Abstract
Aim: The aim of this study was to investigate the antitumor potential of guaiazulene-3-carboxylate derivatives against oral malignant cells. Materials and Methods: Twelve guaiazulene-3-carboxylate derivatives were synthesized by introduction of either with alkyl group [1-5], alkoxy group [6, 7], hydroxyl group [8, 9] or primary amine [10-12] at the end of sidechains. Tumor-specificity (TS) was calculated by the ratio of mean 50% cytotoxic concentration (CC50) against 3 human oral mesenchymal cell lines to that against 4 human oral squamous cell carcinoma (OSCC) cell lines. Potency-selectivity expression (PSE) was calculated by dividing TS value by CC50value against OSCC cell lines. Cell cycle analysis was performed by cell sorter. Results: [6, 7] showed the highest TS and PSE values, and induced the accumulation of both subG1 and G2/M cell populations in HSC-2 OSCC cells. Quantitative structure-activity relationship analysis demonstrated that their tumor-specificity was correlated with chemical descriptors that explain the 3D shape, electric state and ionization potential. Conclusion: Alkoxyl guaiazulene-3-carboxylates [6, 7] can be potential candidates of lead compound for developing novel anticancer drugs.
Azulene (Figure 1A) is an isomer of naphthalene having a dipole moment and a resonance energy with intermediate values between that of benzene and naphthalene; it is considerably more reactive, when compared with these two arenes (1-4). Among the 962 papers cited in PubMed regarding azulenes, most of them have focused on its chemistry, followed by biological activity, while few papers have focused on dentistry and oral application. Sodium azulene sulfonates have been reported to be effective for the treatment of oral mucositis (5) and oral lichen planus (6), possibly due to their antioxidant and anti-inflammatory activities (7, 8). In contrast, much reduced numbers of papers of guaiazulene (Figure 1B), a lipophilic azulene derivative, have been published, approximately half of which have dealt with its chemistry. Guaiazulenes also have antioxidant and anti-inflammatory activities (9-11) and a few papers have dealt with the treatment of oral diseases (12, 13).
As far as we know, anticancer potential of guaiazulene derivatives against human oral malignant cells has not yet been reported. This urged us to initiate the investigation of 10 alkylaminoguaiazulenes (Figure 1C) (14), 10 guaiazulene amides (Figure 1D) (15) and 14 azulene amide derivatives without or with 7-isopropylgroup (Figure 1E, F) (16). We have reported that the introduction of an isopropyl group in the seven-member ring and an amide group rather than alkylamino group in the five-member ring of guaiazulene increased the specific cytotoxicity against malignant cells over non-malignant cells (14-16) (Figure 1). Furthermore, quantitative structure-activity relationship (QSAR) analyses demonstrated the tight correlation of their tumor-specificity with hydrophobicity and molecular shape (15, 16).
The aim of the present study was to search for more tumor-selective guaiazulene derivatives. For this purpose, we synthesized a total of 12 guaiazulene-3-carboxylate derivatives [1-12] (Figure 1), in which alkyl group [1-5], alkoxy group [6, 7], hydroxyl group [8, 9] and primary amine [10-12] were introduced at the end of sidechain (Figure 1G), and investigated their tumor-specificity using four human oral squamous cell carcinoma (OSCC) cell lines and three human normal oral cells. We also investigated the effects of these compounds on cell cycle phase distribution, in OSCC cells.
Materials and Methods
Materials. The following chemicals were obtained from the indicated companies: Dulbecco's modified Eagle's medium (DMEM) from Gibco BRL, Grand Island, NY, USA); fetal bovine serum (FBS), 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) from Sigma-Aldrich Inc., St. Louis, MO, USA; 5-fluorouracil (5-FU) from Kyowa, Tokyo, Japan; cisplatin (CDDP) from Nichi-Iko Pharmaceutical Co. Ltd., Toyama, Japan; carboplatin (CBDCA) from Sawai Pharmaceutical Co. Ltd., Osaka, Japan; Paclitaxel (PTX) from Nipro Corporation, Osaka, Japan; dimethyl sulfoxide (DMSO) and actinomycin D (Act. D) from Wako Pure Chem. Ind., Osaka, Japan. Regarding consumables, 100-mm treated culture dishes were purchased from TrueLine, Nippon Genetics Co., Ltd, Tokyo, Japan and 96-well plates from Techno Plastic Products AG, Trasadingen, Switzerland.
