miR-205 enhances radiation sensitivity of prostate cancer cells by impairing DNA damage repair through PKCε and ZEB1 inhibition
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Radiotherapy is one of the main treatment options for non-metastatic prostate cancer (PCa). Although treatment technical optimization has greatly improved local tumor control, a considerable fraction of patients still experience relapse due to the development of resistance. Radioresistance is a complex and still poorly understood phenomenon involving the deregulation of a variety of signaling pathways as a consequence of several genetic and epigenetic abnormalities. In this context, cumulative evidence supports a functional role of microRNAs in affecting radioresistance, suggesting the modulation of their expression as a novel radiosensitizing approach. Here, we investigated for the first time the ability of miR-205 to enhance the radiation response of PCa models.
miR-205 reconstitution by a miRNA mimic in PCa cell lines (DU145 and PC-3) was used to elucidate miR-205 biological role. Radiation response in miRNA-reconstituted and control cells was assessed by clonogenic assay, immunofluorescence-based detection of nuclear γ-H2AX foci and comet assay. RNAi was used to silence the miRNA targets PKCε or ZEB1. In addition, target-protection experiments were carried out using a custom oligonucleotide designed to physically disrupt the pairing between the miR-205 and PKCε. For in vivo experiments, xenografts generated in SCID mice by implanting DU145 cells stably expressing miR-205 were exposed to 5-Gy single dose irradiation using an image-guided animal micro-irradiator.
miR-205 reconstitution was able to significantly enhance the radiation response of prostate cancer cell lines and xenografts through the impairment of radiation-induced DNA damage repair, as a consequence of PKCε and ZEB1 inhibition. Indeed, phenocopy experiments based on knock-down of either PKCε or ZEB1 reproduced miR-205 radiosensitizing effect, hence confirming a functional role of both targets in the process. At the molecular level, miR-205-induced suppression of PKCε counteracted radioresistance through the impairment of EGFR nuclear translocation and the consequent DNA-PK activation. Consistently, disruption of miR-205-PKCε 3’UTR pairing almost completely abrogated the radiosensitizing effect.
Our results uncovered the molecular and cellular mechanisms underlying the radiosensitizing effect of miR-205. These findings support the clinical interest in developing a novel therapeutic approach based on miR-205 reconstitution to increase PCa response to radiotherapy.
KeywordsProstate Cancer miR-205 Radiosensitivity PKCε
Epidermal growth factor receptor
Non homologous end joining
Protein kinase C epsilon
Quantitative real-time polymerase chain reaction
Severe combined immunodeficiency
Small interfering RNA
Zinc finger E-box binding homeobox 1
Radiotherapy is one of the main treatment options for non-metastatic prostate cancer (PCa) . Although treatment technical optimization has greatly improved local tumor control, a considerable fraction of patients still experience relapse due to development of resistance . Radioresistance is a complex and still poorly understood phenomenon involving the deregulation of a variety of signaling pathways as a consequence of several genetic and epigenetic abnormalities . In this context, mounting evidence supports the ability of microRNAs (miRNAs) to interfere with different radioresistance-associated pathways, such as DNA-repair , epithelial-to-mesenchymal transition [5, 6, 7, 8], and stemness . miRNAs are endogenous small non-coding RNA molecules that negatively regulate gene expression . The notion that miRNAs are heavily deregulated in PCa, together with the ability of a single miRNA to act as negative regulator of several genes and consequently modulate multiple cellular processes, has lead to increasing interest in defining a functional association between miRNA expression and radiation response .
Thus far, most studies assessing the involvement of specific miRNAs in radiosensitivity/radioresistance profile of PCa were limited to in vitro cell lines and generated controversial results . A few in vivo studies on human PCa xenografts identified miRNAs promoting radioresistance, such as miR-620, which regulates prostaglandin E2 levels through direct targeting of hydroxyprostaglandin dehydrogenase 15 , and miR-95, which targets the sphingolipid phosphatase SGPP1 . In the other hand, miR-145 and miR-890 were shown to increase radiation sensitivity of human PCa xenografts through down-regulation of multiple DNA repair genes [14, 15]. More recently, we demonstrated that miR-875-5p significantly enhances the radiation response of both in vitro and in vivo PCa experimental models by concomitantly counteracting epithelial-to-mesenchymal transition (EMT) and impairing DNA damage repair through the suppression of the EGFR-ZEB1 axis .
