Introduction
Phytochemicals are natural molecules found in many foods and medicinal plants, which play an important role in the prevention and treatment of chronic diseases. Because of their anti-inflammatory, antioxidant and anticancer effects, phytochemicals are becoming increasingly accepted in Western countries1. Some of the most studied phytochemicals are genistein, resveratrol, epigallocatechin gallate, and curcumin2. It has been proposed that the implementation of these phytochemicals as adjuvants in the treatment of cancer could improve the efficacy of chemotherapy3. Therefore, their potential effectiveness against different cancers is being evaluated in clinical trials (http://www.clinicaltrials.gov/). Furthermore, there are other natural molecules that are already used in humans for the treatment of other chronic diseases and whose actions could also improve the treatments by conventional chemotherapy.
Daphnetin (7,8-dihydroxycoumarin) is a secondary metabolite of plants used in Traditional Chinese Medicine for pain and rheumatoid arthritis4,5. Its anti-inflammatory actions occur mainly through the modulation of the immune system by downregulating the activation of NF-kB and other signaling pathways, which suppress the production of many pro-inflammatory cytokines6-9. In addition, daphnetin also has antioxidant10, antimicrobial11, antimalarial12 and antiangiogenic properties13.
Among simple coumarins, this compound has the greatest kinases inhibitory activity14, which inhibits several mitogenic pathways and induces an important anti-proliferative effect in some tumor cell lines15. Its kinase inhibitory activity is consistent with the reduction of cyclin D1 and the cell cycle inhibition in S-phase in Michigan Cancer Foundation (MCF)-7 human breast carcinoma cells16.
Daphnetin induces apoptosis in a concentration-dependent manner by inhibiting the anti-apoptotic Akt/NF-κB pathways, which produces upregulation of the pro-apoptotic caspase-3 in A549 human lung adenocarcinoma cells17.
Daphnetin also activates p38 mitogen-activated protein kinase in concentration- and time-dependent manner in the A498 human kidney adenocarcinoma cell line. That correlates with the expression of cellular differentiation markers CK18 and CK8. In addition to its greater cytostatic activity, the following factors contribute to making daphnetin a promising compound to be evaluated as an anticancer agent: (a) it is not mutagenic; (b) it does not intercalate DNA, but rather inhibits its synthesis; (c) it is not a substrate for glycoprotein P, and therefore its anti-proliferative effect will not be affected by the phenotype of multiple drug resistance18.
In contrast, Kimura et al.19 did not observe the anti-proliferative or antitumor effect of daphnetin in osteosarcoma LM8 cells (in vitro) and a highly metastatic model in LM8-bearing mice (in vivo).
To clarify the anticancer effectiveness of daphnetin, the aim of the present work was to evaluate more extensively the in vitro anti-proliferative effect of daphnetin in tumor cell lines not yet studied at this respect, and in addition, to evaluate its in vivo antitumor effect in four different types of murine tumors.
Here, we present that based on the calculated inhibitory concentrations 50 (IC50)s, daphnetin was most effective in B16 murine melanoma cells followed by mitoxantrone (MXT) murine breast adenocarcinoma cells and C26 murine colon carcinoma cells. Regarding the in vitro potency of daphnetin, a correlation was observed with the in vivo experiments. The B16 tumors were the most sensitive to daphnetin followed by MXT tumors, S-180 murine fibrosarcoma tumors, and C26 tumors.
Materials and methods
Compounds
Daphnetin (7,8-dihydroxycoumarin), dimethyl sulfoxide (DMSO), absolute ethanol, and (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide [MTT]) were commercially supplied by Sigma-Aldrich (St. Louis, MO, USA).
Cell lines and tumors
B16 murine melanoma cell line, MXT murine breast adenocarcinoma cell line, and C26 murine colon carcinoma cell lines were purchased from the American Type Culture Collection (Manassas, VA, USA). MXT cells were routinely cultivated at 37°C in humidity, with 5% CO2 in Roswell Park Memorial Institute-1640 medium, supplemented with 10% (v/v) fetal bovine serum, 1% (v/v) pyruvate, and a 1% (v/v) antibiotic-antimycotic mix (penicillin G sodium, streptomycin sulfate and amphotericin B). B16 melanoma cells and C26 cells were cultivated in Dulbecco's Modified Eagle's Medium supplemented as above. S180 sarcoma was obtained from the Chester Beatty Cancer Research Institute, London, UK.
