SLFN family genetic information was analyzed using publicly available datasets, including the International Cancer Genome Consortium (ICGC, Nature 2012), Queensland Centre for Medical Genomics (QCMG, Nature 2016), Clinical Proteomic Tumor Analysis Consortium (CPTAC, Cell 2021), The Cancer Genome Atlas (TCGA, PanCancer Atlas), and the University of Texas Southwestern (UTSW, Nat Commun 2015). These datasets were accessed via the cBio Cancer Genomics Portal (cBioPortal, https://www.cbioportal.org/ (accessed on 1 January 2025), Memorial Sloan Kettering Cancer Center, New York, NY, USA) [30]. The expression patterns of SLFN family members were evaluated in 179 PC tissues and 171 normal pancreatic tissues using the Gene Expression Profiling Interactive Analysis (GEPIA, http://gepia.cancer-pku.cn/ (accessed on 1 January 2025), Peking University, Beijing, China) [31]. This analysis was conducted using patient data obtained from TCGA (https://www.cancer.gov/tcga (accessed on 1 January 2025)) [32] and from the Genotype-Tissue Expression (GTEx, https://gtexportal.org/home/ (accessed on 1 January 2025)) database [33–35], normal tissue samples were acquired. The TCGA dataset includes RNA sequencing data from 179 PC tissue samples collected from 178 patients, comprising 178 primary tumor samples and one metastatic sample. Gene expression levels were quantified in transcripts per million (TPM) and log-transformed using a log₂(TPM + 1) scale for comparative analysis. Expression thresholds were defined at |log₂ fold change (FC)| ≥ 1 with a significance level of p-value < 0.01. Additionally, overall survival (OS) data for PC patients were retrieved from TCGA and analyzed about the expression of SLFN family genes. SLFN11 mRNA expression profiling and drug sensitivity analyses were performed using public datasets from the CellMiner Cross-Database (https://discover.nci.nih.gov/cellminercdb/ (accessed on 1 January 2025)), including National Cancer Institute 60 (NCI-60) (60 cell lines × 237 drugs), Cancer Therapeutics Response Portal (CTRP) (860 cell lines × 481 drugs), CTRP (860 cell lines × 481 drugs), and Cancer Cell Line Encyclopedia (CCLE) (860 cell lines × 481 drugs).

The human PC cell lines AsPC-1 [CRL-1682] and BxPC-3 [CRL-1687] were cultured in RPMI1640 medium (Gibco, 11875-093, Grand Island, NY, USA). MIA PaCa-2 [CRL-1420] and PANC-1 [CRL-1469] were cultured in DMEM (Gibco, 11965-092). HPAF-II [CRL-1997] was cultured in MEM (Gibco, 11095-080). Capan-2 [HTB-80] was cultured in McCoy’s 5A medium (Gibco, 16600-082). These cell culture media contained 10% fetal bovine serum (FBS) (Gibco, 16000-044) and 1% penicillin-streptomycin (pen-strep) (Gibco, 15140-122). Capan-1 [HTB-79] was cultured in IMDM (Gibco, 12440-053) supplemented with 20% FBS and 1% pen-strep. Panc10.05 [CRL-2547] was cultured in RPMI1640 (Gibco, 11875-093) supplemented with 10 units/mL insulin (Sigma-Aldrich, I9278, St. Louis, MO, USA), 15% FBS, and 1% pen-strep. All cell lines were purchased from the American Type Culture Collection (ATCC, Manassas, VA, USA). All cells were cultured in a humidified incubator set at 37°C with 5% CO₂. Mycoplasma contamination was regularly monitored using the MycoAlert mycoplasma assay kit (Lonza, LT07-318, Basel, Switzerland), and all cell lines were confirmed to be mycoplasma-free. Normal human pancreatic ductal epithelial (HPDE) cells were obtained from Joo Kyung Park, MD (Samsung Medical Center, Seoul, Republic of Korea) and cultured in K-SFM (Gibco, 17005-042) added with 10% FBS and 1% pen-strep. For double thymidine block (DTB) experiments, cells were synchronized near the G1/S boundary using 2 mM thymidine (Sigma-Aldrich, T9250). After the second thymidine treatment, a fresh culture medium was changed, and cells were collected at each measurement time [36].

