Cervical cancer-derived HeLa cells were obtained from the American Type Culture Collection. Monkey-kidney-derived Vero, liver-cancer-derived HepG2, and normal human fibroblasts, TIG-1-20 cells were obtained from the National Institutes of Biomedical Innovation, Health and Nutrition, Japan. Cells were grown in DMEM (Sigma-Aldrich; Merck KGaA) supplemented with 10% FBS (Thermo Fisher Scientific, Inc.) and antibiotics (penicillin, 100 U/ml; streptomycin, 100 µg/ml and amphotericin B, 0.25 µg/ml) at 37°C and 5% CO₂. The HeLa-Fucci and Vero-Fucci cell lines were established as previously described (29).

Total RNA was isolated from HeLa cells using TRIzol^® reagent (Invitrogen; Thermo Fisher Scientific, Inc.) according to the manufacturer's protocol. Double-stranded cDNA was synthesized from 20 mg total RNA using Ready-to-Go You-Prime First-Strand Beads (GE Healthcare) and Oligo(dT) primers (Sigma-Aldrich; Merck KGaA) according to the manufacturer's instructions. qPCR was performed using a LightCycler FastStart DNA Master SYBR Green 1 Kit (Roche Diagnostics GmbH) according to the manufacturer's protocol. The transcript levels of Cdc25 (forward, 5′-AGCGAAGATGATGACGGATT-3′ and reverse, 5′-GCAGAGATGAAGAGCCAAAGA-3′) were estimated from the respective standard curves and normalized to the expression of GAPDH (forward, 5′-CATCTCTGCCCCCTCTGCTGA-3′ and reverse, 5′-GGATGACCTTGCCCACAGCCT-3′) determined in corresponding samples. The following thermocycling conditions were used for the qPCR: Initial denaturation for 3 min at 95°C, followed by 40 cycles of denaturation at 94°C for 30 sec, annealing at 60°C for 15 sec and elongation at 72°C for 30 sec. The experiments were performed in triplicate.

(R)-5-(methoxymethyl)-1-(phenylsulfonyl)-1,5-dihydro-2H-pyrrol-2-one (CCL113) was provided by the Chiba Chemical Library (Fig. 1). It was synthesized from d-pyroglutamic acid, and the schematic diagram is shown in Supplementary Fig. S1 (30). CCL113 was dissolved in DMSO (FUJIFILM Wako Pure Chemical Corporation) to obtain a 20-mM stock solution. Nocodazole (Sigma-Aldrich; Merck KGaA) was dissolved in DMSO at 100 µg/ml. DMSO was used as the vehicle control.

Cells (2×10³ cells/well) were seeded in 96-well plates. After 24 h of culture, cells were treated with increasing concentrations (1, 5, 10, 20, 30, and 40 µM) of CCL113 and incubated for 24 h. DMSO (<0.05%) was used as the vehicle control, based on a previous report (31). Cell viability was determined using the CellTiter-Glo Luminescent Cell Viability Assay (Promega Corporation). Luminescent signals were measured using a Wallac 1420 multilabel counter (PerkinElmer, Inc.) and presented as the proportional viability (%) by comparing the viability of CCL113-treated cells with the DMSO-treated cells.

For phase contrast microscopy, HeLa, Vero, HepG2, and TIG-1-20 cells were treated with DMSO or 10 µM CCL113 for 8 and 24 h. Following treatment with 10 µM CCL113 for 8 and 24 h, the cells were stained with Hoechst 33342 (Thermo Fisher Scientific, Inc.) and incubated for 5 min at 37°C. Subsequently, the cells were visualized at ×100 magnification with a UV-2A filter (excitation wavelength 365 nm; emission wavelength 400 nm) on a Nikon Eclipse TE2000-U microscope (Nikon Corporation). Mitotic cells stained with Hoechst 33342 were identified morphologically, and the mean number of mitotic cells in 10 random visual fields was used as the mitotic index. For imaging of HeLa-Fucci and Vero-Fucci cells, 3×10⁴ cells were grown in 35-mm dishes in DMEM with 10% FBS. Following overnight incubation at 37°C and 5% CO₂, cells were synchronized at the G₁/S phase by the double thymidine block (2 mM) method (32); thymidine was added into the culture medium at a final concentration of 2 mM and incubated for 14 h. The medium was removed, and cells were washed with PBS. Fresh cell culture medium was added, the cells were incubated for 9 h and 2 mM thymidine blocking solution was added for the second time and incubated for an additional 14 h. The medium was removed and washed with PBS, and fresh culture medium was added. Next, the cells were exposed to 10 µM CCL113 and visualized by time-lapse imaging using a computer-assisted fluorescence microscope (FV10i; Olympus Corporation). Images were recorded every 30 min. Two filter cubes were chosen for fluorescence imaging: mKusabira-orange (excitation wavelength 548 nm; emission wavelength 559 nm) to observe Fucci orange, and Azami-Green (excitation wavelength 493 nm; emission wavelength 505 nm) to observe Fucci green. Fluoview version 3.1 software (Olympus Corporation) was used for acquiring and analyzing images.