Synthesis of guaiazulene-3-carboxylate derivatives. Methyl guaiazulene-3-carboxylate [1], ethyl guaiazulene-3-carboxylate [2], n-propyl guaiazulene-3-carboxylate [3], isopropyl guaiazulene-3-carboxylate [4], n-butyl guaiazulene-3-carboxylate [5], 2-methoxyethyl guaiazulene-3-carboxylate [6], 2-ethoxyethyl guaiazulene-3-carboxylate [7], 2-hydroxyethyl guaiazulene-3-carboxylate [8], 2-(2-hydroxyethoxy)ethyl guaiazulene-3-carboxylate [9], 2-aminoethyl guaiazulene-3-carboxylate [10], 3-aminoprpyl guaiazulene-3-carboxylate [11], 4-aminobutyl guaiazulene-3-carboxylate [12] (Figure 1G) were synthesized, according to previous reports (6, 17, 18). N-(2-methoxyethyl)guaiazulenecarboxamide [X] was synthesized as previously described (15). All compounds were dissolved in DMSO at 40 mM and stored at −20°C before use.
Cell culture. Human normal oral cells [gingival fibroblast (HGF), periodontal ligament fibroblast (HPLF), pulp cell (HPC)] (19) at 12~20 population doubling level (PDL) and OSCC cell lines (Ca9-22, HSC-2, HSC-3, HSC-4) (Riken Cell Bank, Tsukuba, Japan) were cultured at 37°C in DMEM supplemented with 10% heat-inactivated FBS and antibiotics under humidified 5% CO2 atmosphere, as described previously (14-16).
Assay for cytotoxic activity. Cells were inoculated at 2×103 cells/0.1 ml in a 96-microwell plate. After 48 h, the medium was replaced with 0.1 ml of fresh medium containing various concentrations of test compounds. Control cells were treated with the same amounts of DMSO present in each diluent solution. Cells were incubated for 48 h and the relative viable cell number was then determined by the MTT method, as described previously (14-16). The CC50 was determined from the dose–response curve of triplicate samples.
Calculation of tumor-selectivity index (TS). TS(mean) was calculated as the ratio of the mean CC50 value for the human normal oral cells (HGF+HPLF+HPC) to that for the OSCC cell lines (Ca9-22+HSC-2+HSC-3+HSC-4). Moreover, TS was calculated for cells derived from gingival tissue (20), and as the ratio of CC50 (HGF) to CC50 (Ca9-22) (TS(HGF/Ca9-22)).
Calculation of potency-selectivity expression (PSE). PSE was calculated by the formula: (TS/CC50) ×100 (11, 12).
Cell cycle analysis. Cells (approximately 106 cells) were harvested, fixed, treated with ribonuclease A, stained propidium iodide, filtered through cell strainers and then were subjected to cell sorting (SH800 Series, SONY Imaging Products and Solutions Inc., Atsugi, Kanagawa, Japan) and cell cycle analysis (Cell Sorter Software version 2.1.2., SONY Imaging Products and Solutions Inc), as described previously (16).
Calculation of chemical descriptors. pCC50 (i.e., the −log CC50) was used for the comparison of the cytotoxicity between the compounds, since the CC50 values had a distribution pattern close to a logarithmic normal distribution. The mean pCC50 values for normal cells and tumor cell lines were defined as N and T, respectively (15, 16) (Table II). The 3D-structure of each chemical structure was drawn by Marvin Sketch (MarvinSketch 18.10.0, ChemAxon, Budapest, Hungary, http://www.chemaxon.com), and optimized by CORINA Classic (Molecular Networks GmbH, Nürnberg, Germany) with forcefield calculations (amber-10: EHT) in Molecular Operating Environment (MOE) version 2019.0101 (Chemical Computing Group Inc., Quebec, Canada) and Dragon (Dragon 7 version 7.0.2, Kode srl., Pisa, Italy).
Statistical analysis. Each experimental value was expressed as the mean±standard deviation (SD) of triplicate or quadruplicate measurements. The statistical analysis was performed using one-way analysis of variance (ANOVA) followed by Bonferroni's post-hoc test for multiple comparisons. The correlation between chemical descriptors and cytotoxicity or tumor specificity index was investigated using linear regression analyses. The significance level was set at p<0.05. Statistical analysis was performed using the JMP Pro version 14.3.0 software (SAS Institute Inc., Cary, NC, USA).
