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Article

In Vitro Cytotoxicity Evaluation of Plastoquinone Analogues against Colorectal and Breast Cancers along with In Silico Insights

1
Department of Drug Discovery, Science Farm Ltd., Kumamoto 862-0976, Japan
2
Medicinal and Biological Chemistry Science Farm Joint Research Laboratory, Faculty of Life Sciences, Kumamoto University, Kumamoto 862-0973, Japan
3
Department of Molecular Biology and Genetics, Koc University, 34450 Istanbul, Turkey
4
Department of Pharmaceutical Chemistry, Faculty of Pharmacy, Anadolu University, 26470 Eskisehir, Turkey
5
Department of Chemistry, Faculty of Science, Istanbul University, Fatih, 34126 Istanbul, Turkey
6
Chemistry Department, Gebze Technical University, Gebze, 41400 Kocaeli, Turkey
7
Department of Chemistry, Faculty of Engineering, Istanbul University-Cerrahpasa, Avcılar, 34320 Istanbul, Turkey
*
Authors to whom correspondence should be addressed.
Pharmaceuticals 2022, 15(10), 1266; https://doi.org/10.3390/ph15101266
Submission received: 9 September 2022 / Revised: 28 September 2022 / Accepted: 4 October 2022 / Published: 14 October 2022
(This article belongs to the Special Issue Novel Anti-proliferative Agents)

Abstract

:
Colorectal cancer (CRC) and breast cancer are leading causes of death globally, due to significant challenges in detection and management. The late-stage diagnosis and treatment failures require the discovery of potential anticancer agents to achieve a satisfactory therapeutic effect. We have previously reported a series of plastoquinone analogues to understand their cytotoxic profile. Among these derivatives, three of them (AQ-11, AQ-12, and AQ-15) were selected by the National Cancer Institute (NCI) to evaluate their in vitro antiproliferative activity against a panel of 60 human tumor cell lines. AQ-12 exhibited significant antiproliferative activity against HCT-116 CRC and MCF-7 breast cancer cells at a single dose and further five doses. MTT assay was also performed for AQ-12 at different concentrations against these two cells, implying that AQ-12 exerted notable cytotoxicity toward HCT-116 (IC50 = 5.11 ± 2.14 μM) and MCF-7 (IC50 = 6.06 ± 3.09 μM) cells in comparison with cisplatin (IC50 = 23.68 ± 6.81 μM and 19.67 ± 5.94 μM, respectively). This compound also augmented apoptosis in HCT-116 (62.30%) and MCF-7 (64.60%) cells comparable to cisplatin (67.30% and 78.80%, respectively). Molecular docking studies showed that AQ-12 bound to DNA, forming hydrogen bonding through the quinone scaffold. In silico pharmacokinetic determinants indicated that AQ-12 demonstrated drug-likeness with a remarkable pharmacokinetic profile for future mechanistic anti-CRC and anti-breast cancer activity studies.

1. Introduction

Colorectal cancer (CRC), the third most common cancer type and the fourth leading cause of cancer-related death, comprises nearly 10% of all annually diagnosed tumors across the world [1,2,3,4]. Male gender, old age, dietary habits, and environmental factors affect the pathogenesis of CRC as well as the genetic background [5]. In spite of advancements in CRC screening and treatment options such as surgery, radiotherapy, local ablative therapy, chemotherapy, targeted therapy, and immunotherapy, most of cases in particular diagnosed at an advanced stage with metastases, result in subsequent cancer-related deaths. The size, stage, and metastasis of tumor whether the therapy will be curative or palliative. Among CRC treatment options, chemotherapy incorporates single-agent therapy (primarily fluoropyrimidine, oxaliplatin, irinotecan, and capecitabine) or combined regimens of these agents. Targeted therapy is another approach, which has been reported to extend survival of patients with CRC. However, the resistance and toxicity problems restrict the success of the therapy. Therefore, there is an urgency to find more effective and safer drugs [2,6].
The history of breast cancer was shown to be a risk factor for CRC in several studies, implying low or high relative risks. These risks were considered due to the common etiologic factors associated with the development of both cancers and administration of antihormone drugs in breast cancer treatment, which alter sex hormone levels and contribute to the development of CRC [7,8,9,10,11]. New efficacious therapeutic options have been also developed for the battle with breast cancer related to its clinical stage, histopathologic properties, and biomarker profiling. These options include traditional, personalized, neoadjuvant, and targeted therapies. The treatment still remains limited mainly in the breast cancer metastasis owing to heterogeneity of the disease, acquired and primary resistance, and toxicity problems during the treatment. New agents should be also developed to overcome or prevent these problems in breast cancer treatment [12,13,14].
Much effort to design and discover efficient and safe drug candidates led to identifying several hit compounds and analogues of natural products. In silico analyses were exploited to improve molecules with greater potential efficacy to cope with the adverse toxicological outcomes by emphasizing physicochemical parameters [15]. In addition, the study of the structure–activity relationship (SAR) has provided valuable information on the design of safe drug candidates with continuity about how structural changes can improve potency and bioavailability [16].
1,4-Quinones have been explored as attractive anticancer hit molecules to their multitargeted mode of actions [17,18,19,20,21,22]. In this field, a small library of amino-quinones based on bioactive natural products (fifty Plastoquinone (PQ) [23,24,25] and thirty-four LY83583 analogues [26,27]) that specifically target leukemia cancer cell lines, in the period 2017–2021, was generated for the purpose of discovering the SAR of various substituents in aminoquinones for their further mechanistic anticancer potential. Knowing that the PQ analogues are active toward some cancer cell lines, and considering our previous findings that demonstrated greater activity by the introduction of a chlorine atom in the quinone moiety, we also designed and evaluated the effect on inhibitory activity against some cancer cell lines caused by replacing the chlorine with a bromine atom in PQ analogues [28]. Regarding all PQ analogues, including halogenated (brominated and chlorinated) and non-halogenated analogues, a major breakthrough was the discovery of AQ-11, AQ-12, and AQ-15 [25], as illustrated in Figure 1. These analogues showed consistent growth-inhibitory activities with low IC50 value against K562 human chronic myelogenous leukemia (CML) cell line and low toxicity toward human peripheral blood mononuclear cells (PBMCs) (healthy) (Table 1) [25].
Considering the encouraging results of the target PQ analogues, further studies were assessed aiming at the identification of new analogues for their antiproliferative activity against HCT-116 human CRC and MCF-7 human breast cancer cell lines. In addition, apoptosis-inducing activity in both cell lines, DNA binding characteristics, and a number of pharmacokinetic descriptors of the most effective anticancer analogue were examined.

2. Results

2.1. Anticancer Activity Assessment

2.1.1. In Vitro Screening of Tumor Cell Growth Inhibition at One Dose

Continuing our efforts on anticancer drug discovery, most effective PQ analogues from our previous study [25] were submitted to the National Cancer Institute (NCI) of Bethesda within the Developmental Therapeutics Program (DTP) for their in vitro anticancer activity with the protocol of the Drug Evaluation Branch, NCI. A single dose (10 µM) of all tested PQ analogues was used in the panel of 60 human cancer cell lines, including nine tumor subpanels, namely: leukemia, lung, CRC, central nervous system (CNS), melanoma, ovarian, renal, prostate, and breast cancer cell lines [29,30,31]. The in vitro growth inhibition and lethality were ascertained as percentages as follows: growth inhibition (G%) (values between 0 and 100) and lethality (values less than 0). Herein, three PQ analogues (AQ-11, NCI: D-827199/1; AQ-12, NCI: D-827200/1; and AQ-15, NCI: D-827201/1) were selected by the NCI for in vitro disease-oriented human-cell-screening panel assay.
The results of each tested PQ analogue were reported in terms of percent growth inhibition (GI% = 100 − G%) and lethality [32] (Table 2) and were also depicted as bars in the single-dose mean graphs (Supplementary Materials, Figures S1–S3). Overall, consistent with the previous data, PQ analogues showed the most notable anticancer activity against leukemia cancer cell lines. AQ-11 and AQ-15 were found ineffective against the other cancer cell lines except for significant anticancer effects of AQ-11 on MDA-MB-231 breast cancer cell line with 84.65% inhibition percent. On the other hand, NCI-60 data suggested that AQ-12 revealed prominent anticancer activity toward the subpanel cell line of CRC (HCT-116 cells, 66.14% inhibition; SW-620 cells, 82.93% inhibition) and breast cancer (MCF-7 cells, 64.64% inhibition; MDA-MB-231 cells, 81.04% inhibition). Additionally, this analogue also showed promising anticancer effects against NCI-H522 lung cancer cells.

