Int J Pharm Pharm Sci, Vol 15, Issue 7, 7-19Original Article

ANTIOXIDANT, ANTICANCER AND MOLECULAR DOCKING STUDIESOF NOVEL 5-BENZYLIDENE SUBSTITUTED RHODANINE DERIVATIVES

CICI MATHEW^1*, NAND LAL², LAKSHMI S.², ASWATHY T. R.³, JOYAMMA VARKEY¹

¹College of Pharmaceutical Sciences, Government Medical College, Trivandrum-695011, India. ²Corporate Research and Development Centre, HLL Lifecare Limited, Akkulam, Trivandrum-695017, India. ³Department of Computational Biology and Bioinformatics, University of Kerala, Trivandrum-695581, India
^*Corresponding author: Cici Mathew; ^*Email: ciciabi@gmail.com

Received: 25 Jan 2023, Revised and Accepted: 17 May 2023

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ABSTRAC

Objective: The primary objective was to study the in vitro antioxidant and anticancer evaluation of novel 5-benzylidene substituted rhodanine derivatives and molecular docking studies of the most active compounds with 3 different anticancer targets.

Methods: Antioxidant potential of 5-benzylidene substituted rhodanine derivatives were studied by DPPH assay, anticancer evaluation was done by MTT assay and Computational evaluation were done using various softwares such as ACD Lab Chemsketch 12.0, molinspiration and Discovery Studio 2021.

Results: Compound 3j exhibited the highest antioxidant activity with an IC₅₀ value of 31.21. Other compounds 3b, 3d and 3f also showed moderate antioxidant potential. The Antioxidant study showed a good correlation with molecular docking studies. In vitro anticancer assay results showed that compound 3a has an IC₅₀ value<62.5 against HeLa cell lines. All the other compounds showed only moderate activity. Out of the ten synthesized derivatives, compounds 3d and 3j showed good docking scores with 3 different anticancer targets.

Conclusion: Ten novel rhodanine derivatives which has been studied can be developed into potent antioxidant and anticancer agents in future.

Keywords: Antioxidant, Anticancer, Rhodanine derivatives, Computational evaluation

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© 2023 The Authors. Published by Innovare Academic Sciences Pvt Ltd. This is an open access article under the CC BY license (https://creativecommons.org/licenses/by/4.0/)
DOI: https://dx.doi.org/10.22159/ijpps.2023v15i7.47421. Journal homepage: https://innovareacademics.in/journals/index.php/ijpps.

INTRODUCTION

Cancer is reported to be the second most significant health problem in which cells are growing out of control resulting in tissue growth regulation failure [1, 2]. Worldwide, an estimated 19.3 million new cancer cases and almost 10.0 million cancer deaths occurred in 2020 and the global cancer burden is expected to be 28.4 million cases in 2040 [3]. Female breast cancer became the most commonly diagnosed cancer with an estimated 2.3 million new cases in 2020, representing 11.7% of all cancer cases [4]. The large increase in the number of cancer cases and high mortality rate reveals the fact that the present anticancer treatment is inadequate.

Thiazolidinedione (TZD) and Rhodanine derivatives have become very important groups of heterocyclic compounds in drug design and discovery [5]. Due to the ability to demonstrate a broad range of biological activities rhodanine derivatives have been well recognized as a privileged scaffold in medicinal chemistry. Many studies have revealed the anticancer effects of rhodanines over the last few decades [6-11]. The five-membered rhodanine ring bearing a Sulphur and Nitrogen at the first and third positions are reported to have significant anticancer activity against different types of cancer, including breast cancer, prostate cancer, colorectal cancer, liver cancer, pancreatic cancer, gastric cancer, lung cancer, renal cancer, and leukaemia [12-15].

Reactive oxygen species (ROS) are thought to play an important role in the progression of many chronic diseases, including cancer [16-18]. ROS are produced in the human body from metabolic activity or exogenously from smoking, air pollutants, radiation, ozone, and industrial chemicals. Antioxidants help in scavenging or preventing the generation of ROS and control the formation of free radicals [18]. The intake of antioxidants has been shown to reduce the risk of cancer as well as neurological and cardiovascular pathologies among others [19].