HeLa, Vero, HepG2, and TIG-1-20 cells were treated with CycleTEST™ PLUS DNA Reagent kit (Becton, Dickinson and Company) according to the manufacturer's protocol and analyzed using a BD Accuri™ C6 Flow Cytometer (Becton-Dickinson and Company) equipped with the FACScan fluorescence 2 (FL2) detector. The data were analyzed using FlowJo 7.6.5 software (FlowJo, LLC).

Cells were collected and washed twice with PBS, and then resuspended in M-PER^® Mammalian Protein Extraction reagent (Thermo Fisher Scientific, Inc.) with a cocktail of protease inhibitor (Sigma-Aldrich; Merck KGaA) and mixed gently for 10 min. The cell lysates were centrifuged at 14,000 × g for 10 min at 4°C. The Bio-Rad Protein Assay kit (Bio-Rad Laboratories, Inc.) was used to determine the protein concentration. Equal amounts (50 µg) of extracted protein were resolved on 10% SDS-PAGE (ATTO Corporation) and transferred onto PVDF membranes (Trans-Blot Turbo™ Transfer Pack; Bio-Rad Laboratories, Inc.). The membranes were blocked with 5% skim milk for 1 h at room temperature and then probed at 4°C overnight with the following mouse monoclonal antibodies: Anti-p-histone H3 (Ser10) (1:1,1000; cat. no. 9706S; Cell Signaling Technology, Inc.), anti-histone H3 (1:1,1000; cat. no. 14269S; Cell Signaling Technology, Inc.), anti-cyclin B1 (1:2,000; cat. no. 4135S; Cell Signaling Technology, Inc.), anti-phosphorylated (p)-CDK1 (Tyr15) (1:1,1000; cat. no. 9111S; Cell Signaling Technology, Inc.), anti-p-CDK1 (Thr14) (1:1,000; cat. no. 2543S; Cell Signaling Technology, Inc.), anti-p-CDK1 (Thr161) (1:1,000; cat. no. 9114S; Cell Signaling Technology, Inc.), anti-CDK1 (1:1,000; cat. no. 9116S; Cell Signaling Technology, Inc.), anti-cyclin D1 (1:1,000; cat. no. 2922S; Cell Signaling Technology, Inc.), anti-CDK4 (1:1,000; cat. no. 2906; Cell Signaling Technology, Inc.), anti-cyclin E1 (1:1,000; cat. no. 4129T; Cell Signaling Technology, Inc.), anti-Cdc25B (1:1,000; cat. no. 9525S; Cell Signaling Technology, Inc.), anti-Cdc25C (1:1,000; cat. no. 9522; Cell Signaling Technology, Inc.), anti-p-Cdc25C (Thr48) (1:1,000; cat. no. 9527T; Cell Signaling Technology, Inc.), anti-Plk1 (1:500; cat. no. 4535S; Cell Signaling Technology, Inc.), anti-p-Plk1 (Thr210) (1:1,000; cat. no. 5472S; Cell Signaling Technology, Inc.), anti-CDK2 (1:200; cat. no. sc-6248; Santa Cruz Biotechnology, Inc.), anti-p-CDK2 (Thr160) (1:1,000; cat. no. 2561S; Cell Signaling Technology, Inc.), anti-ATM (1:1,000; cat. no. 92356S; Cell Signaling Technology, Inc.) anti-Chk2 (1:1,000; cat. no. 3440T; Cell Signaling Technology, Inc.), anti-p-Chk2 (Thr68) (1:1,000; cat. no. 2661S; Cell Signaling Technology, Inc.), anti-p-p53 (Ser15) (1:1,000; cat. no. 9286; Cell Signaling Technology, Inc.), anti-p21 (1:2,000; cat. no. 2946S; Cell Signaling Technology, Inc.), anti-poly (ADP-ribose) polymerase (PARP) (1:1,000; cat. no. 9542S; Cell Signaling Technology, Inc.), anti-β-actin (1:1,000; cat. no. 3700S; Cell Signaling Technology, Inc.), anti-cyclin A (1:1,000; cat. no. sc-239; Santa Cruz Biotechnology, Inc.), anti-p53 (1:1,000; cat. no. sc-126; Santa Cruz Biotechnology, Inc.) and p-ATM (Ser1981) (Cell Signaling Technology, Inc. #4526S, dilution: 1:1,000). After washing three times with TBS, the blots were incubated with an HRP-linked anti-mouse IgG (1:1,000; cat. no. 7076S; Cell Signaling Technology, Inc.) for 1 h at room temperature. Clarity Western ECL substrate (Bio-Rad Laboratories, Inc.) was used to visualize protein signals. The bands were analyzed using ImageJ v1.46r software (National Institutes of Health).