2.1.2. In Vitro Full-Panel Five-Dose 60-Cell Lines Assay

From the single-dose assay data from the NCI screen, AQ-12 was selected as a lead PQ analogue because of its pronounced anticancer selectivity compared with other PQ analogues. AQ-12 exhibited the threshold inhibition criterion in the single-dose screening and was qualified for the evaluation in the full-panel five-dose in vitro anticancer screening at 10-fold dilutions in the range 0.01–100 µM. Three response parameters (50% cell growth inhibition (GI50) (growth inhibitory activity), total cell growth inhibition (TGI) (cytostatic activity), and 50% cell death (LC50) (cytotoxic activity)) [33] were used to establish biological potential of the tested AQ-12. The GI50 is an indicative concentration at 50% growth inhibitory activity, whereas TGI reflects total growth inhibition, and LC50 is an indicative concentration at which 50% of cancer cells are killed. In this assay, three parameters were calculated for each cell line from log concentration versus percent growth inhibition curves on nine panels of human cancer cell lines to generate dose response curves [31,34]. GI50 is the concentration of the test drug where 100 × (T − T0)/(C − T0) = 50. Herein, T explains the optical density of the test well after a 48 h period of treatment with the test drug; T0 explains the optical density at time zero; ultimately, C is the control (nondrug) optical density. The “50” is called the GI50PRCNT, a T/C-like parameter that can have values from +100 to −100. The TGI is the concentration of test drug where 100 × (T − T0)/(C − T0) = 0. LC50 is the concentration of the drug where 100 × (T − T0)/T0 = −50 [31].
The GI50, TGI, and LC50 (in µM) values against subpanel cell lines are illustrated in Table 3, indicating that AQ-12 displays high anticancer activity against all leukemia cell lines with GI50 values ranging from 1.32 to 2.59 µM. This compound also demonstrated superior cytotoxic activity against HL-60(TB) and RPMI-8226 cell lines with TGI values 6.54 and 7.32 µM, respectively. On the other hand, LC50 values were more than 100 µM against the entire panel of cancer cell lines. Moderate cytotoxicity was recorded against non-small cell lung cancer cells, except for EKVX cell line with a GI50 value of 1.49 µM, HOP-92 cell line with a GI50 value of 1.51 µM, and NCI-H522 cell line with a GI50 value of 2.24 µM. Moreover, good TGI values ranging from 3.04 to 32.20 µM were obtained against lung cancer cell lines. Additionally, AQ-12 showed high activity with GI50 values ranging from 1.93 to 2.20 µM against some CRC cell lines (HCT-116 cells GI50 = 1.93 µM; HCT-15 cells GI50 = 2.20 µM; SW-620 cells GI50 = 2.09 µM). It also possessed notable TGI values against these three CRC cell lines in the range of 3.99–5.05 µM. Moderate cytotoxicity was recorded against CNS cancer with GI50 values ranging from 4.45 µM to 6.55 µM against most of the tested cancer cell lines. Moreover, important TGI values ranging from 13.60 to 28.60 µM were detected against CNS cell lines. AQ-12 demonstrated pronounced cytotoxicity with GI50 values ranging from 3.36 to 9.96 µM, except for three cell lines (LOX IMVI, MALME-3M, and UACC-257 cells). Concerning the TGI values of AQ-12, the most prominent TGI value was observed with the LOX IMVI melanoma cell line (TGI = 3.32 µM). Furthermore, this analogue demonstrated notable anticancer activity against the entire panel of ovarian cancer cell lines with GI50 values ranging from 1.30 to 3.16 µM, as shown in (Table 3). Its TGI values ranged from 2.97 to 50.70 µM against all tested cancer cell lines. Finally, its LC50 values were found as 7.15, 5.58, and 8.61 µM against IGROV1, OVCAR-4, and OVCAR-5 cell lines; whereas, with regard to the lethality (LC50 values), AQ-12 showed values exceeding 100 µM toward the other panel cancer cell lines. This analogue exhibited remarkable anticancer activity against the renal, prostate, and breast cancer cell lines with GI50 values ranging from 1.17 to 2.67 µM. Accepted pronounced TGI values were recorded against ACHN renal (TGI = 3.19 µM), RXF 393 renal (TGI = 2.85 µM), UO-31 renal (TGI = 4.18 µM), MCF-7 breast (TGI = 3.79 µM), MDA-MB-231 breast (TGI = 3.28 µM), T-47D breast (TGI = 3.60 µM), and MDA-MB-468 breast (TGI = 2.94 µM) cancer cell lines, together with PC-3 prostate (TGI = 12.80 µM) cancer cell line. All the five-dose response curves of AQ-12 against the full panel of 60 human cancer cell lines are presented in Figure 2 and Table 3, which include nine tumor subpanels, namely: leukemia, melanoma, CRC, lung, CNS, ovarian, renal, prostate, and breast cancer cell lines.

2.1.3. Cell Viability Assay on CRC and Breast Cancer Cells

AQ-12 was found to possess a superior sensitivity profile toward HCT-116 CRC and MCF-7 breast cancer cell lines with a higher growth inhibitory percent compared to AQ-11 and AQ-15. AQ-12 also displayed sensitivity toward MDA-MB-468 breast and NCI-H522 lung cancer cell lines. However, AQ-11 also presented significant growth inhibitory effects on MDA-MB-468 breast cancer cells, restricting the selectivity of AQ-12 against this cell line, and GI50, TGI, and LC50 parameters were found very high against NCI-H522 lung cancer cells. Satisfactory results obtained from both single and five doses of NCI-60 screening toward HCT-116 CRC and MCF-7 breast cancer cells encouraged us to further investigate the anticancer effects of AQ-12 against these two cell lines by MTT (3-(4,5-dimethyl-2-thiazolyl)-2,5-diphenyltetrazolium bromide) assay at five dose concentrations (1, 3, 10, 30, and 100 μM) in comparison with cisplatin, the reference agent.
Cisplatin, a metallic coordination compound leading to DNA damage and subsequently apoptosis induction in cancer cells, is one of the most important chemotherapeutic agents, which has been approved for the treatment of different fatal cancer types, including CRC and breast cancer [35,36,37,38,39,40,41].
Results indicated that AQ-12 showed cytotoxic effects on HCT-116 and MCF-7 cells with IC50 values of 5.11 ± 2.14 μM and 6.06 ± 3.09 μM when compared with cisplatin (IC50 = 23.68 ± 6.81 μM for HCT-116 cells and 19.67 ± 5.94 μM for MCF-7 cells). The definite decline in percentage of viable cells was detected between 3 and 10 μM after AQ-12 exposure while a similar decline was observed between 10 and 30 μM after cisplatin implementation (Figure 3, Table 4).

2.1.4. Cell Death Investigation

Based on significant anticancer activity results of AQ-12 on HCT-116 and MCF-7 cells, we also further investigated potential effects of this compound on apoptosis in both cell lines using the annexin V/ethidium homodimer III staining procedure, which was observed by fluorescence microscopy, indicating apoptosis, necrosis or late apoptosis, and necrosis with green, yellow, and red staining, respectively (Figure 4A). AQ-12 induced apoptotic behavior of HCT-116 cells (62.30%) in a similar manner with cisplatin (67.30%). This compound exhibited 21.30% late apoptotic/necrotic and 16.40% necrotic effects in HCT-116 cells compared to cisplatin (12.30% and 20.40%, respectively) (Figure 4B). The difference of apoptosis induction between AQ-12 and cisplatin treatment in HCT-116 cells was found not significant, contrary to that of MCF-7 cells, which was found significant (Figure 4C). AQ-12 enhanced apoptosis in MCF-7 cells significantly with 64.60% when compared with cisplatin (78.80%). AQ-12-treated MCF-7 cells underwent late apoptosis/necrosis and necrosis with 25.30% and 10.10%, respectively when compared with cisplatin (16.40% and 4.80%, respectively) (Figure 4B,C).