Here, we investigated the ability of miR-205 to radiosensitize human PCa preclinical models. A lower miR-205 expression was consistently found in PCa compared with matched normal prostate tissues in different studies [17, 18, 19]. In addition, we previously demonstrated that miR-205 is essential for maintenance of the basal membrane in prostate epithelium , and that it blocks tumor-driven activation of surrounding fibroblasts by reducing secretion of the pro-inflammatory cytokine IL-6 , overall supporting a miRNA oncosuppressive function in PCa. The possible relevance of miR-205 for PCa radiation response is based on our previous observation that its reconstitution in PCa cells counteracts EMT  and increases the antitumor activity of the DNA damaging agent cisplatin in vitro and in vivo, as a consequence of autophagy impairment , as well as on the reported evidence that PKCε, a direct miR-205 target , plays a role in the nuclear translocation of EGFR, which is lost upon PKCε knockdown thus impairing DNA-double strand break (DSB) repair . Consistently, results from this study indicate that miR-205 reconstitution increases the radiation response of human PCa in vitro and in vivo models through the repression of the PKCε-EGFR-DNA-PK axis.
Materials and methods
The human DU145 and PC-3 PCa cell lines were purchased from the American Type Culture Collection (ATCC, Manassas, VA, USA) and maintained in RPMI-1640 medium supplemented with 10% fetal bovine serum (FBS). Cell lines were authenticated and periodically monitored by genetic profiling using short tandem repeat analysis (AmpFISTR Identifiler PCR amplification kit, Thermo Fisher Scientific Inc., Waltham, MA, USA).
Cells seeded at the appropriate density were transfected for 4 h with 20 nM mirVana miRNA mimic and negative control molecules (Thermo Fisher Scientific Inc) or with 20 nM siRNA molecules using Lipofectamine 2000 (Thermo Fisher Scientific Inc), according to the manufacturer’s instructions. In miR-Mask experiments, 20 nM PKCε-miScript Target Protector (Qiagen, Hilden, Germany) was transfected alone or in combination with miR-205 mimic. SiRNAs targeting PKCε, ZEB1, LAMP3 and RAB27A were designed using siMAX Design Software and synthesized by Eurofin MWG Operon (Ebersberg, Germany). A control siRNA with no homology to any known human mRNA was also used. Hereafter, miR-205 synthetic mimic will be referred to as miR-205, negative mock control oligomer as Neg, PKCε-miScript Target Protector as miR-Mask, PKCε siRNA as siPKCε, ZEB1 siRNA as siZEB1, LAMP3 siRNA as siLAMP3, RAB27A siRNA as siRAB27A and control siRNA as siCTRL. DU145 clones stably expressing miR-205 were previously established as described in  and will be referred to as Vec miR-205 and cell stably transfected with negative control as Vec Neg.
Transfected cells were exposed to increasing doses (2–8 Gy) of irradiation delivered as a single dose using the 137Cs γ-irradiator IBL-437 (dose rate 5.2 Gy/min). Cells were then seeded at increasing density (500–8000 cells/well), in triplicate, in 6-well plates in RPMI medium containing 10% FBS. After 10 and 14 days, DU145 and PC-3 colonies, respectively, were fixed with 70% ethanol, stained with crystal violet in 70% ethanol, and counted. The plating efficiency was calculated as the ratio of the number of colonies (consisting of at least 50 cells) to the number of seeded cells. The surviving fraction was calculated as the ratio of the plating efficiency of the irradiated cells to that of the non-irradiated ones. Triplicate wells were set up for each condition.
In vivo experiments
All animal experiments were approved by the Ethics Committee for Animal Experimentation of Fondazione IRCCS Istituto Nazionale dei Tumori. Ten million DU145 cells (Vec Neg and Vec miR-205 clones) were injected into the right flank of eight-week-old male SCID mice, and when tumors reached ~ 100 mm3 (Width2 x Length/2), mice were randomly assigned to control or radiation treatment groups (n = 8). Mice received 5 Gy single dose irradiation using a micro-CT/microirradiator (225Cx, Precision X-ray).
miRNA and gene expression analysis
Quantification of miR-205 and mRNA expression levels was assessed by qRT-PCR using the following TaqMan microRNA or gene expression assays (Thermo Fisher Scientific Inc): miR-205,000,509; PKCε Hs00942886_m1 and ZEB1 Hs00232783_m1. Amplifications were run on the 7900HT Fast Real-Time PCR System. Data were analyzed by SDS 2.2.2 software (Thermo Fisher Scientific Inc) and reported as relative quantity with respect to a calibrator sample using the 2-∆∆Ct method. RNU48 (PN4427975) and GAPDH (PN4326317E) were used as endogenous controls.
