Regulation of prostate cancer immunity-related genes in PC3 prostate cancer cells by ETS-1
- Authors:
- Published online on: December 2, 2011 https://doi.org/10.3892/ol.2011.509
- Pages: 513-516
Abstract
Introduction
Prostate cancer (PCa) is one of the most prevalent forms of cancer affecting males, and a leading cause of cancer mortality (1). The involvement of the immune response in tumor progression and disease outcome remains a matter of debate (2) and, in particular, knowledge of the immune defenses involved in PCa is still lacking. The association between the immune system of the body and tumor behavior has been reported (2), along with indications that the immune system may promote and inhibit tumor growth (2). For instance, the majority of pro-inflammatory cytokines generated by immune cells of the host or tumor cells promote tumor development, while pro-apoptotic and anti-inflammatory cytokines mostly interfere with tumor development (3).
In PCa, reduced infiltration of tumor-associated macrophages and absent or weak tumor infiltrating lymphocytes have been reported to be associated with tumor progression (4,5). The majority of patients with PCa are immunocompetent, even though the host immunity is altered owing to tumor avoidance mechanisms (6). However, the lack of action of the immune defenses against the tumor may indicate an immunological tolerance (6). Moreover, a combination of Th1-adaptive immunity and inflammation genes has recently been suggested to confer improved prognosis of PCa (2).
Since the identification of immunity-related genes may have large implications for the understanding of PCa immunology, we recently reported the identification of immunity-related genes (B-cell, innate and T-cell immunity) in PCa, and reported on their potential regulation by members of the ETS family of transcription factors (7). Of note, our analysis of the promoter regions of the identified immunity-related genes revealed that 31 out of the 37 genes have potential binding sites for the ETS family prototype, ETS-1 (7). In the majority of PCa cases, recurrent gene fusions involving members of the ETS family have frequently been reported (8), along with reports suggesting that members of the family are essential for the regulation of the immune system and immunity-related genes (9).
ETS-1, the prototype of the ETS family, has been reported to be overexpressed in latent and clinically manifest PCa, and poor tumor differentiation has been associated with strong ETS-1 expression (10). Moreover, we have, in previous studies, reported that ETS-1 promotes proliferation, migration and/or invasion of various neoplastic cells, including melanoma, HeLa, glioma and PC3 prostate cells, and plays a role in the regulation of genes involved in the metastatic cascade (11–15).
As a continuation of our recent study, in which we identified immunity-related genes in PCa and reported on their potential regulation by ETS-1 (7), we investigated whether ETS-1 regulates these immunity-related genes in PC3 PCa cells.
Therefore, we specifically blocked ETS-1 in PC3 PCa cells and assessed the effect of the blockade on the expression of the recently identified PCa immunity-related genes using a comprehensive oligo gene expression microarray analysis. Results showed that 8 of the recently identified PCa immunity-related genes are regulated by ETS-1 in PC3 PCa cells. These findings provide insights into the regulation of immunity-related genes in PCa and emphasize the importance of ETS-1 in PCa immunology.
Materials and methods
Cell culture
The PCa cell line PC3 cells were grown in F12K media with L-glutamine (Invitrogen, Carlsbad, CA, USA) supplemented with penicillin, streptomycin (Invitrogen) and 10% heat-inactivated fetal calf serum (Invitrogen). In addition, 4.3 mg/ml of G418 (PAA Laboratories GmbH, Pasching, Austria) was added to the media along with the transfected cells.
Blockade of ETS-1 in the PC3 PCa cell line
Using the calcium phosphate method as described previously (16), the plasmids pcDNA3.1h-ets-1 inverse and pcDNA3.1 (−) (mock control) were transfected into the PC3 cells. After 24 h, selection was initiated with 4.3 mg/ml of G418 (PAA Laboratories GmbH). Cells were lysed by freezing and thawing at room temperature, and a total of 20 μg of protein was analysed on 10% sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis, and transferred onto nitrocellulose filters (Bio-Rad, Hercules, CA, USA). The nitrocellulose filters were then blocked with 5% dry milk in TBST (50 mM Tris, 150 mM NaCl, 0.1% Tween-20, pH 7.5), incubated in TBST with anti-Ets-1 mouse monoclonal antibodies (1:5000; Transduction Laboratories), and finally with anti-mouse IgG horse radish peroxidase-conjugated secondary antibody (1:5000; Amersham Biosciences, Piscataway, NJ, USA). For internal control, the housekeeping protein β-actin was evaluated using the mouse monoclonal anti-β-actin antibody (1:5000; Sigma, St Louis, MO, USA). The antibodies were then detected using enhanced chemiluminescent (ECL) reagents (Amersham Biosciences).