2.2. In Silico Studies

2.2.1. Molecular Docking

In our previous studies, we manifested that PQ analogues were able to bind DNA significantly [26,27,42]. In this study, the DNA binding effects of AQ-11, AQ-12, and AQ-15 were also searched with molecular docking studies in the minor groove of the double helix of DNA (PDB ID: 2GWA) [43] via Maestro software [44]. Results corresponded to previous DNA cleavage outcomes, implying that AQ-15 showed the most promising DNA binding potential through a key π-π interaction between DG-4 with its 4-methyl substituent. However, AQ-11 and AQ-12 displayed less binding capacity compared to AQ-15, forming hydrogen bonding with DT-5 and DG-4, respectively (Figure 5A,B). The docking scores were determined as −4.641 kcal/mol, −5.087 kcal/mol, and −5.097 kcal/mol for AQ-11, AQ-12, and AQ-15, indicating higher binding capacity of AQ-15 compared to AQ-11 and AQ-12.

2.2.2. Estimation of Pharmacokinetic Parameters

AQ-12 was profiled in silico for various pharmacokinetic properties of interest such as octanol/water partition coefficient (QPlogPo/w), aqueous solubility (QPlogS), human serum albumin binding (QPlogKhsa), brain/blood partition coefficient (QPlogBB), and compliance to Lipinski’s rule of five and Jorgensen’s rule of three using the QikProp algorithm [45]. We also checked the in silico inhibitory potential of AQ-12 on several cytochrome P450 (CYP) enzymes such as CYP1A2, CYP2C19, CYP2C9, CYP2D6, and CYP3A4, along with the evaluation of bioavailability and passive gastrointestinal absorption and brain penetration using the SwissADME web service [46,47].
AQ-12 represented a remarkable pharmacokinetic profile in which all the descriptors were found in appropriate ranges: QPlogPo/w, QPlogS, QPlogKhsa, and QPlogBB were computed with the values of 3.513, −5.035, 0.197, and 0.140, respectively, within the limits (−2 to 6.5, −6.5 to 0.5, −1.5 to 1.5, and −3 to 1.2, respectively). Additionally, AQ-12 revealed robust human oral absorption (100%) and was found to possess of all the conditions of drug-likeness characters without any violation of Lipinski’s rule of five and Jorgensen’s rule of three.
The pink region of bioavailability radar (Figure 6) identifies the values of saturation (INSATU), size (SIZE), polarity (POLAR), solubility (INSOLU), lipophilicity (LIPO), and flexibility (FLEX) for oral bioavailability. AQ-12 was found only beyond the saturation value for other values it was participating in, as shown in the pink area. AQ-12 matched with CYP1A2, CYP2C19, CYP2C9, and CYP3A4 inhibition, apart from CYP2D6 inhibition, indicating that AQ-12 could cause possible drug–drug or drug–food interactions. The boiled-egg model (Figure 7) explains whether a molecule has properties for the passive gastrointestinal absorption and blood–brain barrier (BBB) permeation. According to the results, AQ-12 was predicted as brain-penetrant (in the yellow area) and not a substrate for P-glycoprotein (red dot), which decreased the possibility of its resistance by tumor cell lines through efflux [47,48,49,50].

3. Discussion

Worldwide, CRC and breast cancer are prevalent and deadly cancers. The complete cure for both cancers is still far from success, albeit to increase overall survival rate obtained with new therapeutic options. Therefore, the discovery of new and better therapeutics is still needed [51,52]. In spite of numerous efforts in the search for more effective anticancer agents, quinone moiety still remains one of the most versatile members against cancer cell lines in drug discovery [53,54].
In our previous studies, we also reported the significant outcomes of quinone derivatives against CRC or breast cancer cell lines. We showed that compound PQ11, PQ analogue with N-phenylpiperazine (Figure 8), exhibited the most potent anticancer activity against MCF-7, MDA-MB-231, and UACC-2087 cell lines, with the IC50 values of 6.58, 16.66, and 38.52 μM [28]. In our recently published studies, we also confirmed anti-CRC and anti-breast cancer effects of PQ analogues. In the first study [42], the most significant cytotoxic effects were observed with PQ2, amino-1,4-benzoquinone (Figure 8), against HCT-116 CRC cells with an IC50 value of 4.97 ± 1.93 μM. In the latter one [55], compound ClPQ1, quinone-benzocaine hybrid molecule, (Figure 8) was found as the most effective anti-breast cancer agent against T47D and MCF-7 breast cancer cells, with IC50 values of 2.35 ± 0.30 and 6.53 ± 0.71 μM, respectively.
In the current work, PQ analogues (AQ-11, AQ-12, and AQ-15) were selected by the NCI in vitro disease-oriented antitumor screening to be evaluated for their anticancer effects. Testing of the PQ analogues against the NCI-60 cell line panel revealed valuable information on their inhibitory activity across a broad variety of human cancer cell lines. In particular, AQ-12 displayed potential growth inhibitory activity against HCT-116 and MCF-7 cell lines at a single dose and a super-sensitivity profile with low micromolar GI50, TGI, and LC50 values against both cell lines at five doses. These findings indicated that meta trifluoromethyl substitution of AQ-12 played an important role in its significant anti-CRC and anti-breast cancer activity when compared with the para methyl substitution of AQ-15 and non-substitution of AQ-11. Moreover, AQ-12 exerted similar cytotoxic effects against both cell lines in comparison with our aforementioned studies [28,42,55]. Current results once more confirmed that the presence of PQ moiety played an important role in anti-CRC and anti-breast cancer activity.
Genetically encoded programmed cell death (apoptosis) leads to elimination of cancer cells, and DNA degradation is one of the crucial indicators of apoptosis. Aberrant apoptotic activity can increase not only the pathogenesis of CRC and breast cancer, but also their resistance to current therapy options [56,57,58,59]. Regarding the anticancer efficacy of AQ-12 in CRC and breast cancer cells, it was ascertained that AQ-12 led to apoptosis in both cells with similar apoptotic pattern with PQ2 (Figure 8) [42].
Molecular docking studies were carried out for AQ-12 in order to discover its binding efficacy in the minor groove of the double helix of DNA (PDB ID: 2GWA). We previously showed that PQ analogues occupied this region with key interactions [26,27,42]. The 3,5-dimethyl phenyl [26] and benzodioxole [27] moieties were determined to be crucial in binding with DNA, forming π-π stacking interactions with DA-17 and DG-16, and DA-5 and DG-4, respectively. In other our previous study [27], the methoxy substitution was also found to be important for high interaction between PQ2 and DT-5 in the minor groove of DNA. In the current study, AQ-12 was found less capable of binding DNA compared to AQ-15, albeit to hydrogen bonding with DG-4 through quinone moiety. The trifluoromethyl substitution of AQ-12 played no significant role in binding with DNA. AQ-15 bound to DG-4 through its p-methyl moiety, forming π-π stacking interactions. The docking score with the lowest energy (high negative scores) was found to pertain to AQ-15, followed by AQ-12 and AQ-11, indicating their binding affinities. Compare to our previous studies, it can be concluded that CH3 substitution (−σ effect), OCH3 substitution (−σ effect), and (-CH2-O-CH2-) (−σ effect) [26,27,42] were found to increase the binding capacity of the tested compounds, whereas CF3 substitution (+σ effect) was not detected to contribute to binding capacity of AQ-12. The higher docking score and the binding capacity of p-methyl-substituted AQ-15 also complied with the previous data. This finding also suggested that the high apoptotic effect of AQ-12 might be independent from DNA cleavage-associated cell death.
Absorption, distribution, metabolism, and excretion (ADME) parameters of a drug molecule have an enormous impact for successful drug discovery. Some of these essential parameters were predicted in silico for AQ-12. Lipophilicity is crucial for absorption, which is the process of movement of a drug into the systemic circulation crossing the lipid bilayers of cell membranes. On the other hand, optimum water solubility is also necessary since the active ingredient must be dissolved in aqueous compartments to some extent before drug absorption. The human serum albumin binding is directly associated with the volume of distribution and half-life of drugs. The transition of drugs from blood into brain is particularly important for brain metastases of other cancer types. According to the results of the QikProp module, AQ-12 was endowed with drug-like properties. The outcomes of SwissADME web server signified that AQ-12 was predicted not orally bioavailable. This was due to the out-of-limits for saturation, as shown in the bioavailability chart, in which a molecule must be entirely included in the pink area. AQ-12 exerted inhibition against all tested CYP enzymes, except for CYP2D6, which had a higher risk for drug–drug interactions [60,61,62,63].