To measure cytotoxicity, the survival of PC cells was evaluated using the Cell Counting Kit-8 (CCK-8) assay (Dojindo, CK04, Fukuoka, Japan), according to the manufacturer’s protocol. PC cells were plated in 96-well dishes at a concentration of 1 × 10⁴ cells per well. After treating each well with 10 μL of CCK-8 reagent per well in 100 μL of medium, the cells were maintained at 37°C for 4 h. The negative control consisted of wells with only the culture medium and CCK-8 solution but without cells. Absorbance at 450 nm was measured with an Epoch 2 microplate spectrophotometer (BioTek, Santa Clara, CA, USA). All tests were carried out in triplicates, and the results provided are the averages from multiple biological replicates.

SLFN11 siRNA was synthesized as SLFN11_1: 5^′-CAG GGA ACC UUA CGA AUU A-3^′ and 5^′-UAA UUC GUA AGG UUC CCU G-3^′, SLFN11_2 siRNA: 5^′-GGU AUU UCC UGA AGC CGA A-3^′ and 5^′-UUC GGC UUC AGG AAA UAC C-3^′, and SLFN11_3 siRNA: 5^′-CCA GGA UAU UUG CGA UAU A-3^′ and 5^′-UAU AUC GCA AAU AUC CUG G-3^′ [27,37]. Control and SLFN11 siRNAs were obtained from Cosmo Bio Co., Ltd. (Cosmo Genetech, Seoul, Republic of Korea). Transfection of cells with control and SLFN11 siRNAs was carried out using the Lipofectamine RNAiMAX reagent (Invitrogen, 13778075, Carlsbad, CA, USA) as per the manufacturer’s protocol. WT CRISPR/Cas9 (sc-418922) and SLFN11 CRISPR/Cas9 KO (sc-401137-KO-2) plasmids were acquired from Santa Cruz Biotechnology (Dallas, TX, USA). Transfection of WT and SLFN11-KO cells was performed using Santa Cruz Biotechnology’s UltraCruz transfection reagent (sc-395739) and plasmid transfection medium (sc-108062), then subjected to puromycin selection following the manufacturer’s protocol.

Cells were collected, rinsed with 1× phosphate-buffered saline (PBS), stored in 70% ethanol at 4°C overnight, and labeled with Propidium iodide (PI, Sigma-Aldrich, St. Louis, MO, USA) at a concentration of 50 μg/mL, along with 100 U RNase (Ribonuclease A from bovine pancreas, Sigma-Aldrich, St. Louis, MO, USA) to evaluate cell cycle and DNA content. The experiment was conducted at a rate of 150–300 cells/sec [38]. Cell cycle analysis was conducted in triplicate, and representative results were displayed because the findings were consistent across all repeats. The data were analyzed using an FACS Aria Calibur flow cytometer (BD Biosciences, San Diego, CA, USA) following standard protocols.