Based on these findings, we were interested in investigating the antioxidant and anticancer effects of our previously reported new chemical entity (NCE), 3-[(dialkylamino) alkyl]-2-thioxothiazolidinone. In the present study, a series of ten 5-benzylidene substituted rhodanine derivatives were tested for antioxidant potential by DPPH assay and in vitro anticancer activity against HeLa and MDAMB-231 using the MTT assay. To correlate the mechanism of action of the most active compounds, molecular docking studies were also carried out.

Fewer efficacies in the present cancer therapy, patient non-compliance, drug resistance and uncertainty of current candidates in a clinical trial have led to the need for the development of potential anticancer agents.

MATERIALS AND METHODS

Chemistry

A new chemical entity (NCE), 3-[(dialkylamino) alkyl]-2-thioxothiazolidinone (fig. 1) by substituting various benzylidene derivatives at the 5^th position was prepared previously 20] by the reaction of N–substituted Rhodanine, substituted benzaldehyde and ammonium acetate in a minimum amount of acetic acid (Scheme II). Compounds were characterized by melting points, IR, NMR and MASS Spectra and were purified by column chromatography to get excellent yield.

Fig. 1: General structure of the designed molecular framework

In vitro antioxidant studies by DPPH assay

The DPPH radical scavenging activity (H/e-transferring activity of the compound was evaluated according to the method reported by Sunitha Dontha in 2016 with slight modification [21]. Briefly aliquot 100 µl of various concentrations (500, 250, 125, 62.5, 31.25, 15.625 µM) were dissolved in methanol. Added 130 µl (100 µl) of DPPH. 100 µl of methanol mixed with DPPH served as a negative control. The mixture was vortexed and then incubated in the dark for 30 min at room temperature. After the prescribed incubation, the absorbance was measured at 550 nm using a multiwall Elisa reader and plotted the graph by taking the concentration along the X-axis and the percentage scavenging activity along Y-axis.

Where Ac is Absorbance of Control and As is Absorbance of Sample

In vitro anticancer studies

Reagents and cell line

MDAMB-231 (breast carcinoma) and HeLa (human cervical cancer) cells were procured from National Centre for Cell Sciences, Pune, India. The cells were cultured and maintained in a DMEM medium containing 10% fetal bovine serum at 37 °C, 5% CO₂ and saturated humidity. Other reagents used for the study were Dulbecco's modified Eagle's medium (DMEM) (Lonza), Fetal bovine serum, Trypsin, Antibiotic antimycotic (Gibco, USA), MTT (Merck), Sodium dodecyl sulphate (SDS) and Dimethyl formamide (DMF) (Sigma) and cell culture plastic wares (Eppendorff, Germany).

Cell proliferation by MTT assay

MTT assay was performed to study cell proliferation (http://www.organic-chemistry.org/prog/peo/). 5x10³ cells were seeded and incubated overnight in 96 well plates, the next day, the wells were treated with different concentrations of compounds (1000, 500, 250, 125 and 62.5 µg/ml) and incubated further for 48 and 72 h. MTT reagent was added after the specified incubations into each well at a concentration of 100 µg per well and incubated in the dark at 37 °C for two hours. Followed by the addition of lysis solution (20% SDS in 50% DMF) into each well, it was again incubated in the dark for further four hours. The optical densities were measured at 570 nm after the incubation, using an enzyme-linked immunosorbent assay reader (Tecan infinite M200 PRO) and the percentage of cytotoxicity was calculated using the equation,

IC₅₀ was calculated using Easy plot software.

Microscopy

Phase-contrast microscopy (Magnus, Magcam, DC5) is used to assess the morphological changes of MDAMB-231 and HeLa cells. These cells were treated with the compounds at different concentrations for 48 and 72 h before morphological testing. The morphology of the untreated and treated cells was captured and compared for cytotoxic effects.

Statistical analysis

Data were expressed as the mean of three independent experiments for the cytotoxicity studies.

Docking simulations

Docking is a virtual screening of a database of compounds and predicting the strongest binding agents based on various scoring functions. The docking module LibDock using Discovery Studio 2021 was used for docking. Drug likeness scores of the compounds were evaluated with the help of Lipinski’s rule of five. The ligands were positioned in the binding site by using Libdock. Libdock is a suitable algorithm to find various conformations of the ligands within the receptor. Receptor ligand interactions were optimized by molecular dynamics using CHARMM. Protein targets selected for the study are progesterone receptor 1A28, Estrogen receptor 3ERT which are involved in the progression and development of breast cancer and Aurora Kinase-4ZTR which comes under the tyrosine kinase receptor. Therefore these proteins were selected for the docking study. The docking study was done using Discovery studio 2021 software and target proteins (1A28, 3ERT and 4ZTR) were downloaded from the protein data bank.