4. Materials and Methods

4.1. Chemistry

The synthesis and spectral analysis of AQ-11, AQ-12, and AQ-15 were performed previously [25].

4.2. Anticancer Activity Studies

4.2.1. In Vitro Single-Dose Anticancer Screening by NCI

The PQ analogues were submitted to NCI, Bethesda, USA, and screened based on the procedures of NCI; all compounds were investigated for their cancer cell growth inhibitory activity at 10 µM concentration against a wide range of cancer cell lines stemming from leukemia, melanoma, CRC, non-small cell lung, CNS, ovarian, renal, prostate, and breast cancers. Tested compounds were added to the microtiter culture plates followed by incubation for 48 h at 37 °C. SRB was used for end point detection. The percent of growth of the treated cells was observed compared to the untreated control cells. Data from one-dose experiments corresponded to the percentage growth at 10 μM [29,30,31,34,64].

4.2.2. In Vitro Five-Dose Anticancer Screening by NCI

Initial DMSO stock solution was carried out for serial 5 × 10-fold dilution before incubation at each individual concentration. AQ-12 was selected for a higher testing level by DTP-NCI to identify GI50, TGI, and LC50 for each cell line after generating a dose response curve from 5 different concentrations (0.01, 0.1, 1, 10, and 100 µM). The definite protocol for the latter assay was explained in detail previously. The cells were assayed by using the SRB method. The optical densities were measured by a plate reader and a microcomputer processed the optical densities into the special concentration parameters, as defined above [29,34,64,65].

4.2.3. Cell Culture, Drug Treatment, and MTT Assay

The HCT-116 cell line (provided by the RIKEN BRC through the National Bio-Resource Project of the MEXT/AMED, Japan (RCB2979)) and MCF-7 cell line (Precision Bioservices, Frederick, MD, USA) were incubated in Dulbecco’s modified Eagle’s medium (DMEM) (Wako Pure Chemical Industries, Osaka, Japan) and RPMI 1640 (Wako Pure Chemical Industries, Osaka, Japan), respectively. Ten percent fetal bovine serum (FBS) (Sigma Aldrich, St. Louis, MO, USA) and 89 μg/mL streptomycin (Meiji Seika Pharma, Tokyo, Japan) were added to total media (Wako Pure Chemical Industries) at 37 °C and 5% CO2 atmosphere. HCT-116 and MCF-7 cells were cultured for 48 h in a 24-well plate (Iwaki brand Asahi Glass Co., Chiba, Japan) at 4 × 104 cells/mL concentration [42]. The stock solution of AQ-12 and cisplatin in concentrations were prepared in DMSO (Wako Pure Chemical Industries, Osaka, Japan) (0.1 to 10 mM), and fresh culture medium was used for further dilution. The final DMSO concentration was set at 1% to prevent any effect of it on cell viability. MTT (Dojindo Molecular Technologies, Kumamoto, Japan) was used to examine the cytotoxic effects of AQ-12 and cisplatin, as previously indicated [66]. HCT-116 and MCF-7 cells were treated with AQ-12 and cisplatin at five dose concentrations (1, 3, 10, 30, and 100 μM) at 37 °C for 48 h, and then treated with MTT solution and incubated for 4 h. Eventually, 100 μL DMSO was added to each well following removal of supernatants. Infinite M1000 (Tecan, Mannedorf, Switzerland) was used for the analysis of the absorbance of the solution. All experiments were repeated three times, and IC50 values were calculated as the drug concentrations that diminished absorbance to 50% of control values.

4.2.4. Cell Death Analysis

The HCT-116 and MCF-7 cell lines were incubated with AQ-12 and cisplatin at IC50 concentration for 12 h before the apoptotic/necrotic/detection kit (PromoKine, Heidelberg, Germany) was applied, with some alterations to the manufacturer’s guidance [42]. HCT-116 and MCF-7 cells, treated with appropriate content including binding buffer and staining solution, were analyzed by an all-in-one fluorescence microscope, Biorevo Fluorescence BZ-9000 (Keyence, Osaka, Japan). Numbers of apoptotic, late apoptotic/necrotic, and necrotic cells were determined based on the staining with annexin V and ethidium homodimer III, as previously explained [66].

4.2.5. Statistical Analyses

All results were reported as means ± SD. One-way analysis of variance was used for the analysis of data. Differences were defined as significant at * p < 0.05, ** p < 0.01, and *** p < 0.001. GraphPad Prism7 (GraphPad Software, San Diego, CA, USA) was used for the determination of the IC50 values.

4.3. In Silico Studies

4.3.1. Molecular Docking

AQ-11, AQ-12, and AQ-15 were prepared with energy minimization by applying the OPLS_2005 force field at physiological pH using the LigPrep module. The crystallographic structure of DNA was downloaded from the PDB server (PDB ID: 2GWA) [43,44] and prepared for the docking assessment by the PrepWizard module of Maestro. Then, the determined grid by Grid Generation was used for molecular docking with Glide/XP docking procedures [26,27,42].

4.3.2. ADME Prediction

The pharmacokinetic determinants of AQ-12 were estimated by QikProp [45] and SwissADME web tool [46,47].

5. Conclusions

Our previous encouraging anticancer activity results obtained from PQ analogues guided us to analyze AQ-11, AQ-12, and AQ-15 for further effects toward a wide spectrum of cancer cells by NCI-60 in vitro screening. AQ-12 presented a promising growth inhibition in HCT-116 and MCF-7 cells at a single dose and submicromolar level anticancer activity at five doses. It was established that these two cell lines were found susceptible for further anticancer activity studies. The MTT assay outcomes also corresponded to notable anti-CRC and anti-breast cancer activity of AQ-12 at different concentrations compared to cisplatin. This compound also enhanced apoptosis in both cell lines. Taken together, AQ-12 could serve as a valuable lead molecule for CRC and breast cancer treatment with orally bioavailable favorable drug-like features.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/ph15101266/s1, Figure S1: One-dose mean graph of AQ-11 against different cancer cell lines based on Sulforhodamine B (SRB) assay at NCI at 10 µM concentration after 48 h; Figure S2: One-dose mean graph of AQ-12 against different cancer cell lines based on SRB assay at NCI at 10 µM concentration after 48 h; Figure S3: One-dose mean graph of AQ-15 against different cancer cell lines based on SRB assay at NCI at 10 µM concentration after 48 h.

Author Contributions

Conceptualization, H.C., B.S., M.F. and A.F.T.; methodology, H.C., B.S., N.B., M.Y., H.Y. and A.F.T.; software, H.C. and B.S.; validation, H.C. and B.S.; formal analysis, H.C. and B.S.; investigation, H.C., B.S., N.B., M.Y., H.Y. and A.F.T.; resources, H.T., M.O. and M.F.; data curation, H.C.; writing—original draft preparation, H.C., B.S. and A.F.T.; writing—review and editing, H.C., B.S., N.B., M.Y., H.Y., H.T., M.O., M.F. and A.F.T.; visualization, H.C. and B.S.; supervision, M.F. and A.F.T.; project administration, M.F. and A.F.T.; funding acquisition, A.F.T. All authors have read and agreed to the published version of the manuscript.

