancer development in an conditioning model. The stroma of C57BL/6 mice was conditioned by subcutaneous administration of hemin prior to TRAMP-C1 tumor challenge. Complementary and assays were performed to evaluate hemin effect on both angiogenesis and the immune response. To gain clinical insight, we used prostate cancer patient-derived samples in our studies to assess the expression of HO-1 and other relevant genes. Conditioning resulted in increased tumor latency and decreased initial growth rate. Histologic analysis of tumors grown in conditioned mice revealed impaired vascularization. Hemin-treated human umbilical vein endothelial cells (HUVEC) exhibited decreased tubulogenesis only in the presence of TRAMP-C1-conditioned media. Subcutaneous hemin conditioning hindered tumor-associated neovascularization in an Matrigel plug assay. In addition, hemin boosted CD8 T-cell proliferation and degranulation and antigen-specific cytotoxicity A significant systemic increase in CD8 T-cell frequency was observed in preconditioned tumor-bearing mice. Tumors from hemin-conditioned mice showed reduced expression of galectin-1 (Gal-1), key modulator of tumor angiogenesis and immunity, evidencing persistent remodeling of the microenvironment. We also found a subset of prostate cancer patient-derived xenografts and prostate cancer patient samples with mild HO-1 and low Gal-1 expression levels. These results highlight a novel function of a human-used drug as a means of boosting the antitumor response. .
Background: Prostate cancer (PCa) dissemination shows a tendency to develop in the bone, where heme oxygenase 1 (HO-1) plays a critical role in bone remodeling. Previously by LC/ESI-MSMS, we screened for HO-1 interacting proteins and identified annexin 2 (ANXA2). The aim of this study was to analyze the relevance of ANXA2/HO-1 in PCa and bone metastasis. Methods: We assessed ANXA2 levels using a co-culture transwell system of PC3 cells (pre-treated or not with hemin, an HO-1 specific inducer) and the pre-osteoclastic Raw264.7 cell line. Results: Under co-culture conditions, ANXA2 mRNA levels were significantly modulated in both cell lines. Immunofluorescence analysis unveiled a clear ANXA2 reduction in cell membrane immunostaining for Raw264.7 under the same conditions. This effect was supported by the detection of a decrease in Ca 2+ concentration in the conditioned medium. HO-1 induction in tumor cells prevented both, the ANXA2 intracellular relocation and the decrease in Ca 2+ concentration. Further, secretome analysis revealed urokinase (uPA) as a key player in the communication between osteoclast progenitors and PC3 cells. To assess the clinical significance of ANXA2/HO-1, we performed a bioinformatics analysis and identified that low expression of each gene strongly associated with poor prognosis in PCa regardless of the clinico-pathological parameters assessed. Further, these genes appear to behave in a dependent manner. Conclusions: ANXA2/HO-1 rises as a critical axis in PCa.Biomolecules 2020, 10, 467 2 of 24 microenvironment communicate and interact with each other to develop a fertile niche for the promotion of the metastatic process [3][4][5].Evidence has recognized inflammation as a risk factor for this neoplastic disease [6]. Heme oxygenase 1 (HO-1), encoded by the HMOX1 gene, is a stress response protein and a critical mediator of cellular homeostasis [7]. Although the role of HO-1 in cancer is controversial [8,9], we have shown that its pharmacologic or genetic upregulation is associated with a less aggressive phenotype in PCa [10]. HO-1 impairs tumor growth and angiogenesis in vivo and downregulates the expression of target genes associated with inflammation in PCa [11,12]. In the metastatic bone site, we demonstrated that HO-1 is capable of modulating signaling pathways relevant to skeletal PCa metastasis, such as FoxO/β-catenin and promotes bone remodeling when human tumor cells are transplanted into the femur of SCID mice [13]. Moreover, we have shown the direct effect of HO-1 on bone turnover and remodeling. When assessing the physiological impact of Hmox1 gene knockout on bone metabolism in vivo, histomorphometric analysis of Hmox1−/− mice bones exhibited significantly decreased bone density. A positive correlation between Hmox1 expression and key bone markers was observed in primary mouse osteoblasts (PMOs) [14]. These observations highlight the importance of HO-1 expression in bone, not only for the physiology of bone cells but also in the modulation of the communication between PMOs and PC...