For immunoblotting, 20 μg of cell lysates was fractioned by SDS-PAGE and transferred onto nitrocellulose membranes using standard protocols. Equal protein loading was verified by Ponceau staining. Filters were blocked in PBS-Tween-20/0.5% skim milk and probed overnight with specific antibodies for PKCε (ab63638 and ab124806, Abcam, Cambridge, United Kingdom), EGFR (sc-03, Santa Cruz), pEGFR-T654 (ab78283, Abcam), ZEB1 (sc-10,572, Santa Cruz), DNA-PK (MS 423-PO, Thermo Fisher Scientific Inc), DNA-PK-T2609 (ab174576, Abcam). β-actin (a2066, Sigma-Aldrich, St. Louis, MO) or Vinculin (V9131, Sigma-Aldrich) and HDAC (877–616-cell, Cell Signaling) were used as equal protein loading controls. For phospho-DNA-PK evaluation, 48 h after transfection, cells were harvested at 30 and 60 min for subcellular protein fractionation by Subcellular Protein Fractionation Kit (Thermo Fisher Scientific). The filters were then incubated with the secondary peroxidase linked whole antibodies. Bound antibody was detected using the Novex ECL, HRP Chemiluminescent substrate Reagent Kit (Thermo Fisher Scientific Inc). For the preparation of figures, we cropped the original western blots to generate the figure panels with the relevant lanes. Cropped images were then subjected to uniform image enhancement of contrast and brightness. Molecular weights were determined using the colorimetric Precision Plus Protein Standard (Bio-Rad) and standard protein bands were removed from the chemiluminescent blot image.
Cells grown on glass coverslips were fixed with 4% formaldehyde and permeabilized with cold methanol/acetone solution. Cells were probed with FITC-labeled phalloidin (P5282; Sigma- Aldrich) or with primary antibody for phospho-Histone H2AX (ab11174, Abcam) and subsequently with Alexa Fluor488-labeled or Alexa Fluor594-labeled (Thermo Fisher Scientific Inc) secondary antibodies for 1 h at room temperature. Nuclei were counterstained with DAPI (Thermo Fisher Scientific Inc). Images were acquired by Nikon Eclipse E600 microscope using ACT-1 software (Nikon) and processed with ImageJ.
The alkaline Comet assay (Trevigen Inc., Bologna, Italy) was performed on transfected cells 4 h from irradiation (4 Gy), according to the manufacturer’s instructions. Cells were suspended in low melting agarose and layered on microscope slides. Cells were then lysed to release the DNA. Electrophoresis was carried out under alkaline conditions. After electrophoresis for 10 min at 1 V/cm, slides were washed in water and dehydrated with ethanol, air-dried and then DNA was stained with SYBR Green. Comets were imaged using a fluorescence microscope equipped with a video camera (Jai Pulnix, Sunnyvale, CA), and quantitative assessment of DNA damage was obtained using the Comet Assay IV software (Perceptive Instruments, Suffolk, UK). Tail moments were determined by counting at least 200 comets/condition.
Data are shown as mean values ± SD from at least three independent experiments. Statistical analysis was performed by two-tailed Student’s t test. P-values < 0.05 were considered statistically significant.
miR-205 enhances PCa cell sensitivity to radiation
Notably, the radiosensitizing effect was maintained in a polyclonal population of DU-145 cells stably transfected with a vector containing the hairpin precursor sequence of miR-205 , where the persistent miRNA overexpression, although to a lower extent compared to transiently reconstituted DU145 cells (Fig. 1b, left panel), was sufficient to induce a significant enhancement of radiation response (Fig. 1b, right panel). Again, miR-205 stable reconstitution did not affect the clonogenic potential of DU145 cells (plating efficiencies, 0.13 and 0.15 in miRNA-205- and negative control-transfected cells, respectively).