Whole PC cells were collected and washed once with ice-cold 1× PBS. Then, cells were lysed using 1× RIPA lysis buffer (Cell Signaling Technology, 9806, Danvers, MA, USA), and protein content in the lysates was quantified using a BCA protein assay kit (Pierce, 23225, Rockford, IL, USA). The extracted proteins were then resuspended with 4× sample buffer including 10% 2-Mercaptoethanol and denatured by boiling for 5 min. For protein separation, 8%–10% sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was performed, then electrotransfer onto a Trans-blot nitrocellulose membrane (Whatman International Ltd., 10401196, Maidstone, UK). Membranes were pretreated with 5% skim milk in TBST buffer (10 mM Tris [pH 8.0], 150 mM NaCl, 0.05% Tween 20). The blocked membranes were subsequently exposed to primary antibodies overnight at 4°C [39]. Primary antibodies were sourced from various commercial suppliers: anti-SLFN11 (Novus Biologicals, NBP1-92368, Littleton, CO, USA), anti-cell division cycle 6 (CDC6, Novus Biologicals, NBP2-47514), anti-cyclin A2 (Cell Signaling Technology, 4656), and anti-β-actin (Sigma-Aldrich, A5441, St. Louis, MO, USA). The antibodies were diluted in different blocking buffers as follows: anti-SLFN11 was diluted to 1:1000 in 3% skim milk in 1× PBS, anti-CDC6 at 1:200 in 3% BSA in 1× PBS, anti-cyclin A2 at 1:2000 in 5% skim milk in 1× PBS, and anti-β-actin at 1:5000 in 5% skim milk in 1× PBS. Protein expression levels were analyzed using chemiluminescence detection with the SuperSignal West Pico PLUS Chemiluminescent Substrate (Pierce, 34580). Horseradish peroxidase-conjugated secondary antibodies (Jackson Immunoresearch Laboratories, 315-035-045, 111-005-045, West Grove, PA, USA) was diluted at 1:5000 for detection.

Gemcitabine (LY-188011, S1714) and cisplatin (NSC119875) were obtained from Selleckchem (Selleck Chemicals, Houston, TX, USA). Olaparib (AZD2281), ceralasertib (AZD6738), and adavosertib (AZD1775) were supplied by AstraZeneca (Cambridge, UK).

All data are represented as the central tendency, derived from two or three independent experimental replicates. Statistical analyses were performed using GraphPad Prism (version 5.0, GraphPad Software, San Diego, CA, USA), and the results are shown as means ± standard errors of the means (SEMs). Group comparisons were made using a two-way analysis of variance (ANOVA) followed by Bonferroni’s post hoc test for multiple comparisons. A statistically significant difference was defined as p < 0.05 unless otherwise stated, and specific p-values are provided in the figure legends or results section.

We initially analyzed genetic alterations, including mutations and gene amplification, in the SLFN family and SLFN11 across five publicly available PC datasets using the cBioPortal platform (http://cbioportal.org (accessed on 1 January 2025)). In the ICGC (n = 99), QCMG (n = 456), CPTAC (n = 140), UTSW (n = 109), and TCGA (n = 186) datasets that analyzing patients with PC, the genetic variation of the SLFN family (including SLFN11) was 3.67% in UTSW, 3.24% in TCGA, and 1.31% in QCMG. Low amplification rates were typically found, and no amplifications were detected in the ICGC and CPTAC datasets. When analyzing SLFN11 alone, amplification was observed: of 2.16% and 1.83% in the TCGA and UTSW datasets, respectively; however, no amplification was observed in the ICGC, QCMG, and CPTAC datasets (Fig. 1A). Analysis of all five datasets (ICGC, QCMG, CPTAC, UTSW, and TCGA) showed variation in the SLFN family ranging from 0.7% to 1.1%. Genetic alterations were observed in 0.9% of cases for SLFN5, 0.7% for SLFN11, 0.8% for SLFN12, 0.7% for SLFN13, and 1.1% for SLFN14. In addition, SLFN5, SLFN12, and SLFN14 showed amplification, missense mutations, and truncating mutations, while only amplifications were observed in SLFN11 (Fig. 1B).

