The human ovarian cancer cell line SKOV3 was procured from the American Type Culture Collection. The 293 cells were acquired from Canada Microbix Biosystems Inc. All cell lines were cultured following the instructions provided by the suppliers in high-glucose Dulbecco's modified Eagle's medium (DMEM; Gibco; Thermo Fisher Scientific, Inc.) supplemented with 10% (v/v) fetal bovine serum (FBS; Gibco; Thermo Fisher Scientific, Inc.). The cultures were maintained at 37°C in a humidified atmosphere containing 5% CO₂.

The dual-regulated adenovirus Ad-ERCC1-siRNA-hTERT-E1A-HRE-E1B (Ad-ERCC1) and its control adenovirus Ad-negative control (NC)-siRNA-hTERT-E1A-HRE-E1B (Ad-NC) were constructed by Shanghai GeneChem Co., Ltd. Briefly, fragments of the specific siRNA of ERCC1 (ERCC1-siRNA) gene were obtained which were designed based on Genbank's ERCC1 gene sequence by gene synthesis conducted by Shanghai GeneChem Co., Ltd. The sequence of ERCC1-siRNA was 5′-ccAAGCCCTTATTCCGATCTA-3′ and the negative control sequence was 5′-TTCTCCGAACGTGTCACGT-3′. An overexpression vector was first constructed using PXC1 plasmid [PXC1 (hTERTp-E1A + HREp-E1B)], in which the human telomerase reverse transcriptase promoter (hTERT) was used to regulate the adenovirus ELA gene; the hypoxia regulatory element sequence (HRE) regulates the E1B gene. (Fig. 1A and B). ERCC1-siRNA and PXC1 were digested by BamHI and KpnI and then the products were combined by T4 DNA ligase to generate the PXC1-ERCC1-siRNA plasmid. The connected plasmids were transformed into competent cells, identified by PCR and sequenced and then extracted with a TIANprep Mini Plasmid Kit (Tiangen Biotech Co., Ltd.). The purified PXC1-ERCC1-siRNA plasmid was transfected into 293 cells with adenovirus packing plasmid (PBHGE3) using Lipofectamine^® 2000 (Invitrogen; Thermo Fisher Scientific, Inc.) as follows: 5 µg of plasmid was added gently to the DMEM, the total volume adjusted to 50 µl and incubate at room temperature for 5 min. Lipofectamine^® 2000 (Invitrogen; Thermo Fisher Scientific, Inc.; 10 µl) was mixed with 50 µl of DMEM and incubated at room temperature for 5 min. the two solutions were gently mixed without shaking and incubated at room temperature for 20 min to form a DNA/Lipofectamine^® 2000 (Invitrogen; Thermo Fisher Scientific, Inc.) transfection complex. The transfection complex was slowly added to the 293 cell mixing well and incubate at 37°C and in 5% CO₂. At 6 h after incubation, the medium containing the transfection mixture was discarded and the cells rinsed with sterile PBS and gently shaken to wash away the residual transfection mixture. Then 5 ml of DMEM containing 10% FBS was slowly added and incubation continued at 37°C and in 5% CO₂. At 10–15 days after transfection, single virus plaques appeared in 293 cells, which were collected and confirmed by PCR analysis using the forward and reverse primers. The confirmed recombinant adenovirus was designated Ad-ERCC1. Ad-ERCC1 was amplified in 293 cells and purified by ultracentrifugation on cesium chloride (CsCl) gradients (40,000 × g; 2 h; 4°C). Other viruses used were treated with the same method. EGFP gene was cloned into the viruses to determine the infectivity. Viral titer confirmation was performed by infecting 293 T cells using an End-point dilution method and was calculated by Spearman-Karber Method as follows: Viral titer=10 (x+0. 8) plaque-forming units (PFU)/ml) (x=the sum of positive rates of cytopathic effect in sequential dilution from 10⁻¹ to 10⁻¹³).