These results suggest that miR-205 is endowed with a radiosensitizing potential in PCa cell models.
miR-205 impairs cell repair of radiation-induced DNA damage
These findings support the hypothesis that miR-205 impairs the ability of PCa cells to repair radiation-induced DNA damage.
miR-205 enhances in vivo response to radiotherapy in PCa xenografts
No differences were appreciable in the tumor take rate of miR-205 and control xenografts (which was 100% in all experimental groups), although the growth of non-irradiated xenograft tumors originated from miR-205-reconstituted DU145 cells was delayed compared to those arising from control cells (Fig. 3b and c). Since a comparable proliferation rate (in terms of plating efficiency in the clonogenic assay) was observed in vitro for both cell lines, such a growth delay was likely due to limited local invasive capabilities of miR-205 expressing cells, consistent with our previous finding indicating the ability of the miRNA to counteract EMT and impair migration and invasive properties in DU145 cells following transfection with a miR-205 synthetic precursor .
Interestingly, miR-205 enhanced the effect of radiation also in vivo, as indicated by a statistically significant reduction in tumour growth upon irradiation compared to controls (Fig. 3b) and, especially, by the significantly increased time for DU145 xenografts to reach 1000 mm3 tumour burden with respect to controls (Fig. 3c).
Repression of the PKCε-EGFR-DNA-PK axis as main determinant of miR-205-mediated radiosensitization
To dissect the molecular determinants underlying miR-205-induced radiosensitizing effect in PCa cells, we explored the possible role of miRNA target genes relevant to radiation response. Target choice was based on previous findings indicating that PKCε plays a central role in radiation response of A549 lung carcinoma cells by inducing nuclear translocation of EGFR and activation of DNA-PK , together with the evidence that miR-205 increased radiation response of breast cancer models through ZEB1 suppression and consequent inhibition of homologous recombination (HR) repair of DNA-DSBs .
While miR-205-induced inhibition of ZEB1 and of the ubiquitin-conjugating enzyme Ubc13, and the consequent decrease in the ability to repair DNA damage by the homologous recombination (HR) pathway, has been exhaustively documented as a main responsible for the miRNA radiosensitizing effect in breast cancer cells , the role of PKCε in miR-205-mediated increased radiation response of tumour cells has never been investigated.
PKCε has been reported to be up-regulated upon radiation exposure in A549 lung carcinoma cells  and to stimulate radiation-induced damage repair through EGFR phosphorylation and nuclear accumulation, which in turn phosphorylates and activates DNA-PK thus triggering non-homologous end joining (NHEJ) pathway . Consistently, we found that at 30 and 60 min following exposure to 4 Gy irradiation, DU145 control cells displayed enhanced levels of PKCε, pEGFR (T654) and nuclear pDNA-PK (T2609), which were not appreciable in miR-205-reconstituted cells (Fig. 5c).
Overall, our findings suggest that miR-205 exerts its radiosensitizing effect mainly by impairing DNA repair pathways through the inhibition of ZEB1 and the suppression of PKCε-EGFR-DNA-PK axis, respectively, ultimately resulting in a decrease removal of radiation-induced DNA lesions and consequent enhancement of PCa cell susceptibility to radiation. Moreover, miR-205-induced impairment of the autophagy flux, mainly through LAMP3 downregulation, could represent an additional mechanism by which the miRNA exerts its radiosensitizing effect.
Results obtained in experimental models have demonstrated a direct involvement of selected miRNAs in controlling tumor radiation response, thus revealing an entirely new mechanism of radioresistance but also envisaging a possible novel approach of radiosensitization based on the modulation of specific miRNAs .
In this study, we showed that reconstitution of miR-205, the expression of which is down-regulated in primary and, even more, in metastatic PCa lesions [17, 18, 19], was able to enhance radiation response in both in vitro and in vivo PCa models. miR-205 is known to exert oncosuppressive functions in PCa [17, 20, 21, 22], some of which are relevant to radiation-response. Specifically, miR-205 was found to counteract EMT in PCa cells through the suppression of PKCε . EMT was reported to be related to radioresistance in many cancers [5, 6, 7, 8]. In this context, we and others already showed the relevance of some EMT-related miRNAs, including miR-200c , miR-203 , miR-204  and miR-875-5p  in determining the radiation response of experimental tumor models.
