The following chemotherapeutic agents were used: Camptothecin (Sigma-Aldrich, St. Louis, MO, USA), etoposide (Sigma-Aldrich), bleomycin (Sigma-Aldrich) and meso-tetra (N-methyl-4-pyridyl) porphine tetra tosylate (TMPyP4; EMD Millipore, Darmstadt, Germany). All agents were dissolved in dimethyl sulfoxide (DMSO) and stored under sterile conditions at −20°C in the dark. The vehicle (DMSO) was utilized as a control with a final concentration of <0.1%, which had no influence on cell growth.

Cells obtained from American Type Culture Collection (Manassas, VA, USA) were passaged in Dulbecco's modified Eagle's medium (DMEM; GE Healthcare Life Sciences, Logan, UT, USA) supplemented with 10% cosmic calf serum (GE Healthcare Life Sciences) at 37°C in a humidified atmosphere containing 5% CO₂ for <6 months. No antibiotics were added to the medium to avoid stress.

The following primary antibodies were utilized: Polyclonal rabbit anti-OBFC1 (1:500 dilution; cat no. sc-135364; Santa Cruz Biotechnology, Inc., Dallas, TX, USA) and monoclonal mouse anti-β-actin (1:60,000 dilution; cat no. A2228; Sigma-Aldrich). The secondary antibody was horseradish peroxidase-conjugated polyclonal goat anti-mouse immunoglobulin (Ig)G (cat no. 554002; BD Biosciences, San Jose, CA, USA) or anti-rabbit IgG (cat no. PI-1000; Vector Laboratories, Inc., Burlingame, CA, USA).

STN1 small hairpin (sh)RNA sequences targeting GCUUAACCUCACAACUUAA (shStn1-2) (9) and GGACUGCCAGAAACCAAAT (shStn1-4) were cloned into pSIREN-retro-puro (Clontech Laboratories, Inc., Mountainview, CA, USA). Control shRNA targeted luciferase and the sequence was CGU ACG CGG AAU ACU UCG A (shLuc) (Thermo Fisher Scientific, Inc., Waltham, MA, USA). Infection and selection were performed as previously described (9).

MTT assay was employed to evaluate cell viability. Briefly, cells were seeded into 96-well multiplates at a density of 1×10⁴/ml. Following overnight incubation, cells in triplicate wells were treated with camptothecin, etoposide or bleomycin at the indicated concentrations (5, 50 and 500 nM) for 5 days, and subsequently incubated with 100 µl of 0.5 µg/ml MTT for an additional 4 h at 37°C. MTT was subsequently removed, and DMSO was added to dissolve the resulting formazan crystals. The light absorption was measured at 570 nm with a microplate spectrophotometer (BioTek Instruments, Inc., Winooski, VT, USA). Effects of chemicals on cell survival were assessed by half maximal inhibitory concentration (IC₅₀) values (the concentration resulting in 50% inhibition of cell growth).

H1299 shLuc, shSTN1-2 and shSTN1-4 cells, and HeLa shLuc, shSTN1-2 and shSTN1-4 cells (2 days after puromycin selection) were seeded into 6-well plates at a density of 100 cells/well and incubated overnight. On the following day, cells were treated with various concentrations (500, 50 and 5 nM) of each testing drug (camptothecin, etoposide and bleomycin) at 37°C. Identical treatments were repeated every 4 days. After 10 days of incubation, the medium was removed and cell colonies were fixed and stained with crystal violet solution (0.1% crystal violet, 1% methanol and 1% formaldehyde). Colonies with >50 cells were counted and the percentage of drug-treated colonies relative to DMSO-treated control colonies was calculated.

Soft agar assays were performed in 6-well plates. Equal volumes of 1.2% agar were mixed with 2X DMEM and 1 ml of this mixture was added into each well as the base layer. Plates were chilled at 4°C until the agar solidified. Subsequently, 1×10⁴ cells that were suspended in 1X DMEM containing a gradient concentration (5, 50, 500 nM) of drugs, and then mixed with equal volume of 0.7% agar. A total of 1 ml of the mixture was poured as the top layer. Once the growth layer congealed, cells were permitted to grow at 37°C for 10 days and total colonies were counted and normalized against untreated cells.