The geometrical details of the αβ-tubulin protein were obtained from the Research Collaboratory for Structural Bioinformatics Protein Data Bank (https://www.rcsb.org) with the accession code 5syf (33). The structure was cleared of all solvent molecules and compounds before proceeding with the analysis. Docking analysis was performed separately for the α- and β-tubulin subunits. The 3D chemical structures of taxol and CCL113 were designed using Avogadro software (version 1.1.1) (https://avogadro.cc) (34) and optimized in Gaussian 16 (Gaussian Inc.) at the B3LYP/6-31G (d, p) theoretical level (35,36). AutoDock 4.2 software (http://autodock.scripps.edu) (37) was used for molecular docking simulations. Structure files for proteins and ligands were made in the PDBQT format using default charges. Furthermore, non-polar hydrogen atoms were conjoined using AutoDockTools (version 1.5.6) (http://autodock.scripps.edu). A grid box with the dimensions 76 Å × 76 Å × 76 Å XYZ was centered on the tubulin structure. A precalculated value for binding affinity for each ligand was prepared using AutoGrid 4.2 (http://autodock.scripps.edu), and rigid docking was accomplished using the Lamarckian genetic algorithm parameter (37). All other parameters in the AutoDock 4.2 software were considered in their default settings. The best pose for docking was selected based on the lowest values of binding energies obtained. The free binding energies were computed using the in-built linear regression model in AutoDock 4.2. The root-mean-square deviation (RMSD) values for ligands (with the dock input file) and the hydrogen bond occupancy were calculated using PyMOL (https://pymol.org/2/) (38).

All values were expressed as the mean ± SD. Statistical analyses were performed using data obtained from three independent experiments. Data were analyzed using the Mann-Whitney U test with the software Statcel4 version 4 (OMS). One-way ANOVA followed by Bonferroni's correction were used for multiple comparisons. P<0.05 was considered to indicate a statistically significant difference.

The anti-proliferative effects of the novel sulfonamide CCL113 was observed in HeLa and Vero cells during the anticancer drug screening of the Chiba Chemical Library. For the screening, cervical cancer-derived HeLa cells were chosen as a typical cancer cell line, in which wild-type p53 is expressed (39). Monkey kidney-derived Vero cells were chosen as a noncancerous cell line (40). CCL113 was one of the four compounds with an IC₅₀ that was 10-fold lower for HeLa than for Vero cells. Further screening using HepG2 and TIG-1-20 showed only CCL113 exhibited cancer-cell specific cytotoxicities (data not shown). The cytotoxicity of CCL113 was assessed in HeLa and Vero cells using an ATP assay. The IC₅₀ of CCL113 for HeLa and Vero cells was 9.4 and 96 µM, respectively. The results showed that the cell viability of HeLa, but not Vero cells, was significantly decreased following 24 h treatment with 5 and 10 µM CCL113 (Fig. 2A). Significant differences in cytotoxicity were also observed between HeLa and Vero cells at 20–40 µM, although CCL113 caused Vero cells cytotoxicity at concentrations of >10 µM. Furthermore, the effects of 5–20 µM CCL113 on cell cycle progression in both cell lines were investigated. Both HeLa and Vero cells showed a marked increase in the number of round cells after 8 h of 10 µM CCL113 treatment (Fig. 2B). Hoechst 33342 staining of cell nuclei indicated that by 8 h, the chromosomes condensed and congregated to the equatorial plane, in a manner typical of cells in M phase in both HeLa and Vero cells. By 24 h, abnormal nuclei were observed in mitotic HeLa cells (Fig. 2C). These observations suggested that CCL113 might induce cell cycle arrest in the M phase. Both cells showed an increased mitotic index after treatment with CCL113, and the effect was more evident in Vero cells (Fig. 2D).