Cytostatic MTT assay
The cytostatic effect of compound tested on the tumor cells was estimated using the microculture MTT assay. The assay is based on the reduction of soluble tetrazolium salt by mitochondria of viable cells. The reduced product, an insoluble purple-colored formazan, was dissolved in DMSO and measured spectrophotometrically (570 nm). Under the experimental conditions of this study, the amount of formazan was proportional to the number of viable cells. Cells (2 × 103) were seeded in each well of a 96 well microplate in a 200 µL of medium and after overnight incubation, the medium was replaced with fresh media containing the corresponding concentration of daphnetin (10, 20, 40, 80, 160, and 320 µM). Ethanol was used as a solvent, and its maximal concentration in the medium was 0.5% v/v. After 72-h exposure, the percentage of proliferative inhibition of treated cells was estimated against the solvent-treated control cells (P% = [T/C] × 100). P% = proliferation percentage; T = absorbance of treated cells, C = absorbance of control cells. IC50 was calculated from the least square concentration-response regressions.
Animals
Female inbred BDF1 (for MXT and S180 tumors), C57BL/6 (for B16 tumor), and BALB/c (for C26 tumors) mice (8 weeks old) from a specified pathogen free breeding of the Department of Experimental Pharmacology, National Institute of Oncology (Budapest, Hungary) weighing 22-24 g were used for these experiments. The animals were fed with a sterilized standard diet (Biofarm, Budapest) and had access to tap water ad libitum. They were kept in Makrolon cages at 23-25°C (40-50% humidity), with a lighting regimen of 12 h/12 h light/dark. The animals used in these studies were cared for according to the "Guiding Principles for the Care and Use of Animals" based on the Helsinki Declaration and which were approved by the local ethical committee (license number: PE/001/2574-6/2015). In our experiments, we utilized seven mice per group.
Transplantation of the tumors
An optimal fragment (2 × 2 × 3 mm) of S180 sarcoma, MXT breast adenocarcinoma, or C26 colon carcinoma tumor/mouse were transplanted subcutaneously (s. c.) into the intrascapular region of the mice20. The animals were anesthetized by i.p. injection of 20 mg/kg ketamine (Rationpharm, Ulm, Germany) and 12.5 mg/kg xylazine (Rompun, Bayer HealthCare, Leverkusen, Germany). B16 melanoma cells (6 × 105/mouse) were inoculated into the intrascapular region of the mice. Treatment with daphnetin started after development of the tumor (on 7th day). The animals were distributed among groups according to a balanced design based on initial tumor volume (n = 7 animals per group in each experiment), and groups were assigned randomly to treatments.
In vivo treatment conditions, doses, and evaluation.
Every day, before administration, fresh dilutions were prepared diluting daphnetin in DMSO and then in distilled water at 37°C (the final concentration of DMSO was 4% v/v). On the basis of our previous experiments, daphnetin was administrated i.p. at doses of 10, 20 and 40 mg/kg and the mice were treated for 14 days. Ratio of the volume/body weight was 0.1 ml/10 g. In all cases, mice of the control group have received water with DMSO at 4% (v/v). The animals were weighed and the tumor volumes were measured with a micro caliper on every 2nd or 3rd days. The tumor volume was calculated with the following formula: V = (π/6) × L/D2 (V: tumor volume, L: longest diameter, D: diameter perpendicular to L). Tumor volume measurements were continued until day 23 for tumors B16 and until day 18 for the other tumors. The results were expressed in means ± standard error mean (SEM).
Statistical analysis
Statistical significance among groups was analyzed employing one-way analysis of variance (ANOVA). The significance of the differences among data of the control and treated groups of the in vitro cell proliferation assays and the in vivo antitumor assays were estimated by Dunn's or Dunnett's method, as required. The analysis was performed using the SigmaStat 3.1 program, Systat. The results were expressed in means ± SEM. Values of p < 0.05 were considered statistically significant. The in vitro data are representative of at least four independent experiments.