Funding

This work was financially supported by the Scientific Research Projects Coordination Unit of Istanbul University, grant number FBA-2016-20662. This publication has been produced benefiting from TUBITAK 2236 CoCirculation2, grant number 121C063. However, the entire responsibility of the publication belongs to the authors. The financial support received from TUBITAK does not mean that the content of the publication is approved in a scientific sense by TUBITAK.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors present their thanks to the National Cancer Institute (NCI), Bethesda, MD, USA, for carrying out the anticancer activity by the Developmental Therapeutics Program (DTP), Division of Cancer Treatment and Diagnosis, National Cancer Institute (http://dtp.cancer.gov, accessed on 21 October 2020). HCT-116 was provided by the RIKEN BRC.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Davies, R.J.; Miller, R.; Coleman, N. Colorectal cancer screening: Prospects for molecular stool analysis. Nat. Rev. Cancer 2005, 5, 199–209. [Google Scholar] [CrossRef] [PubMed]
  2. Dekker, E.; Tanis, P.J.; Vleugels, J.L.A.; Kasi, P.M.; Wallace, M.B. Colorectal cancer. Lancet 2019, 394, 1467–1480. [Google Scholar] [CrossRef]
  3. Dalal, N.; Jalandra, R.; Sharma, M.; Prakash, H.; Makharia, G.K.; Solanki, P.R.; Singh, R.; Kumar, A. Omics technologies for improved diagnosis and treatment of colorectal cancer: Technical advancement and major perspectives. Biomed. Pharmacother. 2020, 131, 110648. [Google Scholar] [CrossRef] [PubMed]
  4. La Vecchia, S.; Sebastián, C. Metabolic pathways regulating colorectal cancer initiation and progression. Semin. Cell Dev. Biol. 2020, 98, 63–70. [Google Scholar] [CrossRef]
  5. Jin, K.; Ren, C.; Liu, Y.; Lan, H.; Wang, Z. An update on colorectal cancer microenvironment, epigenetic and immunotherapy. Int. Immunopharmacol. 2020, 89 (Pt A), 107041. [Google Scholar] [CrossRef]
  6. Xie, Y.H.; Chen, Y.X.; Fang, J.Y. Comprehensive review of targeted therapy for colorectal cancer. Signal Transduct. Target. Ther. 2020, 5, 22. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  7. Howell, M.A. The association between colorectal cancer and breast cancer. J. Chronic Dis. 1976, 29, 243–261. [Google Scholar] [CrossRef]
  8. Newschaffer, C.J.; Topham, A.; Herzberg, T.; Weiner, S.; Weinberg, D.S. Risk of colorectal cancer after breast cancer. Lancet 2001, 357, 837–840. [Google Scholar] [CrossRef]
  9. Kmet, L.M.; Cook, L.S.; Weiss, N.S.; Schwartz, S.M.; White, E. Risk factors for colorectal cancer following breast cancer. Breast Cancer Res. Treat. 2003, 79, 143–147. [Google Scholar] [CrossRef] [PubMed]
  10. Carney, P.A.; O’Malley, J.P.; Gough, A.; Buckley, D.I.; Wallace, J.; Fagnan, L.J.; Morris, C.; Mori, M.; Heintzman, J.D.; Lieberman, D. Association between documented family history of cancer and screening for breast and colorectal cancer. Prev. Med. 2013, 57, 679–684. [Google Scholar] [CrossRef] [PubMed]
  11. Lu, Y.; Segelman, J.; Nordgren, A.; Lindström, L.; Frisell, J.; Martling, A. Increased risk of colorectal cancer in patients diagnosed with breast cancer in women. Cancer Epidemiol. 2016, 41, 57–62. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  12. Loibl, S.; Poortmans, P.; Morrow, M.; Denkert, C.; Curigliano, G. Breast cancer. Lancet 2021, 397, 1750–1769. [Google Scholar] [CrossRef]
  13. Zubair, M.; Wang, S.; Ali, N. Advanced Approaches to Breast Cancer Classification and Diagnosis. Front. Pharmacol. 2021, 11, 632079. [Google Scholar] [CrossRef]
  14. Lau, K.H.; Tan, A.M.; Shi, Y. New and Emerging Targeted Therapies for Advanced Breast Cancer. Int. J. Mol. Sci. 2022, 23, 2288. [Google Scholar] [CrossRef] [PubMed]
  15. Meanwell, N.A. Improving drug candidates by design: A focus on physicochemical properties as a means of improving compound disposition and safety. Chem. Res. Toxicol. 2011, 24, 1420–1456. [Google Scholar] [CrossRef] [PubMed]
  16. Guha, R. On exploring structure-activity relationships. Methods Mol. Biol. 2013, 993, 81–94. [Google Scholar] [PubMed] [Green Version]
  17. Shrestha, J.P.; Subedi, Y.P.; Chen, L.H.; Chang, C.W.T. A mode of action study of cationic anthraquinone analogues: A new class of highly potent anticancer agents. MedChemComm 2015, 6, 2012–2022. [Google Scholar] [CrossRef]
  18. Gholampour, M.; Seradj, H.; Pirhadi, S.; Khoshneviszadeh, M. Novel 2-amino-1,4-naphthoquinone hybrids: Design, synthesis, cytotoxicity evaluation and in silico studies. Bioorg. Med. Chem. 2020, 28, 115718. [Google Scholar] [CrossRef] [PubMed]
  19. Kruschel, R.D.; Buzid, A.; Khandavilli, U.B.R.; Lawrence, S.E.; Glennon, J.D.; McCarthy, F.O. Isoquinolinequinone N-oxides as anticancer agents effective against drug resistant cell lines. Org. Biomol. Chem. 2020, 18, 557–568. [Google Scholar] [CrossRef]
  20. Eyong, K.O.; Ketsemen, H.L.; Zhao, Z.; Du, L.Q.; Ingels, A.; Mathieu, V.; Kornienko, A.; Hull, K.G.; Folefoc, G.N.; Baskaran, S.; et al. Antiproliferative activity of naphthoquinones and indane carboxylic acids from lapachol against a panel of human cancer cell lines. Med. Chem. Res. 2020, 29, 1058–1066. [Google Scholar] [CrossRef]
  21. Ravichandiran, P.; Subramaniyan, S.A.; Kim, S.Y.; Kim, J.S.; Park, B.H.; Shim, K.S.; Yoo, D.J. Synthesis and Anticancer Evaluation of 1,4-Naphthoquinone Derivatives Containing a Phenylaminosulfanyl Moiety. ChemMedChem 2019, 14, 532–544. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  22. Defant, A.; Mancini, I. Design, Synthesis and Cancer Cell Growth Inhibition Evaluation of New Aminoquinone Hybrid Molecules. Molecules 2019, 24, 2224. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  23. Bayrak, N.; Yıldırım, H.; Yıldız, M.; Radwan, M.O.; Otsuka, M.; Fujita, M.; Ciftci, H.I.; Tuyun, A.F. A novel series of chlorinated plastoquinone analogues: Design, synthesis, and evaluation of anticancer activity. Chem. Biol. Drug Des. 2020, 95, 343–354. [Google Scholar] [CrossRef] [PubMed]
  24. Bayrak, N.; Yildirim, H.; Yildiz, M.; Radwan, M.O.; Otsuka, M.; Fujita, M.; Tuyun, A.F.; Ciftci, H.I. Design, synthesis, and biological activity of Plastoquinone analogues as a new class of anticancer agents. Bioorg. Chem. 2019, 92, 103255. [Google Scholar] [CrossRef] [PubMed]
  25. Ciftci, H.I.; Bayrak, N.; Yildirim, H.; Yildiz, M.; Radwan, M.O.; Otsuka, M.; Fujita, M.; Tuyun, A.F. Discovery and structure-activity relationship of plastoquinone analogues as anticancer agents against chronic myelogenous leukemia cells. Arch. Pharm. 2019, 352, 1900170. [Google Scholar] [CrossRef] [PubMed]
  26. Bayrak, N.; Ciftci, H.I.; Yildiz, M.; Yildirim, H.; Sever, B.; Tateishi, H.; Otsuka, M.; Fujita, M.; Tuyun, A.F. Structure based design, synthesis, and evaluation of anti-CML activity of the quinolinequinones as LY83583 analogues. Chem. Biol. Interact. 2021, 345, 109555. [Google Scholar] [CrossRef] [PubMed]
  27. Ciftci, H.I.; Bayrak, N.; Yıldız, M.; Yıldırım, H.; Sever, B.; Tateishi, H.; Otsuka, M.; Fujita, M.; Tuyun, A.F. Design, synthesis and investigation of the mechanism of action underlying anti-leukemic effects of the quinolinequinones as LY83583 analogues. Bioorg. Chem. 2021, 114, 105160. [Google Scholar] [CrossRef] [PubMed]
  28. Jannuzzi, A.T.; Yıldız, M.; Bayrak, N.; Yıldırım, H.; Shilkar, D.; Jayaprakash, V.; Tuyun, A.F. Anticancer agents based on Plastoquinone analogues with N-phenylpiperazine: Structure-activity relationship and mechanism of action in breast cancer cells. Chem. Biol. Interact. 2021, 349, 109673. [Google Scholar] [CrossRef] [PubMed]
  29. DTP Developmental Therapeutics Program. Available online: https://dtp.cancer.gov/databases_tools/docs/compare/compare_methodology.htm#perform (accessed on 25 September 2022).
  30. Kazakova, O.; Mioc, A.; Smirnova, I.; Baikova, I.; Voicu, A.; Vlaia, L.; Macașoi, I.; Mioc, M.; Drăghici, G.; Avram, Ş.; et al. Novel Synthesized N-Ethyl-Piperazinyl-Amides of C2-Substituted Oleanonic and Ursonic Acids Exhibit Cytotoxic Effects through Apoptotic Cell Death Regulation. Int. J. Mol. Sci. 2021, 22, 10967. [Google Scholar] [CrossRef] [PubMed]
  31. Boyd, M.R.; Pauli, K.D. Some practical considerations and applications of the National-Cancer-Institute in vitro anticancer drug discovery screen. Drug Dev. Res. 1995, 34, 91–109. [Google Scholar] [CrossRef]