To further verify CCL113-induced cell cycle arrest, CCL113-treated (10 µM; 8 and 24 h) HeLa and Vero cells were analyzed by flow cytometry (Fig. 3A and B). Compared with control groups, a significantly higher proportion of CCL113-treated cells was observed in the G₂/M phase (Fig. 3C and D). The results were consistent with the morphological observations.

To elucidate the molecular basis of CCL113-induced M phase arrest in HeLa and Vero cells, the levels of cell cycle regulatory proteins were assessed using western blotting. Total cellular protein was isolated from cells treated with 10 µM CCL113 for 8 and 24 h. Since phosphorylation at Ser10 of histone H3 is significantly related to mitotic chromosome condensation (41–44), phosphorylation levels of histone H3 (Ser10) were first examined to confirm mitotic arrest. The results showed that the phosphorylation levels of histone H3 (Ser10) were significantly upregulated in CCL113-treated cells, suggesting that CCL113 induced M phase arrest by facilitating phosphorylation at Ser10 of histone H3 (Fig. 4A).

Activation of the CDK1-cyclin B1 complex initiates entry into mitosis and facilitates mitotic progression (13,14). CDK1 activation, in turn, requires dephosphorylation at Tyr15 and Thr14 residues and phosphorylation at Thr161 (16). To investigate the activity of CDK1-cyclin B1, the levels of cyclin B1 and p-CDK1 in CCL113-treated HeLa and Vero cells were measured. As shown in Fig. 4A, the levels of cyclin B1 in CCL113-treated HeLa cells was significantly higher compared with DMSO-treated cells. This could be explained by the increase in the number of cells in M phase. As depicted in Fig. 4A, the results showed that in HeLa cells, the relative phosphorylation levels at Tyr15 and Thr14 [p-CDK1(Tyr15)/CDK1 and p-CDK1(Thr14)/CDK1] were significantly elevated at 8 h, indicating an increase in CDK1 inhibitory phosphorylation. Additionally, in Vero cells, the relative phosphorylation levels at Tyr15 and Thr14 of CDK were significantly lower at 24 h, indicating a relative decrease in the CDK1 inhibitory phosphorylation. CCL113-mediated inactivation of CDK1 by inhibitory phosphorylation at Tyr15 and Thr14 in HeLa cells might inhibit mitotic entry and progression, leading to an increase in the number of cells in the G₂/M phase. By contrast, the elevated expression of cyclin B1 and decrease in CDK1 phosphorylation at Tyr15 and Thr14 in Vero cells (CCL113 treatment, 24 h) could explain the increase in cells in M phase with activated CDK1-cyclin B1 complexes.

The Thr210 residue of Plk1 protein is the primary phosphorylation site responsible for its activation during mitosis; moreover, activated P1k1 regulates the CDK1-cyclin B1 complex during mitosis (32,45). Following treatment with CCL113, significantly increased Thr210 phosphorylation of Plk1 was observed in both HeLa and Vero cells, consistent with the increased number of cells in the G₂/M phase (Fig. 4A). Therefore, CCL113 treatment might inhibit the activation of CDK1 indirectly by upregulating Plk1.

Subsequently, the present study examined whether CCL113 affected the expression of regulatory proteins during other phases of the cell cycle, including key regulators of G₁ progression (cyclin D1 and CDK4), G₁/S transition (cyclin E1 and p-CDK2) and S phase progression (cyclin A and p-CDK2). As shown in Fig. 4B, CCL113 had little effect on the expression of CDK4 and cyclin E1, key regulators of G₁ and G₁/S transition, at 8 h. However, CCL113 significantly reduced the protein levels of cyclin D1 after 24 h of treatment, suggesting the decrease in the number of cells in the G₁ phase. Aside from a temporal upregulation of cyclin A in Vero cells after 8 h, CCL113 seemed to have a negligible direct effect on the expression levels of cyclin A and p-CDK2 (Thr160) in both HeLa and Vero cells, suggesting CCL113 had little effect on G₁/S transition. These results suggested that although CCL113 treatment led to a slight modulation in the regulatory proteins during other phases of the cell cycle, its main impact was observed during the M phase in treated cells.