Results
In vitro anti-proliferative effect of daphnetin
In accordance with our previous works, at concentrations lower than 160 µM, although some small inhibitory effects were observed in all cell lines after 24- or 48-h exposure, the anti-proliferative effect became significant and concentration-dependent only after 72 h of exposure.
In all cases, at 320 µM concentration, daphnetin produced cytotoxicity which was confirmed by Trypan blue exclusion (data not shown), but in the case of B16 and MXT cells the cytotoxicity become evident even at 160 µM.
All cell lines were inhibited by daphnetin at similar ranges of concentration, as the IC50 were in the range between 54 and 108 µM. However, some cell lines were more sensitive than others (Fig. 1). B16 cells were the most sensitive to daphnetin (IC50 = 54 ± 2.8 µM) and the differences observed between the treated cells and control cells were statistically significant from the concentration of 20 µM. In contrast, in MXT cells (IC50 = 74 ± 6.4 µM) and in C26 cells (IC50 = 108 ± 7.3 µM) were less sensitive to compound, because their anti-proliferative effect began to be statistically significant only at concentration of 80 µM.
In vivo antitumor effect of daphnetin
The antitumor activity of daphnetin in four different tumor types over time is shown in figure 2. The percentage of tumor growth produced by daphnetin at different doses compared to the control group in the last evaluation day is shown in table 1.
Tumor type | Dose (mg/kg) | Dose (µmol/kg) | Treatment schedule | Tumor volume (cm3 ± SEM) | T/Cx100 (%) | TGI (%) | Evaluation daya |
---|---|---|---|---|---|---|---|
B16 melanom | 10 | 56 | 14 x qd | 2.7 ± 0.47* | 70 | 30 | 23 |
20 | 112 | 14 x qd | 2.2 ± 0.20* | 56 | 44 | 23 | |
40 | 224 | 14 x qd | 2.0 ± 0.31* | 52 | 48 | 23 | |
control | 14 x qd | 3.9 ± 0.51 | 23 | ||||
MXT breast adenocarcinoma | 10 | 56 | 14 x qd | 2.8 ± 0.12* | 71 | 29 | 18 |
20 | 112 | 14 x qd | 2.7 ± 0.26* | 67 | 33 | 18 | |
40 | 224 | 14 x qd | 2.4 ± 0.37* | 60 | 40 | 18 | |
control | 14 x qd | 3.9 ± 0.54 | 18 | ||||
S180 Sarcoma | 10 | 56 | 14 x qd | 5.7 ± 0.37 | 88 | 12 | 18 |
20 | 112 | 14 x qd | 5.1 ± 0.27 | 80 | 20 | 18 | |
40 | 224 | 14 x qd | 4.3 ± 0.28* | 67 | 33 | 18 | |
control | 14 x qd | 6.4 ± 0.65 | 18 | ||||
C-26 colon carcinoma | 10 | 56 | 14 x qd | 5.2 ± 0.33 | 87 | 13 | 18 |
20 | 112 | 14 x qd | 5.5 ± 0.39 | 93 | 7 | 18 | |
40 | 224 | 14 x qd | 4.8 ± 0.62 | 80 | 20 | 18 | |
control | 14 x qd | 6.0 ± 0.42 | 18 |
aThe day in which the first death was observed in the control group. TGI = Tumor growth inhibition. qd = each day.
*= p < 0.05
B16 MELANOMA TUMOR
A statistically significant reduction of the tumor volume (approximately 35%) was observed at day 16 and the magnitude of the antitumor effect was increased as time progressed. In the last evaluation day, the dose of 40 mg/kg produced the best response with 48 % of inhibition (p < 0.05).
MXT BREAST ADENOCARCINOMA TUMOR
A significant tumor inhibition of approximately 35% was observed at day 11; however, the magnitudes of the effects were similar at different days. The best response was observed at dose of 40 mg/kg with 40 % of inhibition (p < 0.05).