Next, we analyzed the mRNA expression levels of SLFN11 and other SLFN family genes in PC using TCGA data (n = 179) and compared them with normal tissue expression from GTEx (n = 171). Survival analysis was conducted based on publicly available data via the GEPIA web portal (http://gepia.cancer-pku.cn/ (accessed on 1 January 2025)). Analysis of TCGA data revealed that SLFN11 expression patterns were elevated in PC tissues relative to normal tissues (Fig. 1C). Then, we assessed the association between SLFN11 mRNA expression and clinical-pathological parameters using overall survival analysis (Kaplan-Meier curves). Although high SLFN11 expression appeared to correlate with lower survival rates after 20 months, the overall survival difference was not statistically significant (Fig. 1D). Further investigations with expanded cohorts and additional prognostic factors are necessary to clarify the potential relationship between SLFN11 expression and survival outcomes.

Additionally, among the SLFN family members, SLFN5, SLFN12, and SLFN13 exhibited elevated expression in PC and were linked to poorer overall survival. In contrast, SLFN14 showed no significant variation in expression levels or survival outcomes when comparing normal and PC tissues (Supplementary Fig. S1). Although SLFN11 mRNA expression exhibited a tendency to increase with tumor stage, this trend failed to achieve statistical significance (Fig. 1E). Based on these findings, SLFN11 protein expression levels were examined afterward in non-cancerous immortalized HPDE cells and eight PC cell lines (AsPC-1, BxPC-3, MIA PaCa-2, PANC-1, Panc10.05, HPAF-II, Capan-1, and Capan-2) using western blotting. Compared to HPDE cells, SLFN11 protein levels were lower in AsPC-1, BxPC-3, MIA PaCa-2, HPAF-II, and Capan-2 cells but higher in PANC-1, Panc10.05, and Capan-1 cells (Fig. 1F). According to these results, we examined the effect of SLFN11 expression in PC cells and hypothesized that it is related to cell death.

To investigate how SLFN11 influences cell cycle progression and apoptosis in PC cells, we used Panc10.05 cells with high SLFN11 expression and evaluated them using western blotting, CCK-8 assay, and FACS. We used three separate siRNAs to silence SLFN11 expression, all of which inhibited SLFN11 protein expression (Supplementary Fig. S2A). Cell growth was monitored for 72 h following siRNA transfection, revealing showing no significant impact on proliferation (Supplementary Fig. S2B). Next, we measured the cell cycle and the effect of siRNA treatment on apoptosis by assessing the hypodiploid (sub-G1) peak using PI staining in SLFN11-knockdown Panc10.05 cells. Apoptotic sub-G1 phase cells comprised 2.5% of the control and 4.8% of the SLFN11-knockdown PC cells, while polyploidy cells were found in 11.4% of the control and 17.3% of the SLFN11-knockdown PC cells. In addition, the percentage of cells arrested at the G0/G1 phase was 44.7% in the control and 34.4% in SLFN11-knockdown PC cells, while the percentage in the S phase was 11.4% in the control and 12.7% in SLFN11-knockdown PC cells (Supplementary Fig. S2C,D).

To investigate whether SLFN11 affects cell cycle progression in PC cells, we conducted a double thymidine block (DTB) assay. Pyrimidine deoxynucleoside was used as thymidine to synchronize cells arrested at the G1/S transition phase. In the DTB assay, cells were first synchronized at the G1/S phase boundary, and upon release from the second thymidine block, they progressed into the S phase (0–4 h) and subsequently entered the G2/M phase by 8 h. In Panc10.05 cells, SLFN11 expression was knocked down using siRNA, followed by DTB synchronization. Cells were then harvested at 0, 2, 4, 6, 8, and 10 h following the removal of the second thymidine block (Fig. 2A). Western blot analysis was conducted to examine the expression of key cell cycle regulators, including CDC6 and cyclin A, which are critical for DNA replication and checkpoint maintenance. In SLFN11-knockdown PC cells, CDC6 accumulation was observed at 0–4 h but rapidly decreased at 6–8 h compared to the control group. Similarly, cyclin A expression increased at 0–2 h and declined at 8 h in SLFN11-knockdown PC cells relative to the control group (Fig. 2B, Supplementary Fig. S3).