Cdc25 phosphatases activated by Plk1 are responsible for the dephosphorylation and activation of CDK1 (46). Cdc25 phosphatases include three different isoforms: Cdc25A, B and C (46). To examine the effects of CCL113 on the expression levels of Cdc25 and cell cycle progression, cells were treated with various concentrations (0, 5, 10 and 20 µM) of CCL113 and the levels of Cdc25 phosphatases were examined by western blotting. Nocodazole, an inducer of M phase arrest, served as a positive control.

In HeLa cells, the expression of p-histone H3 (Ser10) increased as the concentration of CCL113 increased from 5 to 10 µM but decreased at 20 mM (Fig. 5A), suggesting that in these cells, CCL113 might inhibit mitotic entry at 20 mM. The levels of Cdc25B and total Cdc25C protein decreased in HeLa cells in a time- and dose-dependent manner in response to CCL113 treatment (Fig. 5A). RT-qPCR analysis did not detect any apparent changes in Cdc25B/C mRNA levels in HeLa cells after treatment with 5 to 20 µM CCL113 for 8 h (data not shown). The levels of phosphorylated Plk1 (p-Plk1, Thr210) and p-histone H3 (Ser10) showed a similar response after treatment with various concentrations of CCL113 (Fig. 5A), indicating that 5 to 10 µM CCL113 might inhibit mitotic progression but not mitotic entry. In addition, a reduced amount of actin in HeLa cells was observed following exposure to 20 µM CCL113, suggesting that the cytotoxicity of 20 µM CCL113 might cause nonspecific protein degradation.

As shown in Fig. 5B, Vero cells showed a similar expression pattern of p-histone H3 (Ser10) and Cdc25B protein in HeLa cells in response to treatment with various concentrations of CCL113.

The Fucci system, based on fluorescent ubiquitination-based cell cycle indicator (FUCCI), allows visualization of cell cycle progression in real time at the single-cell level, and the dynamic data can aid in understanding how individual cells respond to a drug (47). CCL113-induced cell cycle alterations in synchronized HeLa-Fucci and Vero-Fucci cells were monitored. FUCCI can be used to determine the distribution of a cell population through different stages of the cell cycle and distinguish G₁ and S/G₂/M phases of the cell cycle by labeling G₁ nuclei in red and S/G₂/M nuclei in green. During the G₁/S transition (red-to-green conversion), red and green fluorescence overlap, resulting in yellow nuclei.

The results showed that most HeLa-Fucci and Vero-Fucci cells were in the S phase at the beginning of imaging (Fig. 6A and B) and showed differential progression following exposure to CCL113. The serially collected images of 650 HeLa-Fucci and 344 Vero-Fucci cells were traced and analyzed. In synchronized HeLa-Fucci cells, 19% of cells required more time than control cells to progress through the M phase (mean, 2.4 vs. 1.6 h for control cells) and passed through the G₁ phase to S/G₂ phase as shown in Fig. 6A-a. A total of 24% of cells underwent abnormal cell division and subsequent cell death at the G₁ phase (Fig. 6A-b). These cells required more time to progress through the M phase (mean, 4.0 h) than the control cells. As shown in Fig. 6A-c, 53% of cells entered the M phase and exhibited long-term mitotic cell rounding (mean, 16.6 h) before eventual cell death. The nuclei of very few HeLa-Fucci cells (1%) changed color from green to G₁-like red without undergoing mitosis (Fig. 6A-d), while a few cells (3%) were arrested at the S/G₂ phase and subsequently exhibited cell death (Fig. 6A-e). Therefore, CCL113 treatment resulted in a longer S/G₂ and M phase in HeLa cells compared with control cells.

In contrast to HeLa-Fucci cells, Vero-Fucci cells exhibited different responses to CCL113. Nearly half the cells (48%) progressed through the S/G₂ phase at approximately the same time (mean, 6.2 h) as synchronized control cells but were arrested in the M phase (Fig. 6B-f). A total of 12% of treated cells required more time to progress through the S/G₂ phase (mean, 9.8 h) and underwent prolonged mitosis (mean, 10.2 h) to the G₁-like phase without cytokinesis (Fig. 6B-g). Furthermore, 36% of cells progressed slowly through the S/G₂ phase (mean, 20.8 h) and entered the G₁-like phase without undergoing mitosis (Fig. 6B-h). Prior to transitioning to the G₁-like phase, the nuclei of these cells stained yellow for a brief period, similar to G₁/S transition (red-to-green conversion), suggesting that the G₁-like phase did not correspond to the beginning of G₁ phase, at which the red color is weak.