Whole human genome oligo microarray analysis of RNA isolated from PC3 cells with ETS-1 blockade and mock control
Using the RNeasy Mini kit (Qiagen, Hilden, Germany), RNA was isolated from PC3 cells with ETS-1 blockade and mock control according to the manufacturer’s instructions. The recommended DNase digestion was performed with the RNase-Free DNase set (Qiagen). The amount of RNA was then measured using the ND1000 Nanodrop (Thermo Fisher Scientific, Waltham, MA, USA). The RNA was then sent to Miltenyi Biotech (Bergisch Gladbach, Germany), for whole human genome oligo microarray analysis and bioinformatical interpretation. The RNA was labeled with Cy3 and hybridized on the Whole Human Genome Oligo Microarray 4×44K (Agilent, Santa Clara, CA, USA) according to the manufacturer’s instructions. The results of the entire microarrays were validated by examining the expression of a subset of genes using quantitative reverse transcriptase-polymerase chain reaction (qRT-PCR) analysis.
Results
ETS-1 blockade in PC3 PCa cells
Western blot analysis of cell lysates prepared from two stable PC3 cell cultures that were established by transfection with an ETS-1 inverse antisense expression vector or a mock control vector revealed the absence of ETS-1 in the inverse-transfected cells compared to the presence of ETS-1 in the mock control transfected cells over a period of 121 days (14).
Gene expression analysis of previously reported PCa immunity-related genes in PC3 cells with ETS-1 blockade compared to mock control
We have recently reported the identification of 37 immunity-related genes (B cell, innate and T-cell immunity) in PCa tissues, and found binding sites for ETS-1 within the promoter regions of 31 out of 37 of these genes (7). Therefore, the recently identified immunity-related genes were verified for their presence in the results of the gene expression microarray analysis of PC3 cells with ETS-1 blockade compared to mock control. Only genes with an expression of >2-fold increase or decrease and a p-value <0.01 between PC3 cells with ETS-1 blockade compared to mock control were considered to indicate a statistically significant difference (Tables I and II).
The recently reported immunity-related genes that were found to be upregulated >2-fold in ETS-1 blockade compared to the mock control are CD38 and HDAC9 (Table I). Conversely, the genes that were found to be downregulated are BCL11A, CRISP3, DMBT1, FGR, NOS2 and SAA1 (Table II).
Discussion
As knowledge of the immune defenses in PCa remains incomplete, we recently reported the identification of immunity-related genes in PCa, and suggested (based on bioinformatical analysis) that the genes are potentially regulated by members of the ETS family of transcription factors (7), which are known to be involved in translocations frequently found in PCa (8), and are reported to be essential for the regulation of immunity-related genes (9). More specifically, our analysis revealed that 31 out of the 37 immunity-related genes that we have identified have potential binding sites for the ETS family prototype, ETS-1 (7).
As a continuation of our recent study, in which we identified immunity-related genes in PCa (7), we investigated whether ETS-1 regulates these PCa immunity-related genes in PC3 cells. We specifically blocked ETS-1 in PC3 PCa cells (14) and assessed the effect of the blockade on the expression of the recently identified PCa immunity-related genes (7) using a comprehensive oligo gene expression microarray analysis.
Our results reveal that out of the 31 PCa immunity-related genes with potential ETS-1 binding sites within their promoter regions, the expression of 8 genes was found to be significantly up- or downregulated in PC3 cells with ETS-1 blockade compared to mock control (Tables I and II).