Next, after evaluating the cell cycle before release after DTB, most of the cells detected in the control group showed accumulation in the G0/G1 phase (54.6%), then in the S (18%), G2/M (20.9%), and sub-G1 phases (6.2%). However, in SLFN11-knockdown PC cells, the percentage of cells arrested at the G0/G1 was significantly reduced (37%), while those in the S (21.4%) and G2/M (24.4%) phases showed a partial increase. Additionally, the sub-G1 population (17.1%) exhibited an important rise relative to the control group at 0 h (Fig. 2C,D). Four hours after the release of the second thymidine block, the number of SLFN11-knockdown PC cells accumulated in the G0/G1 phase reduced (control siRNA: 45.8%, SLFN11 siRNA: 31.7%) while those in the sub-G1 phase (control siRNA: 4.4%, SLFN11 siRNA: 16%) increased, compared with control cells (Fig. 2C,D, 4 h). These data demonstrate that SLFN11 contributes to the regulation of PC cell transition to the G1 phase and apoptosis.

Gemcitabine, a DDA, is a standard chemotherapeutic agent for PC [40,41]. To investigate the influence of SLFN11 on gemcitabine sensitivity, we analyzed the association between SLFN11 mRNA expression and gemcitabine response across various cancer types using the CellMiner Cross-Database (https://discover.nci.nih.gov/cellminercdb/ (accessed on 1 January 2025)). A statistically significant association was identified between SLFN11 mRNA levels and gemcitabine sensitivity using the CTRP and CCLE datasets (r = 0.43, p = 3.1 × 10⁻³⁴, Fig. 3A). This correlation was further supported by analyses using the GDSC and CCLE datasets (r = 0.29, p = 1.3 × 10⁻¹³, Supplementary Fig. S4A) and the NCI-60 dataset (r = 0.69, p = 7.8 × 10⁻¹⁰, Supplementary Fig. S4B). These findings indicate a possible function of SLFN11 in modulating drug response across multiple cancer types.

Next, we analyzed gemcitabine sensitivity in PC cell lines according to SLFN11 mRNA expression levels using the GDSC and CCLE datasets. PC cell lines with high SLFN11 expression, such as Panc10.05 and Capan-1, exhibited greater gemcitabine sensitivity, whereas AsPC-1 and Capan-2 cells, which have low SLFN11 expression, were less sensitive (Fig. 3B). Furthermore, a strong statistical association was identified between SLFN11 expression and gemcitabine sensitivity in PC cell lines (r = 0.54, p = 0.013, Fig. 3B), further supporting the role of SLFN11 in gemcitabine response.

To further validate these findings, we assessed gemcitabine sensitivity in PC cell lines using the CCK-8 assay. Consistent with the results from Fig. 3B, Panc10.05 and Capan-1 cells exhibited high gemcitabine sensitivity, whereas Capan-2 cells displayed lower sensitivity (Fig. 3C). Interestingly, MIA PaCa-2 and AsPC-1 cells, despite low SLFN11 expression, showed relatively high gemcitabine sensitivity (Fig. 3B,C), suggesting that additional factors may contribute to drug response. Additionally, although PANC-1 cells exhibit high SLFN11 expression, their gemcitabine sensitivity was lower than that of Panc10.05 and Capan-1 cells (Fig. 3B,C). Conversely, Capan-2, another low-SLFN11-expressing cell line, exhibited the lowest gemcitabine sensitivity, further suggesting that SLFN11 expression alone does not fully predict drug response and that additional regulatory mechanisms are involved. This suggests that SLFN11 expression alone may not fully determine gemcitabine response, with other factors, such as DNA repair pathways or drug efflux mechanisms, may influence drug sensitivity in PC. To further assess the direct link between SLFN11 levels and gemcitabine response, we established SLFN11-KO PC cells through the CRISPR/Cas9 system in two PC cell lines, PANC-1 and Panc10.05. Western blot and immunofluorescence assays confirmed the successful knockout of SLFN11 in Panc10.05 cells (Supplementary Fig. S4C,D). According to the CCK-8 assay results, SLFN11-KO cells exhibited increased resistance to gemcitabine compared to WT Panc10.05 cells. However, in PANC-1 cells, the difference in survival between WT and KO was less pronounced, with WT survival leveling off at approximately 80% (Fig. 3D). This suggests that SLFN11 knockout alone may not be sufficient to significantly alter gemcitabine sensitivity in certain PC cell lines and that additional resistance mechanisms may be involved. These findings indicate that SLFN11 plays a significant role in modulating gemcitabine sensitivity in PC cells, although additional factors may also contribute to drug response.