  32. Cuartas, V.; Aragón-Muriel, A.; Liscano, Y.; Polo-Cerón, D.; Crespo-Ortiz, M.; Quiroga, J.; Abonia, R.; Insuasty, B. Anticancer activity of pyrimidodiazepines based on 2-chloro-4-anilinoquinazoline: Synthesis, DNA binding and molecular docking. RSC Adv. 2021, 11, 23310–23329. [Google Scholar] [CrossRef] [PubMed]
  33. Rostom, S.A.; Shalaby, M.A.; El-Demellawy, M.A. Polysubstituted pyrazoles, part 5. Synthesis of new 1-(4-chlorophenyl)-4-hydroxy-1H-pyrazole-3-carboxylic acid hydrazide analogues and some derived ring systems. A novel class of potential antitumor and anti-HCV agents. Eur. J. Med. Chem. 2003, 38, 959–974. [Google Scholar] [CrossRef] [PubMed]
  34. Monks, A.; Scudiero, D.; Skehan, P.; Shoemaker, R.; Paull, K.; Vistica, D.; Hose, C.; Langley, J.; Cronise, P.; Vaigrowolff, A.; et al. Feasibility of a high-flux anticancer drug screen using a diverse panel of cultured human tumor cell lines. J. Natl. Cancer Inst. 1991, 83, 757–766. [Google Scholar] [CrossRef]
  35. Sledge, G.W., Jr.; Loehrer, P.J., Sr.; Roth, B.J.; Einhorn, L.H. Cisplatin as first-line therapy for metastatic breast cancer. J. Clin. Oncol. 1988, 6, 1811–1814. [Google Scholar] [CrossRef] [PubMed]
  36. Passalacqua, R.; Bisagni, G.; Cocconi, G.; Boni, C.; Di Blasio, B.; Ceci, G. Cisplatin and etoposide in advanced colorectal carcinoma. Ann. Oncol. 1991, 2, 687–688. [Google Scholar] [CrossRef]
  37. Haller, D.G. Recent updates in the clinical use of platinum compounds for the treatment of gastrointestinal cancers. Semin. Oncol. 2004, 31, 10–16. [Google Scholar] [CrossRef]
  38. Prabhakaran, P.; Hassiotou, F.; Blancafort, P.; Filgueira, L. Cisplatin induces differentiation of breast cancer cells. Front. Oncol. 2013, 3, 134. [Google Scholar] [CrossRef] [Green Version]
  39. Shen, M.; Duan, W.M.; Wu, M.Y.; Wang, W.J.; Liu, L.; Xu, M.D.; Zhu, J.; Li, D.M.; Gui, Q.; Lian, L.; et al. Participation of autophagy in the cytotoxicity against breast cancer cells by cisplatin. Oncol. Rep. 2015, 34, 359–367. [Google Scholar] [CrossRef] [Green Version]
  40. Wan, X.; Wang, C.; Huang, Z.; Zhou, D.; Xiang, S.; Qi, Q.; Chen, X.; Arbely, E.; Liu, C.Y.; Du, P.; et al. Cisplatin inhibits SIRT3-deacetylation MTHFD2 to disturb cellular redox balance in colorectal cancer cell. Cell Death Dis. 2020, 11, 649. [Google Scholar] [CrossRef]
  41. Lynce, F.; Nunes, R. Role of Platinums in Triple-Negative Breast Cancer. Curr. Oncol. Rep. 2021, 23, 50. [Google Scholar] [CrossRef]
  42. Ciftci, H.; Sever, B.; Ocak, F.; Bayrak, N.; Yıldız, M.; Yıldırım, H.; DeMirci, H.; Tateishi, H.; Otsuka, M.; Fujita, M.; et al. In Vitro and In Silico Study of Analogues of Plant Product Plastoquinone to Be Effective in Colorectal Cancer Treatment. Molecules 2022, 27, 693. [Google Scholar] [CrossRef] [PubMed]
  43. Brogden, A.L.; Hopcroft, N.H.; Searcey, M.; Cardin, C.J. Ligand bridging of the DNA Holliday junction: Molecular recognition of a stacked-X four-way junction by a small molecule. Angew. Chem. Int. Ed. Eng. 2007, 46, 3850–3854. [Google Scholar] [CrossRef] [PubMed]
  44. Schrödinger Release 2016-2; Schrödinger, LLC: New York, NY, USA, 2016.
  45. Schrödinger Release 2016-2: QikProp; Schrödinger, LLC: New York, NY, USA, 2016.
  46. SwissADME. Available online: http://www.swissadme.ch (accessed on 29 August 2022).
  47. Daina, A.; Michielin, O.; Zoete, V. SwissADME: A free web tool to evaluate pharmacokinetics, drug-likeness and medicinal chemistry friendliness of small molecules. Sci. Rep. 2017, 7, 42717. [Google Scholar] [CrossRef] [Green Version]
  48. Tukulula, M.; Little, S.; Gut, J.; Rosenthal, P.J.; Wan, B.; Franzblau, S.G.; Chibale, K. The design, synthesis, in silico ADME profiling, antiplasmodial and antimycobacterial evaluation of new arylamino quinoline derivatives. Eur. J. Med. Chem. 2012, 57, 259–267. [Google Scholar] [CrossRef]
  49. Rasal, N.K.; Sonawane, R.B.; Jagtap, S.V. Potential 2,4-dimethyl-1H-pyrrole-3-carboxamide bearing benzimidazole template: Design, synthesis, in vitro anticancer and in silico ADME study. Bioorg. Chem. 2020, 97, 103660. [Google Scholar] [CrossRef] [PubMed]
  50. Varano, F.; Catarzi, D.; Vigiani, E.; Vincenzi, F.; Pasquini, S.; Varani, K.; Colotta, V. Piperazine- and Piperidine-Containing Thiazolo[5,4-d]pyrimidine Derivatives as New Potent and Selective Adenosine A2A Receptor Inverse Agonists. Pharmaceuticals 2020, 13, 161. [Google Scholar] [CrossRef] [PubMed]
  51. Waldner, M.J.; Neurath, M.F. The molecular therapy of colorectal cancer. Mol. Aspects Med. 2010, 31, 171–178. [Google Scholar] [CrossRef] [PubMed]
  52. Howell, A.; Anderson, A.S.; Clarke, R.B.; Duffy, S.W.; Evans, D.G.; Garcia-Closas, M.; Gescher, A.J.; Key, T.J.; Saxton, J.M.; Harvie, M.N. Risk determination and prevention of breast cancer. Breast Cancer Res. 2014, 16, 446. [Google Scholar] [CrossRef]
  53. Wellington, K.W. Understanding cancer and the anticancer activities of naphthoquinones—A review. RSC Adv. 2015, 5, 20309–20338. [Google Scholar] [CrossRef]
  54. Tandon, V.K.; Kumar, S. Recent development on naphthoquinone derivatives and their therapeutic applications as anticancer agents. Expert Opin. Ther. Pat. 2013, 23, 1087–1108. [Google Scholar] [CrossRef]
  55. Yilmaz Goler, A.M.; Jannuzzi, A.T.; Bayrak, N.; Yıldız, M.; Yıldırım, H.; Otsuka, M.; Fujita, M.; Radwan, M.O.; TuYuN, A.F. In Vitro and In Silico Study to Assess Toxic Mechanisms of Hybrid Molecules of Quinone-Benzocaine as Plastoquinone Analogues in Breast Cancer Cells. ACS Omega 2022, 7, 30250–30264. [Google Scholar] [CrossRef] [PubMed]
  56. Davidson, N.E.; Hahm, H.A.; Armstrong, D.K. Apoptosis and Breast Cancer. In Apoptosis and Cancer Chemotherapy. Cancer Drug Discovery and Development; Hickman, J.A., Dive, C., Eds.; Humana Press: Totowa, NJ, USA, 1999; pp. 291–303. [Google Scholar]
  57. Parton, M.; Dowsett, M.; Smith, I. Studies of apoptosis in breast cancer. BMJ 2001, 322, 1528–1532. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  58. Yang, S.Y.; Sales, K.M.; Fuller, B.; Seifalian, A.M.; Winslet, M.C. Apoptosis and colorectal cancer: Implications for therapy. Trends Mol. Med. 2009, 15, 225–233. [Google Scholar] [CrossRef] [PubMed]
  59. Watson, A.J.M. Recent advances in basic science apoptosis and colorectal cancer. Gut 2004, 53, 1701–1709. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  60. Yamashita, F.; Hashida, M. In silico approaches for predicting ADME properties of drugs. Drug Metab. Pharm. 2004, 19, 327–338. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  61. Alqahtani, S. In silico ADME-Tox modeling: Progress and prospects. Expert Opin. Drug Metab. Toxicol. 2017, 13, 1147–1158. [Google Scholar] [CrossRef] [PubMed]
  62. Honório, K.M.; Moda, T.L.; Andricopulo, A.D. Pharmacokinetic properties and in silico ADME modeling in drug discovery. Med. Chem. 2013, 9, 163–176. [Google Scholar] [CrossRef] [PubMed]
  63. Durán-Iturbide, N.A.; Díaz-Eufracio, B.I.; Medina-Franco, J.L. In Silico ADME/Tox Profiling of Natural Products: A Focus on BIOFACQUIM. ACS Omega 2020, 5, 16076–16084. [Google Scholar] [CrossRef]
  64. Grever, M.R.; Schepartz, S.A.; Chabner, B.A. The National-Cancer-Institute: Cancer drug discovery and development program. Semin. Oncol. 1992, 19, 622–638. [Google Scholar]
  65. Skehan, P.; Storeng, R.; Scudiero, D.; Monks, A.; McMahon, J.; Vistica, D.; Warren, J.T.; Bokesch, H.; Kenney, S.; Boyd, M.R. New colorimetric cytotoxicity assay for anticancer-drug screening. J. Natl. Cancer Inst. 1990, 82, 1107–1112. [Google Scholar] [CrossRef]
  66. Ciftci, H.I.; Can, M.; Ellakwa, D.E.; Suner, S.C.; Ibrahim, M.A.; Oral, A.; Sekeroglu, N.; Özalp, B.; Otsuka, M.; Fujita, M.; et al. Anticancer activity of Turkish marine extracts: A purple sponge extract induces apoptosis with multitarget kinase inhibition activity. Investig. New Drugs 2020, 38, 1326–1333. [Google Scholar] [CrossRef] [PubMed]
Figure 1. Line of thought. Structures of target molecules (AQ-11, AQ-12, and AQ-15).
Figure 1. Line of thought. Structures of target molecules (AQ-11, AQ-12, and AQ-15).
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Figure 2. Graphical presentation of growth inhibition of the PQ analogue AQ-12 at five dose concentrations (0.01, 0.1, 1, 10, and 100 µM) after 48 h based on SRB assay at NCI.