For quantitative RT-PCR, total RNA was extracted from cells of different groups (6-well plate with 80% cell density) using SuperfecTRI, Total RNA Isolation Reagent (cat. no. 3101-400; Shanghai Pufei Biotechnology Co., Ltd.). cDNA was synthesized from 400 ng of RNA with the Promega M-MLV kit according to the manufacturer's protocol (cat. no. M1705; Promega Corporation). RT-qPCR) were performed in triplicate according to the kit protocol of Bulge-Loop miRNA qRT-PCR Starter Kit (cat. no. C10211-1; Guangzhou RiboBio Co., Ltd.) using a LightCycler 480 II (Roche Diagnostics) with SYBR green PCR reagents. Experiments were replicated four times and the data are shown as fold changes. The primer sequences were: ERCC1: 5′-CTACGCCGAATATGCCATCTC-3′, 3′-GTACGGGATTGCCCCTCTG-5′; GAPDH: 5′-TGACTTCAACAGCGACACCCA-3′, 3′-CACCCTGTTGCTGTAGCCAAA-5′. The PCR program included 95°C for 30 s, 40 cycles of 95°C for 5 sec and 60°C for 30 sec. The relative amount of mRNA for target gene was determined by the 2^−ΔΔCq method (24) and presented as changes in fold in the target gene expression normalized to two endogenous reference genes (GAPDH).

The cancer cell inhibition rate was evaluated by a standard MTT assay. Briefly, SKOV3 cells were plated in 96-well plates at a density of 2×10⁴ cells/well. After incubation for 24 h, the cells were infected with of different multiplicity of infection (MOI)s of Ad-siERCC1 (0, 0.001, 0.01, 0.1, 1, 5, 10, 50, 100 and 500 for 48 or 72 h) or different concentrations of DDP (0, 2, 4, 6, 8, 10, 12, 14, 16 and 18 µmol for 24 h) or both (10 MOI Ad-siERCC1 first for 24 h, 10 µmol DDP for anther 24 h). After treatment, 20 µl (5 mg/ml) MTT solution (cat. no. JT343; Genview Corp.) was added to each well. After 4 h incubation at 37°C, the supernatant was discarded and 100 µl DMSO was loaded in every well for 2–5 min. Blank control wells were also set. The optical density (OD) of each well was measured with a Microplate Reader (cat. no. M2009PR; Tecan infinite; Tecan Group, Ltd.) at 490 nm. The cell growth inhibitory rate (I%) was calculated according to the following equation: inhibitory rate%=(OD_control-OD_sample)/(OD_control-OD_blank) × 100%, where OD_control is the absorbance of the untreated cells, OD_sample is the absorbance of the cells exposed to Ad-siERCC1, DDP or both and A_blank is the absorbance of the media. A total of three reduplicate wells were measured at each group and every experiment was performed at least 3 times.

Cells were counted in a Neubauer chamber slide using the trypan blue exclusion method. Viable cells were plated at 3×10⁵ cells/well in 6-well culture plates using growth media containing 10% FBS for 24 h. The cells were washed with DPBS and pretreated with either DDP or recombinant adenovirus in serum-free media. To control wells, only serum-free media was added. The cells were scratched perpendicular to the horizontal line with a 200 µl sterile pipette tip to create a cell-free wound area. After washing away suspended cells, fresh serum-free media was added and images were captured immediately (time 0 h) using an Olympus CX41 inverted microscope (Olympus Corporation). The cells were cultured with 37°C and 5% CO₂ and images were captured again after 24 h at the same position. The measurement of cell scratch was done by ImageJ software (version 1.47; National Institutes of Health). Within each assay the experiments were performed in triplicates. Data shown are representative of minimum three independent experiments.