DNA damage levels in wild-type and STN1 knockdown cells following exposure to drugs were assessed using the comet assay. H1299 cells were treated with 1 µM of each testing agent for 6 h, while HeLa cells were treated with 3 µM of each agent for 8 h. Immediately subsequent to treatment, 10 µl cell suspension was mixed with 50 µl 0.5% low-melting agarose, spread onto a Cometslide (Trevigen, Gaithersburg, MD, USA), and pre-coated with 100 µl of 1% normal-melting agarose. Cells were lysed by immersing the slides in a freshly prepared lysis solution [2.5 M NaCl, 100 mM ethylenediaminetetraacetic acid (EDTA), 10 mM Tris, 1% Triton X-100, 10% DMSO; pH 10] at 4°C for 2 h. Following lysis, slides were washed 3 times in 1X phosphate-buffered saline and placed in a gel electrophoresis apparatus with freshly prepared electrophoresis buffer (1 mM EDTA, 300 mM NaOH; pH 13) for 25 min to allow DNA unwinding. Electrophoresis was subsequently performed at 20 V with a starting current of 300 mA for 20 min. Subsequently, slides were neutralized with 0.4 M Tris (pH 7.5) 3 times, stained with 1X SYBR Gold solution (Thermo Fisher Scientific, Inc.), and viewed under an epifluorescence microscope (Axio Imager M2; Zeiss AG, Oberkochen, Germany). Data was analyzed and presented in terms of comet occurrence (% cells containing comets) and tail extent moment (tail length × tail intensity). Comets were scored visually without using analysis software, classifying them as belonging to one of five classes according to the tail intensity. Each comet class was given a value between 0 and 4: A score of 0 indicated undamaged cells (i.e., no comet) while a score of 4 indicated maximum damage. The parameter ‘comet occurrence’ was calculated from this classification and measured in arbitrary units. The comet occurrence was calculated using the following equation: [(% of cells in class 0) × 0 + (% of cells in class 1 × 1 + (% of cells in class 2) × 2 + (% of cells in class 3) × 3 + (% of cells in class 4) × 4] / total cell number (26). Tail length and tail intensity were evaluated by OpenComet version 1.3 software (www.cometbio.org). A total of 100 cells per sample were selected from random fields and counted for comets. A single investigator analyzed all slides to minimize scoring variation.

Two-tailed Student's t-tests were performed in Microsoft Excel 97–2003 (Microsoft Inc., Redmond, WA, USA) to calculate P-values. P<0.05 was considered to indicate a statistically significant difference.

The CST complex has a significant role in telomere length control as well as in promoting efficient replication of difficult-to-replicate genomic sequences (8–10,15). Previously the present authors and others have demonstrated that suppression of CST in human cells results in increased staining of the phosphorylated form of histone H2A, member X in telomeric and non-telomeric regions in the absence of exogenous damage (8,9), suggesting that CST deficiency may lead to genome instability. However, the DNA damage level induced by CST deficiency is insufficient to elicit marked growth defects in common cancer cell lines (9,10), suggesting that cancer cells may be able to tolerate low levels of DNA damage induced by CST deficiency. We hypothesize that, in the presence of exogenous DNA damaging agents, CST deficiency may augment DNA damage levels, therefore sensitizing cancer cells to damage-inducing agents. To test this, the present study investigated the differences in the sensitivity between wild-type and STN1-deficient cells using the MTT assay. The present study focused on STN1, as a previous study indicated that STN1 is required for formation of the CST complex (27). In agreement with this, the present study also observed that CTC1 expression was reduced when STN1 was absent (data not shown). Using shRNA, the present study initially established cell lines with stable STN1 depletion (Fig. 1). Cancer cell lines from various origins, including the H1299 human non-small lung carcinoma cell line, HeLa human cervical epithelial adenocarcinoma cell line and human breast adenocarcinoma cell line MDA-MB231, were infected with retroviruses expressing two distinct STN1 shRNAs (shStn1-2 and shStn1-4). Following selection, puromycin-resistant cells were collected and immediately treated with chemotherapeutic agents that are commonly used in clinical treatment. STN1 depletion was confirmed by western blotting (Fig. 1). A total of 4 chemotherapeutic agents were used: Camptothecin (CPT), etoposide, bleomycin and TMPyP4. Among them, CPT, bleomycin and etoposide are potent DNA damage inducers (28–33). TMPyP4 is a cationic porphyrin compound that binds to and stabilizes a particular DNA secondary structure known as G-quadruplexes, which are formed by guanine residues through Hoogsteen hydrogen bonding (34). Such stabilization creates prominent barriers to DNA replication that stall replication forks, which may eventually collapse, leading to DNA damage (35,36).

Following 5 days of exposure, the growth of H1299 shStn1-2 and shStn1-4 cells was remarkably inhibited by all four agents, with IC₅₀ values two to three times lower compared with the shLuc control cells (Table I). When the HeLa and MDA-MB231 cell lines were investigated, a similar degree of chemosensitivity was observed (Tables II and III). Therefore, STN1 knockdown reduced the survival of tumor cells following exposure to various damage-inducing anti-tumor agents, independent of cell type.