Since it is well known that radiosensitivity depends in part on tumor cell kinetics, being G2-M the most radiosensitive phase of the cell cycle , the recently established role for PKCε in the control of mitotic spindle organization in transformed cell models  could also contribute to the miR-205-mediated radiosensitizing effect. Most importantly, PKCε also plays a role in the nuclear translocation of EGFR, a main mechanism of tumor radioresistance . Specifically, it has been shown that radiation-induced nuclear EGFR presented PKCε-mediated increased phosphorylation at T654 . EGFR contributes to radiation resistance, at least in part, by interacting with the catalytic subunit of DNA-PK and increasing the enzyme activity through stabilization of the phosphorylated forms of the protein at specific serine (S2056) and threonine (T2609) residues, which are essential for DNA double-strand break repair by NHEJ pathway . Indeed, we found that siRNA-mediated PKCε down-regulation was able to phenocopy the radiosensitizing effect induced by miR-205 and to reduce the accumulation of phosphoEGFR and phosphoDNA-PK. Consistently, the inhibition of miR-205-PKCε interaction through the use of a miRNA mask almost completely abolished the radiosensitizing effect of the miRNA as a consequence of the complete recovery of PKCε expression.
miR-205 reconstitution in experimental models of human breast cancer, another tumor type characterized by a reduced expression of the miRNA , was found to improve the radiation response by directly targeting ZEB1 and the ubiquitin-conjugating enzyme Ubc13, thus inhibiting HR-mediated repair of DNA-DSBs . Consistently, in this study we found a significant inhibition of ZEB1 expression, at both mRNA and protein level, following miR-205 reconstitution in PCa cell lines. In addition, siRNA-mediated ZEB1 silencing was able to recapitulate miR-205 radiosensitizing effect, thus confirming a functional role of ZEB1 in determining the radiation response also in PCa cells.
In addition, consistent with the previously reported ability of miR-205 to enhance the response of PCa to cisplatin treatment through autophagy impairment , results of this study suggest a possible role of LAMP3 downregulation in the miRNA-mediated enhancement of PCa cell radiation response.
Although data collected in PCa and breast cancer models support the clinical interest in developing a novel miR-205-based radiosensitization approach, the evidence that involvement of specific miRNAs in the onset of radiation resistance seems to be cell/tissue specific represents a constraint for the clinical exploitation of miRNA-based therapeutic molecules. In this context, it was found that Sp1-mediated transcriptional activation of miR-205 promotes radioresistance in esophageal squamous cell carcinoma , where the miRNA was reported to exert oncogenic functions , and that miR-205 determines the radioresistance of human nasopharyngeal carcinoma by directly targeting PTEN , thus envisaging a possible opposite role of the miRNA in controlling radiation response as a function of tumour cell type, based on the availability of specific targets.
In conclusion, this is the first report indicating that miR-205 reconstitution enhances radiation response in prostate cancer cell and xenograft models. We also proposed that such an effect may mainly rely on DNA repair impairment as a consequence of PKCε and ZEB1 targeting, as suggested by the evidence that RNAi-mediated silencing of either gene was able to phenocopy miR-205 radiosensitizing effect. Cumulatively, our results support the clinical interest in developing a novel therapeutic approach based on miR-205 reconstitution to increase prostate cancer response to radiotherapy.
The authors thank Dr. Alessandro Cicchetti and Martina Tripari for providing their technical contribution.
The work was supported by Italian Association for Cancer Research (AIRC), Special Program “Innovative Tools for Cancer Risk Assessment and Early Diagnosis”, 5X1000, (ED12162; NZ, RV); AIRC grants (MFAG11542, PG; IG15191, NZ), and I. Monzino Foundation (NZ).
Availability of data and materials
Data sharing is not applicable to this article as no datasets were generated or analysed during the current study.
REB contributed to the acquisition of experimental data, to the analysis and interpretation of results and to the writing of the manuscript. ST, MT, VD and VZ contributed to the acquisition of experimental data. CS contributed to data analysis. TR and RV contributed to the interpretation of results. MF contributed to the interpretation of results and to the writing of the manuscript. PG contributed to the conception and design of the study, to the interpretation of data, and to the writing of the manuscript. NZ contributed to the conception and design of the study, to the analysis and interpretation of experimental data, to the writing of the manuscript and supervised the study.
All animal experiments were approved by the Ethics Committee for Animal Experimentation of Fondazione IRCCS Istituto Nazionale dei Tumori and by the Italian Health Ministry.
Consent for publication
The authors declare that they have no competing interests.
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