A total of 3×10⁵ cells in 100 µl serum-free medium were seeded in a Transwell chamber (MilliporeSigma) with a coating of Matrigel (MilliporeSigma). The Matrigel was placed on ice and thawed overnight at 4°C in the freezer. It was applied diluted with DMEM at 1:5 to the insert cell growth surface at 150–200 µl/cm² at 37°C for 30 min. Briefly, SKOV3 cells were seeded into the upper chamber in a serum-free medium and treated with either DDP or recombinant adenovirus. A volume of 0.5 ml of medium containing 10% FBS was added to the lower chamber. After 24 h of incubation, the upper surface of the membrane was wiped off with a cotton swab. Cells that invaded the lower surface of the porous membrane were fixed with 4% formaldehyde in PBS containing 4% sucrose for 10 min at room temperature and stained with 0.1% crystal violet for 10 min at room temperature. Stained cells were counted in 20 random fields per filter, in a total of three filters (n=3). Invasion was presented as percentage of invasion=(number treated cells/number of control cells) ×100.

SKOV3 cells were transfected with Ad at an MOI of 10 for 6 h. Following DDP treatments for 24 h, cells were detached with trypsinization, washed with Dulbecco's phosphate buffered saline (DPBS) and the cells collected. For assessment of DNA contents, cells were stained with propidium iodide (PI; 50 µg/ml; cat. no. P4170; MilliporeSigma) with 0.5 mg/ml RNase (cat. no. EN0531; Thermo Fisher Scientific, Inc.) in DPBS + 0.1% Tween (pH 7.4) in the dark for 30 min and then monitored by a fluorescence-activated cell sorter (FACS) using a BD C6 PLUS (BD Biosciences). The FACS data were analyzed using NovoExpress (ACEA Biosciences, Inc.) to calculate the fraction of cells in G₁, S and G₂ phases.

Annexin V-APC staining and flow cytometry analysis were used to detect cell apoptosis. Annexin V Apoptosis Detection Kit APC (cat. no. 88-8007; eBioscience; Thermo Fisher Scientific, Inc.) was used to measure cell apoptosis according to the manufacturer's instructions. Briefly, after washing with PBS, cells were resuspended in Annexin-V binding buffer, stained with the Annexin V-APC for 15 min at room temperature in the dark and analyzed using FACSCalibur (C6 PLUS; BD Biosciences) and the apoptotic rate was calculated as the numbers of early + late apoptotic cells/total numbers of cell.

Cells were harvested and re-suspended in a RIPA buffer (Beyotime Institute of Biotechnology) containing protease inhibitor cocktail (cat. no. GK10014; GlpBio). After determining the protein concentration using an Enhanced BCA Protein Assay kit (Beyotime Institute of Biotechnology), the obtained lysates (20 µg/well) were subjected to 4–10% SDS-PAGE to separate the proteins, which were subsequently transferred to PVDF membranes (cat. no. A29562259; Cytiva). The membranes were incubated with the following primary antibodies: anti-PI3K (1:1,000; cat. no. 4257; Cell Signaling Technology, Inc.), phosphorylated (p)-Akt (Ser473; 1:1,000; cat. no. 4060; Cell Signaling Technology, Inc.), anti-AKT (1:1,000; cat. no. ab179463; Abcam), anti-caspase-3 (1:1,000; cat. no. sc-7272; Santa Cruz Biotechnology, Inc.), cleaved caspase-3 (1:1,000; cat. no. 9661S; Cell Signaling Technology, Inc.), GAPDH (1:2,000; cat. no. sc-32233; Santa Cruz Biotechnology), β-Actin (1:2,000; cat. no. sc-8432; Santa Cruz Biotechnology). After blocking for 1 h at room temperature in non-fat milk in TBST (Tris-buffered saline with 0.1% Tween-20), membranes were incubated overnight at 4°C with primary antibodies in blocking buffer. After rinses with TBST, membranes were incubated with horseradish peroxidase-conjugated secondary antibodies (goat anti-rabbit, cat. no. 7074; goat anti-mouse, cat. no. 7076; Cell Signaling Technology, Inc.) for 1.5 h at room temperature and detected using 20X LumiGLO reagent and 20X peroxide (cat. no. 7003; Cell Signaling Technology, Inc.) and film exposure. Optical densities of the bands from the original image were measured with NIH ImageJ software (version 1.47; National Institutes of Health).