As shown in Fig. 6B-i, the 4% of CCL113-treated Vero-Fucci cells that required a shorter time to progress through the S/G₂ phase than the control cells (mean, 2.3 vs. 5.6 h for control cells) underwent normal division. A small fraction of the Vero cell population may have experienced inefficient thymidine block, which reflected the cell population in the G₂ phase and suggested that CCL113 may not be effective during the G₂ phase. To confirm and validate the cell cycle phase regulated by CCL113, CCL113-treated Vero-Fucci cells were further analyzed. As shown in Fig. 6C, CCL113 treatment significantly reduced the number of cells 1 to 1.5 h before M phase entry. Treament with CCL113 increased the number of cells with extended periods before M phase entry, suggesting that the G₂/M checkpoint hindered the cells from entering the M phase.

Cells that fail to progress through mitosis accumulate de novo DNA damage foci and experience mitotic failure (23,48). To confirm whether CCL113 activated the DNA damage response, its central regulators, such as ATM and other proteins including Chk2, p53, and p21, were examined in cells treated with CCL113. The results showed that exposure to CCL113 (10 µM) increased the levels of p-ATM (Ser1981), p-Chk2 (Thr68), p53 (Ser15), and p21 in HeLa cells (Fig. 7). Increase in p-p53 at Ser15 reduces the interaction with E3 ubiquitin-protein ligase MDM2 (49), which might explain the increase in p53 levels in CCL113-treated Vero cells (Fig. 7). To examine the effects of CCL113 on apoptosis, the present study analyzed the expression of PARP fragment, which is an indicator of apoptosis (10). Cleaved PARP fragment (89 kDa) was observed in CCL113-treated HeLa cells at 24 h (Fig. 7), indicating the induction of apoptosis; however, the cleaved PARP band could not be detected in CCL113-treated Vero cells at 24 h, suggesting that CCL113-induced apoptosis might not be frequent in normal cells.

To investigate the effects of CCL113 on other cancer cells and normal cells, HepG2, a human liver cancer cell line, and TIG-1-20, normal human fibroblasts, were employed. Similar to HeLa cells, HepG2 cells are known to express wild-type p53 (39). Consistent with the results observed in HeLa and Vero cells, both HepG2 and TIG-1-20 cells showed a marked increase in the number of round cells after 24 h of exposure to 10 µM CCL113. Hoechst 33342 staining of cell nuclei confirmed that CCL113 treatment arrested HepG2 cells in metaphase, whereas TIG-1-20 cells were arrested in prometaphase (Fig. 8A). Flow cytometry analyses showed that the number of both HepG2 and TIG-1-20 cells significantly increased in the G₂/M phase following CCL113 treatment (Fig. 8B). Treatment with CCL113 significantly decreased the cell viability of HepG2 compared with TIG-1-20 cells, after 24 h of treatment (Fig. 8C).

As shown in Fig. 8D, the expression of cell cycle regulators in HepG2 cells in response to CCL113 treatment was comparable to the response observed in HeLa cells; the levels of cyclin B1 and phosphorylation of CDK1 at Tyr15 significantly increased, while the levels of Cdc25B and Cdc25C protein were decreased. Similarly, CCL113-treated TIG-1-20 cells showed responses comparable to those of Vero cells. Furthermore, CCL113 treatment led to a significant increase in the levels of p53 and p21 in HepG2 and TIG-1-20 cells. Meanwhile, the cleaved PARP fragment was observed only in CCL113-treated HepG2 cells and not in TIG-1-20 cells at 24 h (Fig. 8D), suggesting that apoptosis was induced only in HepG2 cells and not in normal cells, consistent with the results observed in HeLa and Vero cells.

Since microtubule-targeting agents (MTAs), which are commonly used anticancer drugs, often function by blocking cell entry into mitosis (50,51) the possibility of CCL113 acting as an MTA was investigated. Molecular docking studies between CCL113 and tubulins were performed using AutoDock 4.2. CCL113 exhibited the highest binding affinity at the taxol-binding site of β-tubulin (Table I). The free binding energy of CCL113 at the taxol-binding site of β-tubulin (−4.24) was favorable to facilitate the interaction, unlike that of a-tubulin and taxol (−3.41 and −4.81, respectively). The RMSD value of CCL113 with b-tubulin was lower compared with taxol with β-tubulin. Furthermore, CCL113 exhibited a higher number of hydrogen bond interactions with the taxol-binding sites of β-tubulin than taxol, suggesting that CCL113 could bind to the taxol-binding site of β-tubulin.