Results
Cytotoxicity and tumor-specificity. Twelve guaiazulene-3-carboxylate derivatives used in this study were classified into four groups: alkyl guaiazulene-3-carboxylates [1-5], alkoxyl guaiazulene-3-carboxylates [6, 7], hydroxyalkyl guaiazulene-3-carboxylates [8, 9] and aminoalkyl guaiazulene-3-carboxylates [10-12] (Figure 1G). We compared their cytotoxic activity against four human oral squamous cell carcinoma (OSCC) cell lines (Ca9-22, HSC-2, HSC-3, HSC-4) and three normal oral cells (HGF, HPLF, HPC), by comparing the 50% cytotoxic concentration (CC50) determined from the dose-response curve (Table I). We have adopted 48 h treatment time, based on our observation that significant (p<0.05) cytotoxicity of compounds [6, 7] appeared 3 h after treatment, reaching the plateau level after 24~48 h (Figure 2). We have repeated the same experiments 3 times. The mean values of CC50, tumor-selectivity index (TS), and potency-selectivity expression (PSE) of these twelve compounds, as well as of positive controls (5-FU, CDDP, and CBDCA) obtained from these 3 independent experiments are listed in Table I. Most of the compounds [1, 3, 4-6, 8-12] showed significantly higher cytotoxicity against OSCC cell lines, compared to normal cells (p<0.05). Among the 12 studied guaiazulene-3-carboxylates, two alkoxyl guaiazulene-3-carboxylates [6, 7] (TSmean=4.4±0.2; PSE=13.0±1.9) showed the highest TS values than five alkyl guaiazulene-3-carboxylates [1-5], two hydroxyalkyl guaiazulene-3-carboxylates [8, 9], and three aminoalkyl guaiazulene-3-carboxylates [10-12] (Table I). Moreover, both [6, 7] showed higher TS value than CDDP and CBDCA (TSmean=2.2±1.5 and 2.4±1.1, respectively), and had PSE(mean) values comparable to that of 5-FU (13.4±6.5). Regarding TS(HGF/Ca9-22) and PSE(HGF/Ca9-22), high SD values were observed, possibly due to a cytostatic, rather than cytotoxic inhibition of cell proliferation, causing variations of CC50 values in each experiment (Table I).
Induction of apoptosis and G2/M arrest. Light microscopical observation (Figure 3A) revealed that HSC-2 cells treated for 48 h with 20 μM of either [6] or [7] (slightly lower concentration of their CC50: 34.8 and 28.0 μM, Table I) were a mixture of shrunken and spread cells. Cell cycle analysis demonstrated that when compared to the control, [6, 7] significantly (p<0.05) reduced the G1 cell population, while increased the subG1 and G2/M phase cells, regardless of treatment time (24 h and 48 h) (Figure 3B, 3C). Actinomycin D (Act. D) increased more the percentage of subG1 cell population (p<0.05), but slightly reduced (p<0.05) the G2/M phase cells at 24 h (Figure 3B, 3C).
Computational analysis. The number of descriptors calculated from MOE and dragon were 344 and 5,255, respectively. As a result of excluding duplicates or descriptors with standard deviation of 0, the number of descriptors reduced to 264, 2,808, respectively. Among a total of 3,072 descriptors, the top six descriptors that showed the highest correlation coefficient (r2) to T, N and T-N are listed in Table II.
Cytotoxicity against human OSCC cell lines was correlated with descriptors BCUT_SLOGP_0 (r2=0.841, p<0.0001) (topological shape), Mi (r2=0.785, p=0.0001) (ionization potential), Mor24e (r2=0.757, p=0.0002) (3D shape and electric state), C% (r2=0.751, p=0.0003) (percentage of C atoms), Mor24i (r2=0.737, p=0.0003) (3D shape and ionization potential) and DISPi (r2=0.734, p=0.0004) (3D shape, size and ionization potential) (Figure 4).
Cytotoxicity against human normal oral mesenchymal cells was correlated with descriptors vsurf_Wp2 (r2=0.783, p=0.0001) (3D shape and polarizability), vsurf_IW1 (r2=0.753, p=0.0003) (3D shape and hydrophilicity), h_logD (r2=0.751, p=0.0003) (lipophilicity), vsurf_Wp3 (r2=0.740, p=0.0003) (3D shape and polarizability), RDF010s (r2=0.730, p=0.0004) (3D shape, size and electric state), and BCUT_SLOGP_0 (r2=0.678, p=0.0010) (topological shape) (Figure 5).
Tumor-specificity was correlated with descriptors MEcc (r2=0.696, p=0.0007) (3D shape), L3s (r2=0.692, p=0.0008) (3D shape, size and electric state), SpMAD_G/D (r2=0.678, p=0.0010) (3D shape and size), L3m (r2=0.649, p=0.0016) (3D shape, size and electric state), H2i (r2=0.648, p=0.0016) (3D shape and ionization potential) and TDB10i (r2=0.646, p=0.0016) (3D shape and ionization potential) (Figure 6).