All data are expressed as mean ± SEM. The statistical comparisons for two groups were made with unpaired Independent-Samples t test. Multiple comparisons were made with one-way ANOVA followed by between-group comparisons using the Bonferroni comparisons or Dunnett's T3 comparisons post hoc tests, according to whether the data were normally distributed or not, using SPSS 13.0 software (SPSS, Inc.). P<0.05 was considered to indicate a statistically significant difference.

In the present study, the recombinant adenovirus effectively infected and killed tumor cells (Fig. 1C). Subsequently, the transfection efficiency of the recombinant adenovirus on ovarian cancer cells was evaluated. Cultured SKOV3 cells were infected with the recombinant adenovirus expressing green fluorescent protein (GFP) with ERCC1-siRNA (Ad-ERCC1-siRNA, Ad-siERCC1) or the empty vector (Ad-NC-siRNA, Ad-NC) at varying MOI levels ranging from 1–10,000. It was determined that the most efficient MOI value was 10 (Fig. 2A). At MOI=10, the mRNA and protein levels of ERCC1 were validated using RT-qPCR and immunoblotting techniques, revealing a decrease in ERCC1 mRNA (~60% less than control; Independent-Samples t test; t₍₆₎=36.842; P<0.001; Fig. 2B) and protein (>3-fold less than control) (Independent-Samples t test; t₍₆₎=24.036; P<0.001; Fig. 2C) upon Ad-siERCC1 treatment.

Oncolytic viruses specifically target and replicate within tumor cells, ultimately lysing them and releasing viral progeny that can propagate among tumors, eventually leading to the destruction of all tumors and thereby inhibiting tumor cell proliferation and survival (16). Considering this, it was further assessed using MTT assay whether the recombinant adenovirus would induce inhibition of cancer cell survival following transduction. As demonstrated in Fig. 2D, the recombinant adenovirus caused a significant increase in cell mortality from MOI 5 (~47.87% for 48 h and 62.49% for 72 h) to MOI 500 [~94.03% for 48 h and 95.43% for 72 h; one-way ANOVA; 48 h: F (9,20)=362.834; P<0.001; vs. the control group, LOG (5): P<0.001; LOG (10): P<0.001; LOG (50): P<0.001; LOG (100): P<0.001; LOG (500): P<0.001; 72 h: F (9,20)=313.047; P<0.001; vs. the control group, LOG (5): P<0.001; LOG (10): P<0.001; LOG (50): P<0.001; LOG (100): P<0.001; LOG (500): P<0.001].

DDP is a widely used anticancer drug in combination regimens and it exerts its activity by inducing the formation of various types of DNA adducts, leading to the inhibition of DNA synthesis, function and transcription (25). According to our previous study (26), a systematic inhibition of SKOV3 cell survival was observed with increasing concentrations of DDP from 0–18 µM after 24 h of treatment, as determined by MTT assay (one-way ANOVA; F (9,30)=258.978; P<0.001; Fig. 3A). Markedly, the inhibitory effect had a significantly higher expression of 18.05, 24.98, 29.18, 51.73 and 59.75% for 10,12,14,16,18 µM DDP (vs. the 0 µM DDP group, 10 µM DDP: P=0.001; 12 µM DDP: P=0.001; 14 µM DDP: P=0.002; 16 µM DDP: P=0.001; 18 µM DDP: P=0.001). Therefore, this concentration was chosen for subsequent experiments. Subsequently, the inhibitory rates were compared among DDP, Ad-NC and Ad-siERCC1. The results demonstrated that the recombinant adenovirus [both Ad-NC (38.63%) and Ad-siERCC1 (40%)] exhibited greater effectiveness in inducing cell mortality vs. DDP alone (10.7%; one-way ANOVA; F (2,9)=258.978, P<0.001; vs. DDP group, Ad-NC: P<0.001; Ad-siERCC1: P<0.001, Fig. 3B).