S180 SARCOMA TUMOR
The antitumor effect was observed from day 14 and a clear relation dose-dependent response was observed each day. The best response of daphnetin was observed at dose of 40 mg/kg with 33% inhibition (p <0.05).
C26 COLON CARCINOMA
At day 11, all concentrations produced a meaningful antitumor effect (p < 0.05) of approximately 50 % of inhibition in respect to the control group. On the last measurement day, the differences between treated and control were approximately 15%. The best effect was observed at dose of 40 mg/kg with 20% of inhibition (p < 0.05).
Discussion
Among simple coumarins, esculetin (6,7-dihydroxycoumarin) is one of the most studied and it has been proposed as a potential anticancer agent21. Recently, Kimura et al.19 reported that esculetin inhibited the proliferation of osteosarcoma cells LM8 at 12 and 24 h of exposure, whereas any effect of daphnetin was not observed. However, it has been widely reported that the anti-proliferative effect of coumarin derivatives is dependent on both time and concentration and they are considerably more active in leukemia cell lines than in the cell lines derived from epithelial tumors22.
It is not clear why Kimura et al. did not observe the anti-proliferative effect of daphnetin. In contrast with their results, in our previous work, we have reported that the effect of coumarins became evident only after exposure for 72 h and daphnetin has a greater anti-proliferative effect than esculetin in MCF-7 cell line16. The results of the present paper agree with our previous findings as well as with the other authors' in other cell lines17,18. According to the estimated IC50s, daphnetin was more active in B16 cells, followed by MXT cells and C26 cells.
Our in vivo results demonstrated the antitumor effect of daphnetin in four different types of mouse tumors. Although the antitumor effect of daphnetin has different latency and magnitude in each mouse model, the best response was observed at the concentration of 40 mg/kg of the compound in all cases. Based on the magnitude of the effect on the last evaluation day, the sensitivity of the tumors to daphnetin was the following: B16 melanoma > MXT breast adenocarcinoma > S180 sarcoma > C26 colon carcinoma.
Kimura et al.19 did not observe the antitumor effect of daphnetin in osteosarcoma LM8-bearing mice at the concentration of 3 mg/kg and 10 mg/kg. One part of our results is in agreement with this report, because at a 10 mg/kg dose, we have also observed no effect in S180 sarcoma. However, in the B16 melanoma and MXT breast adenocarcinoma a significant antitumor effect were observed, this effect became more evident at higher concentrations. In addition, in the case of hormone dependent cancers such as breast cancer, daphnetin could potentially be safer because it does not have the estrogenic effect observed in esculetin16.
In accordance with the method of body surface area for dose translation from animal to human23, the dose of 40 mg/kg of daphnetin in mice corresponds to a human equivalent dose of 3.24 mg/kg, which equates to a 227 mg dose of daphnetin for a 70 kg person. The oral tablet commercially available for human consumption contains 300 mg of daphnetin and the usual clinical dose range for daphnetin was 450 mg 3 times a day6.
Our results suggest that daphnetin could be beneficial to improving the efficacy of chemotherapy, as has been observed with other phytochemicals (http://www.clinicaltrials.gov/).
Daphnetin (7,8-dihydroxycoumarin) is a natural coumarin that has been developed successfully as an oral medicine for the clinical treatment of traumatic injury and rheumatoid arthritis in China since the 1980s. Unlike traditional anti-inflammatory agents (NSAIDs and glucocorticoids), its chronic use does not produce significant adverse effects, making it safer in humans.
In the present work, the in vivo antitumor activity of daphnetin was demonstrated in four different types of mouse tumor and its in vitro anti-proliferative effect was corroborated in three tumor cell lines. Regarding the in vitro potency of daphnetin, a correlation was observed with the in vivo experiments. However, the possible changes in the expression of genes involved in antitumoral effect of daphnetin must be evaluated in future studies. The pleiotropic actions and low toxicity of this molecule represent a great advantage for its possible inclusion as adjuvant agent in human protocols to improve the efficacy of chemotherapy.