To additionally investigate the effectiveness of STN1 suppression on the survival and proliferation of cancer cells, the present study evaluated whether STN1 suppression affected the abilities of cancer cells to form colonies and to grow independently of anchorage using clonogenic and soft agar assays. In both assays, the same enhanced growth inhibitory effect was observed in H1299 (Fig. 2A and B) and HeLa (Fig. 3A and B) cells with STN1 suppression following drug treatment, compared with shLuc cells. In the clonogenic assay, cells were treated with a gradient concentration of 5, 50 and 500 nM of each drug for 10 days. In the absence of drug treatment, no significant growth defects were observed in H1299 or HeLa cells with STN1 knockdown compared with the shLuc control (data not shown). Colony formation was largely inhibited by drug treatment in all cells (Figs. 2A and 3A). Notably, this inhibition was significantly escalated in STN1 knockdown H1299 cells (Fig. 2A). Under all three drug concentrations, colony numbers of drug-treated shStn1-2 and shStn1-4 H1299 cells were greatly diminished compared with the drug-treated shLuc control. The most significant changes were observed in cells treated with 500 nM of bleomycin (shStn1-2, P=0.005; shStn1-4, P=0.022) or TMPyP4 (shStn1-2, P<0.001; shStn1-4, P<0.001; Fig. 2A). In HeLa cells, the long-term synergetic effects of STN1 knockdown and drug treatment were additionally observed. The colony growth in shStn1-2 and shStn1-4 cells was reduced in all drug-treated groups, in contrast to their shLuc controls (Fig. 3A).

Anchorage-independent growth is one of the hallmarks of cancerous cell transformation (37,38). In general, there is a positive correlation between in vitro transformation and in vivo carcinogenesis (39–41). Soft agar assay is considered the most accurate and stringent in vitro assay for detection of malignant transformation of cells (37,38). The present study used soft agar assay to determine the effect of STN1 knockdown on anchorage-independent growth in H1299 and HeLa cells. Following 10 days of treatment with drugs, STN1 knockdown enhanced growth inhibition induced by all four drugs in soft agar (Figs. 2B and 3B). The results of the present study additionally support the conclusion that STN1 suppression enhanced the growth inhibitory effect of tested anticancer agents.

Given the role of CST in maintaining genome stability and countering replication stress, it was suspected that STN1 deficiency may elevate DNA damage levels caused by damage inducers, eliciting rapid growth inhibition. To investigate this hypothesis, the present study employed the widely-used comet assay to detect DNA lesions in STN1 knockdown cells. The principle of comet assay is based on the ability of denatured broken DNA fragments to migrate out of the nucleoid under the influence of an electric field, whereas undamaged DNA migrates more slowly and remains within the confines of the nucleoid when a current is applied. Evaluation of the DNA ‘comet’ tail shape and migration pattern allows for assessment of DNA damage (26,42). Comet assays were performed on H1299 and HeLa control cells and the corresponding STN1 knockdown cells following treatment with each chemotherapeutic agent. As shown in Fig. 4A, untreated H1299 cells in all three groups exhibited a normal organized of nucleus without tails, indicative of undamaged DNA. As expected, treating H1299 cells with damage-inducing agent (CPT, etoposide and bleomycin) induced comet tails in all groups (Fig. 4A). Notably, quantification of comet occurrence and tail moment revealed that an increased number of comets as well as longer tails were present in shStn1-2 and shStn1-4 cells compared with control shLuc cells (Fig. 4B and C). In CPT-treated cells, STN1 knockdown increased comet occurrence by 1.5- (shStn1-2, P=0.011) and 1.8-fold (shStn1-4, P=0.005). In etoposide-treated cells, shStn1-2 and shStn1-4 increased comet occurrence by 1.6- (P=0.002) and 2-fold (P=0.015). In bleomycin-treated cells, comet occurrence in H1299 cells expressing shStn1-2 and shStn1-4 was 2- (P=0.001) and 3-fold (P=0.001) higher compared with control cells (Fig. 4B). Similarly, STN1 knockdown also significantly increased the tail moment by 2- to 3-fold in cells treated with CPT (shStn1-2, P=0.004; shStn1-4, P=0.0004) etoposide (shStn1-2, P=0.002; shStn1-4, P=0.003;) and bleomycin (shStn1-2, P=0.0005; shStn1-4, P=0.0003; Fig. 4C).

In HeLa cells, a significant fraction of shLuc cells showed comet tails following treatment with DNA-damaging agents. However, in all drug-treated groups, shStn1-2 and shStn1-4 cells had increased numbers of comets and longer tail moments compared with shLuc controls (Fig. 5A). Among the three DNA damage inducers, etoposide gave rise to the most marked increase in terms of comet occurrence, while CPT treatment led to the largest increase in tail moments in shStn1-2 and shStn1-4 cells, in contrast to shLuc controls (Fig. 5B and C). These results suggest that STN1 knockdown cells are more susceptible to DNA damage. The results of the present study suggest that the chemosensitivity induced by STN1 suppression is at least in part due to elevated levels of DNA damage in STN1 knockdown cells.