Resistance, however, has limited the efficacy of these drugs in most ovarian cancer patients. Among the various mechanisms contributing to cisplatin (DDP) resistance, enhanced tolerance and repair of DNA damage through the NER pathway have been recognized as the most crucial resistance mechanism to platinum drugs (7,8). To further investigate whether ERCC1 silencing could enhance the cancer cell-killing effect following chemotherapy, MTT assays were performed on SKOV3 cells treated with recombinant adenovirus and DDP. As depicted in Fig. 3C, in the presence of DDP, cancer cells transduced with Ad-siERCC1 (74.19%) exhibited significantly lower cell viability compared with those transduced with Ad-NC (56.85%) six days post-transduction (Independent-Samples t test; t₍₆₎=−7.420; P<0.001). Additionally, cell cycle analysis revealed that SKOV3 cells in all groups were arrested in the G₁ phase when compared with the control group (control group: 46.60%; Ad-NC: 63.79%; Ad-siERCC1: 66.05%; DDP: 68.42%; DDP + Ad-NC: 70.56%; DDP + Ad-siERCC1: 75.12%; one-way ANOVA, G₁: F (5,12)=148.758, P<0.001; vs. the control group, Ad-NC: P<0.001; Ad-siERCC1: P<0.001; DDP: P<0.001; DDP + Ad-NC: P<0.001; DDP + Ad-siERCC1: P<0.001). However, the G₁ phase cell block was more pronounced in the Ad-siERCC1 combined with cisplatin group (vs. DDP group, DDP + Ad-siERCC1: P=0.001; vs. DDP + Ad-NC group, DDP + Ad-siERCC1: P=0.027) and the proportion of cells in the G₂/M phase was the lowest (Fig. 3D and E; one-way ANOVA, S: F (5,12)=16.442, P<0.001; vs. the control group, Ad-NC: P=0.036; Ad-siERCC1: P=0.001; DDP: P<0.001; DDP + Ad-NC: P<0.001; DDP + Ad-siERCC1: P<0.001; G₂/M: F (5,12)=3.697, P=0.029; vs. the control group, DDP + Ad-siERCC1: P<0.036).

To assess the effect of the recombinant adenoviruses on SKOV3 cell migration, a scratch wound-healing migration assay was performed. The change in scratch width reflected cell mobility. Ad-siERCC1 combined with DDP resulted in the most potent inhibition of cell migration to 54.69%. (one-way ANOVA, F (3,16)=24.970, P<0.001; vs. the control group, DDP: P=0.038; DDP + Ad-NC: P=0.024; DDP + Ad-siERCC1: P=0.001; vs. DDP group, DDP + Ad-siERCC1: P=0.034; Vs. DDP + Ad-NC group, DDP + Ad-siERCC1: P=0.035; Fig. 4A and B). In the Transwell invasion assay, it was observed that the recombinant adenovirus and DDP inhibited the migration ability of SKOV3 cells (one-way ANOVA, F (3,16)=69.035, P<0.001; vs. the control group, DDP: P=0.001; DDP + Ad-NC: P=0.001; DDP + Ad-siERCC1: P=0.001; Fig. 4C and D). Moreover, in the presence of DDP, the effect of Ad-siERCC1 was significantly superior to the DDP group (control group: 100.00%; DDP: 53.62%; DDP + Ad-NC: 56.18%; DDP + Ad-siERCC1: 29.93%; vs. DDP group, DDP + Ad-siERCC1: P=0.034; vs. DDP + Ad-NC group, DDP + Ad-siERCC1: P=0.021). These findings indicated that the recombinant adenovirus significantly enhanced the inhibitory effect on migration and invasion of ovarian cancer cells and Ad-siERCC1 can improve the chemotherapy sensitivity of DDP.