Cancer is a risk factor for SARS-CoV-2 infection. Recent reports have shown that prostate cancer (PCa) patients who underwent androgen-deprivation therapies (ADT) were partially protected from COVID-19. The human myxovirus resistance gene 1 (MX1) is expressed in many tissues, including prostate, and we have previously demonstrated its antitumoral activity in PCa, tilting the balance of endoplasmic reticulum stress towards pro-death events. Another key aspect of this protein is its participation in the antiviral response. It is recognized as an IFN-stimulated gene (ISGs), especially during influenza virus infection. Currently, there are several ongoing clinical trials for COVID-19 prevention and/or treatment using type I or III interferons. However, IFN administration could enhance a "cytokine-storm" causing a hyper-inflammatory response and contributing to multiple organ failure. In this work we used a published case-control study (GSE152075) from SARS-CoV-2 positive (n=403) and negative patients (n=50) to analyze the response to infection assessing gene expression profiles of key host cell receptors and antiviral proteins. Additionally, given that MX1 was differentially expressed between COVID-19 and non-COVID-19 patients, we evaluated MX1 expression in A549 and Calu3 lung cell lines and ferrets infected with SARS-CoV-2. Since ADT seems to reduce SARS-CoV-2 infection incidence, we aimed to study MX1 regulation by dihydrotestosterone (DHT). We browsed publicly available ChIP-seq experiments evaluating androgen receptor (AR) binding sites in MX1 promoter and coding region in different PCa cell lines under DHT stimulation; and we treated LNCaP cells with DHT to assess MX1 expression under androgen stimulation. Finally, using transcriptomics data from PCa patients under ADT, we studied how androgen ablation regulates MX1 expression. SUMMARYRESULTS 1. Expression of host cell receptor genes in COVID-19 and non-COVID-19 patients 2. Expression of host antiviral effector genes in COVID-19 and non-COVID-19 patients. Gene expression analysis for host cell receptor genes: A) ACE2, B) TMPRSS2, C) BSG/CD147, D) CTSB, E) CTSL and F) ADAM17. I) COVID-19 vs. non-COVID-19 patients (P-values correspond to Wilcoxon rank sum test); II) COVID-19 and non-COVID-19 patients by sex (P-values correspond to Wilcoxon rank sum test); III) COVID-19 and non-COVID-19 patients categorized by age groups (P-values correspond to decreasing Jonckheere-Terpstrata trend test). Data was obtained from (GSE152075). Statistical significance was set at P < 0.05. Gene expression analysis for key antiviral genes: A) MX1, B) MX2, C) NRF2, D) IRF3, E) HIF1A and F) HMOX1. I) COVID-19 vs. non-COVID-19 patients (P-values correspond to Wilcoxon rank sum test), II) COVID-19 and non-COVID-19 patients by sex (P-values correspond to Wilcoxon rank sum test), and III) COVID-19 and non-COVID-19 patients categorized by age groups (P-values correspond to decreasing Jonckheere-Terpstrata trend test). Data was obtained from (GSE152075). Statistical significance was set at P ...
Cancer is a risk factor for SARS-CoV-2 infection. Recent reports have shown that prostate cancer (PCa) patients undergoing androgen-deprivation therapies (ADT) were partially protected from COVID-19. The human myxovirus resistance gene 1 (MX1) is expressed in many tissues, including prostate, and we have previously demonstrated its antitumoral activity in PCa. This protein participates in the antiviral response and it is an IFN-stimulated gene (ISGs), especially during influenza virus infection. There are ongoing clinical trials for COVID-19 prevention and/or treatment using type I or III interferons. However, IFN administration could enhance a "cytokine-storm" causing a hyper-inflammatory response and contributing to organ failure. In this work, we performed bioinformatics analyses in a case-control study from SARS-CoV-2 positive (n=403) and negative (n=50) patients. We analyzed the response to infection assessing gene expression profiles in nasopharyngeal swabs of key host cell receptors (ACE2, TMPRSS2, BSG/CD147, CTSB, CTSL, ADAM17) and antiviral proteins (MX1, MX2, NRF2, IRF3, HIF1A, HMOX1).SARS-CoV-2 positive cases had higher ACE2, but lower TMPRSS2, BSG/CD147 and CTSB expression. Patient age negatively affected ACE2 expression. MX1 and MX2 were higher in SARS-CoV-2 positive individuals, and negative trends were observed as patients' age increased. Principal Component Analysis determined that ACE2, MX1, MX2 and BSG/CD147 expressions were able to cluster non-COVID-19 and COVID-19 individuals. Multivariable regression showed that MX1 expression significantly increased for each unit of viral load increment.Given that MX1 was differentially expressed between COVID-19 and non-COVID-19 patients, we evaluated MX1 expression in A549 and Calu3 lung cell lines. MX1 was significantly up-regulated upon infection with SARS-CoV-2.Since ADT reduces SARS-CoV-2 infection incidence, we aim to study MX1 regulation by dihydrotestosterone (DHT). We browsed publicly available ChIP-seq experiments evaluating androgen receptor (AR) binding sites in different PCa cell lines under DHT stimulation. Results indicated enriched AR binding sites on the MX1 sequence. Therefore, we treated LNCaP cells with DHT, observing a significant decrease in MX1 mRNA levels. Accordingly, we observed a significant increase of MX1 gene expression in PCa patients after ADT treatment.In summary, our study findings support differences in ACE2, MX1, MX2 and BSG/CD147 expression between COVID-19 and non-COVID-19 patients; and point out to MX1 as a critical responder in SARS-CoV-2 infection. Furthermore, we demonstrated MX1 modulation by ADT. Taking into consideration the fact that PCa patients that underwent ADT were less prone to present the infection, we propose this gene as an alternative druggable target for COVID-19 patients, especially those with PCa as a previous condition. Citation Format: Juan Antonio Bizzotto, Pablo Sanchis, Sofia Lage-Vickers, Rosario Lavignolle, Agustina Sabater, Mercedes Abbate, Ayelen Toro, Florencia Cascardo, Santiago Olszevicki, Nicolas Anselmino, Estefania Labanca, Emiliano Ortiz, Elba Vazquez, Javier Cotignola, Geraldine Gueron. Androgen-deprivation therapy boosts MX1 expression, a silent effector against COVID-19 [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 710.
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