Figure 2. Graphical presentation of growth inhibition of the PQ analogue AQ-12 at five dose concentrations (0.01, 0.1, 1, 10, and 100 µM) after 48 h based on SRB assay at NCI.
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Figure 3. The cytotoxic effects of AQ-12 and cisplatin at varying concentrations (1, 3, 10, 30, and 100 μM) on MCF-7 and HCT-116 cells based on MTT assay. All descriptive data are expressed as the mean ± standard deviation (SD). All experiments were repeated three times.
Figure 3. The cytotoxic effects of AQ-12 and cisplatin at varying concentrations (1, 3, 10, 30, and 100 μM) on MCF-7 and HCT-116 cells based on MTT assay. All descriptive data are expressed as the mean ± standard deviation (SD). All experiments were repeated three times.
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Figure 4. (A) Alteration of HCT-116 and MCF-7 cells after treatment with IC50 concentration of the control (DMSO), AQ-12, and cisplatin (B) for 12 h. The percentage of apoptosis, late apoptosis/necrosis, and necrosis (green, yellow, and red, respectively) cells (C) was determined by analyzing 100 randomly selected stained cells in each experiment (ns: not statistically significant). Data from three independent experiments were expressed as means ± standard deviation and p values were determined using Student’s test.
Figure 4. (A) Alteration of HCT-116 and MCF-7 cells after treatment with IC50 concentration of the control (DMSO), AQ-12, and cisplatin (B) for 12 h. The percentage of apoptosis, late apoptosis/necrosis, and necrosis (green, yellow, and red, respectively) cells (C) was determined by analyzing 100 randomly selected stained cells in each experiment (ns: not statistically significant). Data from three independent experiments were expressed as means ± standard deviation and p values were determined using Student’s test.
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Figure 5. Docking poses (A) and docking interactions (B) of AQ-11, AQ-12, and AQ-15 in the minor groove of the DNA double helix (AQ-11, AQ-12, and AQ-15 are shown in dark green, maroon, and turquoise, respectively) (PDB ID: 2GWA).
Figure 5. Docking poses (A) and docking interactions (B) of AQ-11, AQ-12, and AQ-15 in the minor groove of the DNA double helix (AQ-11, AQ-12, and AQ-15 are shown in dark green, maroon, and turquoise, respectively) (PDB ID: 2GWA).
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Figure 6. Bioavailability radar for AQ-12 from the SwissADME web tool.
Figure 6. Bioavailability radar for AQ-12 from the SwissADME web tool.
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Figure 7. Boiled-egg graph of AQ-12 from the SwissADME web tool.
Figure 7. Boiled-egg graph of AQ-12 from the SwissADME web tool.
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Figure 8. PQ analogues that were previously determined by our research group as potential anticancer agents against CRC and breast cancer.
Figure 8. PQ analogues that were previously determined by our research group as potential anticancer agents against CRC and breast cancer.
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Table 1. The cytotoxic effects of AQ-11, AQ-12, and AQ-15 on K562 cells and PBMCs in comparison with imatinib [25].
Table 1. The cytotoxic effects of AQ-11, AQ-12, and AQ-15 on K562 cells and PBMCs in comparison with imatinib [25].
CompoundSubstitution GroupsCell Type (IC50, μM)
RK562 aPBMC aSI c
AQ-11H0.75 ± 0.055.14 ± 1.766.85
AQ-12m-CF30.88 ± 0.063.00 ± 1.223.41
AQ-15p-CH30.76 ± 0.047.64 ± 1.5810.05
Imatinib b5.58 ± 1.8333.92 ± 4.196.08
a Cell lines include K562 leukemia cells and peripheral blood mononuclear cells (PBMC). b Used as a reference. c selectivity index (SI) = IC50 for PBMCs/IC50 for K562 cells.
Table 2. Anticancer activity results as per single-dose assay at 10 µM concentration as percent cell growth of AQ-11, AQ-12, and AQ-15 after 48 h, based on Sulforhodamine B (SRB) assay at NCI.
Table 2. Anticancer activity results as per single-dose assay at 10 µM concentration as percent cell growth of AQ-11, AQ-12, and AQ-15 after 48 h, based on Sulforhodamine B (SRB) assay at NCI.
Panel/Cancer Cell LineCompound
AQ-11AQ-12AQ-15
Growth Percentage of Cell Lines in NCI 60
Leukemia
CCRF-CEM5.285.9047.98
HL-60(TB)45.6438.4673.23
K-56215.933.7854.03
MOLT-412.7223.5366.29
RPMI-822653.63−3.1287.67
SR62.8624.9779.88
Non-Small Cell Lung Cancer
A549/ATCC99.8196.78101.90
EKVX55.2449.4493.61
HOP-6292.6090.9889.82
HOP-9246.0248.8695.70
NCI-H22696.9490.87101.59
NCI-H23NDNDND
NCI-H322M99.29100.88104.93
NCI-H46095.7494.85100.91
NCI-H52283.4617.7393.90
CRC
COLO 205107.07101.80111.35
HCC-2998NDNDND
HCT-11679.1133.8695.79
HCT-1594.1965.71101.63
HT2999.13103.04104.47
KM1278.3467.20100.25
SW-62096.4917.07102.49
CNS Cancer
SF-26895.3994.3495.65
SF-295102.1496.20107.03
SF-53995.4293.4097.15
SNB-1988.7992.4196.00
SNB-7565.4466.4765.44
U25184.3078.9999.94
Melanoma
LOX IMVINDNDND
MALME-3M107.9894.35102.03
M1495.8785.23102.50
MDA-MB-435102.3098.46107.59
SK-MEL-285.4885.7795.31
SK-MEL-28106.1198.26104.07
SK-MEL-5NDNDND
UACC-25790.2778.53106.17
UACC-6290.2880.2296.80
Ovarian Cancer
IGROV19.69−7.2080.83
OVCAR-3101.7970.40105.64
OVCAR-4−97.92−80.4199.38
OVCAR-5103.60100.01100.88
OVCAR-894.8987.14104.55
NCI/ADR-RESNDNDND
SK-OV-3NDNDND
Renal Cancer
786-099.18101.74104.29
A49891.2455.1772.19
ACHN100.46−37.6996.49
CAKI-196.0892.7491.53
RXF 39396.8097.82108.41
SN12C91.1387.6296.37
TK-10128.28183.73142.33
UO-3198.8177.3392.50
Prostate Cancer
PC-373.8764.3586.95
DU-145101.2699.72107.98
Breast Cancer
MCF790.7235.3696.29
MDA-MB-231/ATCC15.3518.9694.55
HS 578T100.9187.5790.46
BT-549113.97120.60119.94
T-47D−38.88−38.9684.68
MDA-MB-468−76.01−65.5552.82
Table 3. GI50, TGI, and LC50 values (in µM) of anticancer activity data, as per five doses (0.01, 0.1, 1, 10, and 100 µM) of AQ-12 after 48 h based on SRB assay at NCI.
Table 3. GI50, TGI, and LC50 values (in µM) of anticancer activity data, as per five doses (0.01, 0.1, 1, 10, and 100 µM) of AQ-12 after 48 h based on SRB assay at NCI.
Panel/Cell LineGI50TGILC50
Leukemia
CCRF-CEM1.93>100>100
HL-60(TB)2.346.54>100
K-5622.40>100>100
MOLT-42.22>100>100
RPMI-82261.327.32>100
SR2.59 >100
Non-Small Cell Lung Cancer
A549/ATCC13.30>100>100
EKVX1.493.739.31
HOP-6211.5027.6066.50
HOP-921.513.046.14
NCI-H22610.8034.90>100
NCI-H236.8724.0065.40
NCI-H322M22.70>100>100
NCI-H46011.6032.2089.30
NCI-H5222.245.66>100
CRC
COLO 20513.0029.3066.00
HCC-29985.8818.4046.00
HCT-1161.933.998.22
HCT-152.205.0516.20
HT297.2951.80>100
KM123.5825.70>100
SW-6202.094.73>100
CNS Cancer
SF-2684.9928.60>100
SF-2956.5524.0074.10
SF-5392.406.6124.80
SNB-195.8323.4077.40
SNB-751.1613.6091.00
U2514.4517.9058.20
Melanoma
LOX IMVI1.693.326.51
MALME-3M1.986.0430.90
M149.9632.70>100
MDA-MB-4355.9819.5049.20
SK-MEL-28.2621.7050.90
SK-MEL-283.3610.8036.00
SK-MEL-54.1415.7043.80
UACC-2572.616.7226.90
UACC-623.4616.1056.00
Ovarian Cancer
IGROV11.423.197.15
OVCAR-32.315.58>100
OVCAR-41.582.975.58
OVCAR-51.984.138.61
OVCAR-82.686.89>100
NCI/ADR-RES3.1642.30>100
SK-OV-31.3050.70>100
Renal Cancer
786-010.6024.3055.70
A49813.7045.20>100
ACHN1.733.195.87
CAKI-11.949.1132.40
RXF 3931.492.855.44
SN12C2.2523.40>100
TK-1019.0037.0071.90
UO-311.464.1814.20
Prostate Cancer
PC-32.6712.80>100
DU-14515.6034.8077.70
Breast Cancer
MCF71.713.798.39
MDA-MB-231/ATCC1.593.286.77
HS 578T6.0064.40>100
BT-5498.5622.2051.70
T-47D1.173.60>100
MDA-MB-4681.242.947.00
Table 4. The cytotoxic effects of AQ-12 on MCF-7 and HCT-116 cells based on MTT assay at five dose concentrations (1, 3, 10, 30, and 100 μM).
Table 4. The cytotoxic effects of AQ-12 on MCF-7 and HCT-116 cells based on MTT assay at five dose concentrations (1, 3, 10, 30, and 100 μM).
CompoundIC50 Value (µM)
MCF-7 CellsHCT-116 Cells
AQ-126.06 ± 3.095.11 ± 2.14
Cisplatin19.67 ± 5.9423.68 ± 6.81
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Ciftci, H.; Sever, B.; Bayrak, N.; Yıldız, M.; Yıldırım, H.; Tateishi, H.; Otsuka, M.; Fujita, M.; TuYuN, A.F. In Vitro Cytotoxicity Evaluation of Plastoquinone Analogues against Colorectal and Breast Cancers along with In Silico Insights. Pharmaceuticals 2022, 15, 1266. https://doi.org/10.3390/ph15101266