Recombinant adenovirus improves drug resistance to DDP by enhancing apoptosis through the PI3K/AKT-caspase-3 signaling pathways in ovarian cancer cells. Flow cytometry with Annexin V-APC single-dye method was used to detect cells arrested in early apoptosis. As shown in Fig. 5A and B (one-way ANOVA, F (5,18)=892.196, P<0.001), recombinant adenovirus and/or DDP induced apoptosis in SKOV3 cells. The mean fluorescence intensity was 0.61± 0.07 on control cells, 0.65±0.03 on Ad-NC cells, 1.11±0.11 on Ad-siERCC1 cells, 2.05±0.11 on DDP cells, 1.96±0.14 on DDP + Ad-NC cells and 5.68±0.21 on DDP + Ad-siERCC1 cells. (Vs. the control group, Ad-NC: P<0.001; Ad-siERCC1: P<0.001; DDP: P<0.001; DDP + Ad-NC: P<0.001; DDP + Ad-siERCC1: P<0.001) and Ad-siERCC1 significantly enhanced the apoptotic effect of DDP (>2.7-fold more than control; vs. DDP group, DDP + Ad-siERCC1: P<0.001; vs. DDP + Ad-NC group, DDP + Ad-siERCC1: P<0.001). To gain further insights into this phenomenon, immunoblotting was performed to examine the proteins involved in apoptosis. As depicted in Fig. 5C (one-way ANOVA, F (5,18)=14.040, P<0.001; vs. the control group, Ad-NC: P=0.019; Ad-siERCC1: P=0.006; DDP: P=0.002; DDP + Ad-NC: P=0.002; DDP + Ad-siERCC1: P<0.001; vs. DDP group, P=0.034; vs. DDP + Ad-NC group, P=0.037). PI3K were significantly suppressed by recombinant adenovirus and/or DDP and Ad-siERCC1 greatly enhanced the effect of DDP (DDP + Ad-siERCC1: 0.55±0.10 vs. DDP: 0.76±0.05). Recombinant adenovirus and/or DDP reduced the phosphorylation level of p-AKT. Ad-siERCC1 enhanced the effect of DDP on p-AKT [DDP + Ad-siERCC1: 0.56±0.11 vs. DDP: 0.77±0.05; one-way ANOVA, p-AKT: F (5,18)=16.062, P<0.001; vs. the control group, Ad-siERCC1: P=0.003; DDP: P=0.003; DDP + Ad-NC: P=0.001; DDP + Ad-siERCC1: P<0.001; vs. DDP group, P=0.012; vs. DDP + Ad-NC group, DDP + Ad-siERCC1: P=0.035. AKT: F (5,18)=0.107, DDP + Ad-siERCC1: P=0.989]. Concurrently, procaspase-3 levels were notably reduced after incubation with recombinant adenovirus and/or DDP (control: 1.03±0.11 vs. DDP: 0.77±0.05 vs. DDP + Ad-NC: 0.71±0.04 vs. DDP + Ad-siERCC1: 0.56±0.08), whereas the cleaved caspase-3, the activated form of procaspase-3, exhibited a substantial increase (control: 0.21±0.04 VS DDP: 0.44±0.08 vs. DDP + Ad-NC: 0.49±0.04 vs. DDP + Ad-siERCC1: 0.52±0.08; one-way ANOVA, procaspase-3: F (5,18)=36.689, P<0.001; vs. the control group, DDP: P<0.001; DDP + Ad-NC: P<0.001; DDP + Ad-siERCC1: P<0.001; vs. DDP group, P=0.003. cleaved caspase-3: F (5,18)=22.502, P<0.001; vs. the control group, DDP: P=0.001; DDP + Ad-NC: P<0.001; DDP + Ad-siERCC1: P<0.001, Fig. 5E). These results indicated that recombinant adenovirus ameliorates drug resistance to DDP by promoting apoptosis through the PI3K/AKT-caspase-3 signaling pathways in ovarian cancer cells.