The PCa immunity related-genes CD38 and HDAC9 were found to be upregulated more than 2-fold in PC3 cells with ETS-1 blockade compared to the mock control (Table I), whereas BCL11A, CRISP3, DMBT1, FGR, NOS2 and SAA1 were found to be downregulated (Table II).
The significant up- or downregulation of these 8 genes in PC3 cells with ETS-1 blockade compared to mock control cells indicate that ETS-1 regulates these immunity-related genes directly or indirectly. These results suggest that ETS-1 represses the expression of the immunity-related genes CD38 and HDAC9, while activating the expression of BCL11A, CRISP3, DMBT1, FGR, NOS2 and SAA1 in PC3 PCa cells. Besides the roles of these genes in the immune response, several have been reported to be involved in various types of cancer, including PCa (17–28). However, the precise roles that these genes may play in the network of cellular and molecular mechanisms of antitumor immunology according to current models is not always clear from the literature. Briefly, decreased levels of CD38 have been reported in prostate adenocarcinoma cells (17). A high HDAC9 expression has been found in primary medulloblastoma samples and reported to be significantly associated with poor survival (18). In addition, a high expression of HDAC9 has also been found to be associated with poor prognosis in childhood acute lymphoblastic leukemia (19). BCL11A has been reported to be involved in lymphoid malignancies (20). CRISP3 is stated to be overexpressed in PCa (21) and suggested to be an independent predictor of recurrence following radical prostatectomy for localized PCa (22). DMBT1 has been reported to be involved in the carcinogenesis of the malignant brain tumors medulloblastoma and glibolastoma multiforme (23), and the DMBT1 gene has also been stated to be highly unstable in cancer, and to be involved in the immune defense (24). FGR has been suggested to play a significant role in ovarian carcinoma cancer growth (25). NOS2 has been reported to be implicated and correlated with various prostatic diseases including PCa (26). Finally, SAA1 has been found to be highly expressed in lung cancer tissue (27) and over-expressed in ovarian carcinoma tissues (28).
In correlating our results from the PC3 cells with the recent findings from the PCa tissues (7), we found that the PCa immunity related genes CRISP3 and FGR, which were reported to be upregulated in PCa glands compared to normal glands (7), are downregulated in PC3 cells with ETS-1 blockade compared to the mock control (Table II). Conversely, CD38, which was reported to be downregulated in prostate carcinoma glands compared to normal glands (7), is found to be upregulated in PC3 cells with ETS-1 blockade compared to the mock control (Table I). These observations suggest that ETS-1 may be involved in the activation of the immunity-related genes CRISP3 and FGR, and the repression of CD38 in PCa.
Of note, correlating results from PCa cell lines such as PC3 cells, with the findings from primary PCa tissues should be interpreted with caution. A major issue is that the three most commonly used cell culture models of PCa, DU145, PC3 and LNCaP, are metastatic cell lines derived from brain, advanced androgen-independent bone and supraclavicular lymph node metastasis, respectively. Although these cell lines are useful cell culture models for PCa, the fact that they were derived from metastatic sites, rather than primary PCa tumors, makes correlating findings from PCa cell lines with primary PCa tumor tissues a challenge, as gene changes may occur during tumor progression. Therefore, primary PCa cell lines would be the optimal choice; however, such cell lines are difficult to culture and maintain for a long period of time.
We report that 8 of the recently identified PCa immunity-related genes are regulated by ETS-1 in PC3 PCa cells. These findings provide insights into the regulation of immunity-related genes in PCa, and emphasize the importance of ETS-1 in PCa immunology.
In conclusion, this study investigated the regulation of immunity-related genes, recently identified from PCa tissues in the in vitro PCa cell line model, PC3 cells. Our results have shown that ETS-1 is involved in the activation and repression of immunity-related genes in PCa. To determine the precise molecular mechanisms of ETS-1 regulation of these genes requires further investigation, including DNA binding and co-transfection assays. However, these findings provide further insight into the molecular aspects of PCa immunology, and emphasize the importance of ETS-1 in PCa immunology.
Acknowledgements
We are grateful to the Deutsche Forschungsgemeinschaft (DFG); German Research Association, grant no. WE 1104/11-1) and the Deutsche Krebshilfe (German Cancer Aid, grant no. 107827) for financial support.
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