AMA Style

Ciftci H, Sever B, Bayrak N, Yıldız M, Yıldırım H, Tateishi H, Otsuka M, Fujita M, TuYuN AF. In Vitro Cytotoxicity Evaluation of Plastoquinone Analogues against Colorectal and Breast Cancers along with In Silico Insights. Pharmaceuticals. 2022; 15(10):1266. https://doi.org/10.3390/ph15101266

Chicago/Turabian Style

Ciftci, Halilibrahim, Belgin Sever, Nilüfer Bayrak, Mahmut Yıldız, Hatice Yıldırım, Hiroshi Tateishi, Masami Otsuka, Mikako Fujita, and Amaç Fatih TuYuN. 2022. "In Vitro Cytotoxicity Evaluation of Plastoquinone Analogues against Colorectal and Breast Cancers along with In Silico Insights" Pharmaceuticals 15, no. 10: 1266. https://doi.org/10.3390/ph15101266

APA Style

Ciftci, H., Sever, B., Bayrak, N., Yıldız, M., Yıldırım, H., Tateishi, H., Otsuka, M., Fujita, M., & TuYuN, A. F. (2022). In Vitro Cytotoxicity Evaluation of Plastoquinone Analogues against Colorectal and Breast Cancers along with In Silico Insights. Pharmaceuticals, 15(10), 1266. https://doi.org/10.3390/ph15101266

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