To further explore the relationship between SLFN11 levels and drug sensitivity, we examined data from the NCI-60, GDSC, and CCLE datasets in the CellMiner Cross-Database for cisplatin (DDA), olaparib (PARP inhibitor), ceralasertib (ATR inhibitor), and adavosertib (Wee1 inhibitor). SLFN11 expression was strongly correlated with cisplatin sensitivity (Pearson correlation r = 0.64, p = 4.3 × 10⁻⁸) and a moderately correlated with ceralasertib sensitivity (r = 0.29, p = 0.027). Conversely, SLFN11 expression exhibited a weak and non-statistically meaningful relationship with olaparib (r = 0.11, p = 0.4) and adavosertib (r = −0.03, p = 0.85) sensitivity (Fig. 4A, Supplementary Fig. S4E,F). Next, the effects of cisplatin, olaparib, ceralasertib, and adavosertib on the growth of PC cell lines (AsPC-1, Capan-1, MIA PaCa-2, Capan-2, and Panc10.05) were confirmed using the CCK-8 assay. The treatment concentration ranges of cisplatin, olaparib, ceralasertib, and adavosertib were determined using IC50 values from the CellMiner Cross-Database (Supplementary Fig. S5), which served as a reference for experimental conditions. As a result, Panc10.05 and Capan-1 cells (high SLFN11 expression) showed high cisplatin and ceralasertib sensitivity, while Capan-2 cells (low SLFN11 expression) showed low cisplatin and ceralasertib sensitivity. MIA PaCa-2 and AsPC-1 cells had low SLFN11 expression, but showed high sensitivity to cisplatin and ceralasertib. On the other hand, SLFN11 expression was moderately associated with adavosertib sensitivity but not with olaparib sensitivity (Fig. 4B). Thus, SLFN11 expression appears to be partially associated with how PC cells respond to cisplatin and DDR inhibitors.

To investigate how SLFN11 expression influences the responsiveness of PC cells to DDR-targeted agents, we treated WT and SLFN11-KO Panc10.05 and PANC-1 cells with cisplatin, olaparib, ceralasertib, and adavosertib, either as monotherapies or in combination with gemcitabine, and assessed their impact on cell proliferation using the CCK-8 assay. When WT and SLFN11-KO cells were treated with cisplatin, olaparib, ceralasertib, and adavosertib alone, SLFN11-KO cells showed decreased responsiveness to cisplatin and adavosertib relative to WT cells, whereas no significant difference was observed in olaparib or ceralasertib treatment (Fig. 5A,B). In PANC-1 cells, SLFN11-KO cells inhibited cell proliferation only after high-concentration ceralasertib treatment (Fig. 5B). When cisplatin, olaparib, ceralasertib, and adavosertib were co-administered with gemcitabine (+G), SLFN11-KO cells exhibited greater sensitivity compared to WT cells across all tested drugs (Fig. 5C,D). The obtained results suggest that SLFN11 deficiency enhances the cytotoxic effects of these agents in the presence of gemcitabine. The obtained results indicate that targeting SLFN11 may serve as a potential strategy for improving the efficacy of various anticancer drugs in the treatment of gemcitabine-resistant PC.