These data suggest that both tumor-specificity and cytotoxicity of guaiazulene-3-carboxylate against OSCC correlate with 3D shape, electric state, and especially ionization potential.
Discussion
The present study demonstrated that among twelve guaiazulene-3-carboxylates, two alkoxyl guaiazulene-3-carboxylates [6, 7] showed higher tumor-specificity than five alkyl [1-5] and two hydroxyalkyl [8, 9] guaiazulene-3-carboxylates and three aminoalkyl guaiazulene-3-carboxylate carboxamides [10-12] (Table I). Both [6, 7] showed higher TS value than CDDP and CBDCA, and having comparable PSE value with 5-FU (Table I). Higher TS of [6, 7] might be explained by their 3D shape, electric state and especially ionization potential (Figure 6). This point was confirmed by the fact that when carboxylate portion in [6] was replaced with amide (N-(2-methoxyethyl)guaiazulenecarboxamide [X]), both TS and PSE were reduced (Figure 7). Guaiazulene has been reported to induce apoptosis in normal HGF (21). Therefore, compounds with much higher tumor-specificity should be synthesized.
PubMed search demonstrated that no paper published on the G2/M arrest by guaiazulene. Therefore, the present study demonstrated for the first time that [6, 7] induced cell shrinkage and subG1 cell accumulation (one of the markers of apoptosis) (22, 23), as well as G2/M cell accumulation (indication of mitotic arrest). We have recently reported that 7-isopropyl-3-methyl-N-propylazulene-1-carboxamide and 2-methoxy-N-pentylazulene-1-carboxamide, both of which do not have guaiazulene structure, did not induce the accumulation at G2/M, although they induced apoptosis in HSC-2 cells (16). Taken together, the presence of guaiazulene structure may be involved in G2/M arrest induction; however, further study is required to confirm the induction of apoptosis markers by [6, 7] and investigate the possible link of G2/M arrest and apoptosis induction.
We have recently reported that several G2/M blockers such as taxanes paclitaxel [Taxol®, the first microtubule stabilizing agent (24)] and docetaxel (25), and 3-styrylchromone derivatives [7-methoxy-3-[(1E)-2-phenylethenyl]-4H-1-benzopyran-4-one, 3-[(1E)-2-(4-hydroxyphenyl)ethenyl]-7-methoxy-4H-1-benzopyran-4-one] show very high TS values (>7267, >86122, 301 and 182, respectively) (26). However, many reports, including ours, demonstrated that microtubule-targeted agents have potent neurotoxicity, adversely affecting the quality of life of patients on a long-term basis (27-30). We have also reported that doxorubicin induced very potent keratinocyte toxicity by inducing apoptosis, characterized by the loss of cell surface microvilli, chromatin condensation, nuclear fragmentation and caspase-3 activation (31). Therefore, the possible side effects of guaiazulene-3-carboxylate derivatives such as neurotoxicity and keratinocyte toxicity should be evaluated.
In conclusion, the present study demonstrated for the first time that two guaiazulene-3-carboxylate derivatives with alkoxy group at the end of sidechain [6, 7] showed highest TS against OSCC cell lines, among 12 related compounds, and induced subG1 and G2/M arrest. TS was correlated with chemical descriptors that explain the 3D shape, electric state, and ionization potential. These two compounds can be potential candidates of lead compound for manufacturing new type of anticancer drugs. Further study is ongoing by our team, regarding combination of [6] or [7] and anticancer drugs against the human OSCC HSC-2 cell line.
Acknowledgements
This work was partially supported by KAKENHI from the Japan Society for the Promotion of Science (JSPS) (16K11519).
Footnotes
Author's Contributions
M.T., S.N. performed all experiments. M.F. synthesized samples. N.O., K.B., Y.I. and H.S. performed the cell culture and apoptosis assays. J.N. and Y.U. performed the QSAR analysis. H.S., M.H. and H.W. wrote and reviewed the manuscript.
This article is freely accessible online.
Conflicts of Interest
The Authors confirm that there are no known conflicts of interest associated with this publication and there was no significant financial support for this work that could have influenced its outcome.
- Received May 9, 2020.
- Revision received June 7, 2020.
- Accepted June 24, 2020.
- Copyright© 2020, International Institute of Anticancer Research (Dr. George J. Delinasios), All rights reserved