Preparation of ligands

Structures of the biochemical compounds were obtained from Pub Chem (https://pubchem.ncbi.nlm.nih.gov/) compound database, the world’s largest freely accessible chemical database that provides information regarding chemical and physical properties, biological activities, safety and toxicity, patents and literature citations of chemical molecules. The ligand structure procured from PubChem possess different protonation states and 3D geometries and is prepared for molecular interaction studies by correcting, editing and generating variations of the structures and optimizing them using Biovia Discovery Studio v.21.

Preparation of the target proteins

The three-dimensional X ray crystallographic structure of proteins was retrieved from Research Collaboratory for Structural Bioinformatics (RCSB) Protein Data Bank (http://www.rcsb.org/pdb/home/home.do). The Protein Data Bank (PDB) is a freely accessible structural database that provides three-dimensional X-ray crystallographic and NMR data of large biological molecules such as proteins and nucleic acids. From the crystallographic structure of the proteins, unwanted water molecules, heteroatoms and complex ligands were manually removed. The Protein Prepare protocol in Discovery Studio v.21 was used to insert the missing atoms, missing loop regions, delete alternate conformations, remove waters, standardise atom names and protonate titratable residues using predicted pKs. Energy minimization was also performed, and the minimized structure was used as the target structure for the docking studies.

Molecular docking analysis

The molecular interaction study between the targets and ligands was conducted using Biovia Discovery Studio v.21. Initially, the binding sites of the proteins were predicted using the ‘define and edit binding site’ option in the software based on the PDB site records. For the molecular interaction study LibDock protocol [22], a high throughput docking algorithm to find various ligand conformations in the protein active site based on polar interaction sites (hotspots) was used. CHARMM was the force field applied which uses positional relationships between atoms to determine the energy and forces acting on each particle of the system. The LibDock score and binding energy of the protein-ligand complexes were estimated and recorded.

Pharmacokinetic screening

The compounds were evaluated for their acceptability as an oral drug based on Lipinski’s rule of five [23] which is essential for drug-like pharmacokinetic profile in rational drug design [24]. The druggability of the ligand molecules was also predicted by ADMET analysis which computes the absorption, distribution, metabolism, excretion and toxicity potential of a pharmaceutical compound within an organism [25]. The 2D structures of the molecules were subject to analysis of solubility, intestinal absorption, and hepatotoxicity, plasma protein binding ability, blood-brain barrier (BBB) penetration, cytochrome P450 inhibition and AMES mutagenicity using ADMET descriptors in Discovery studio v.21.

RESULTS AND DISCUSSION

Chemistry

Synthesis of a new chemical entity (NCE), 3-[(dialkylamino) alkyl]-2-thioxothiazolidinone by substituting various benzylidene derivatives at the 5^th position (Scheme 1) was reported previously [20]. Different Rhodanine derivatives (3a-3j) synthesized are given in table 1.

Scheme II: Reagents and condition: a) Ammonium acetate, Acetic acid, 80-85 °C

Table 1: List of derivatives selected for synthesis using ACD Lab Chemsketch 12.0 and their molecular formula

Compound code	Structure	Chemical name	Molecular formula
3a		5-Benzylidene-3-(2-(dimethyl amino)ethyl)-2-thioxothiazolidin-4-one	C14H16N2OS2
3b		3-(2-(dimethyl amino) ethyl)-5-(4-ethylbenzylidene)-2-thioxothiazolidin-4-one	C16H20N2OS2
3c		3-(2-(dimethyl amino) ethyl)-5-(4-methylbenzylidene)-2-thioxothiazolidin-4-one	C15H18N2OS2
3d		3-(2-(diethylamino)ethyl)-5-(4-ethylbenzylidene)-2-thioxothiazolidin-4-one	C18H24N2OS2
3e		3-(2-(dimethylamino)ethyl)-5-(2-methylbenzylidene)-2-thioxothiazolidin-4-one	C15H18N2OS2
3f		3-(2-(dimethylamino)ethyl)-5-(4-isopropylbenzylidene)-2-thioxothiazolidin-4-one	C17H22N2OS2
3g		5-benzylidene-3-(2-(diethylamino)ethyl)-2-thioxothiazolidin-4-one	C16H20N2OS2
3h		3-(2-(diethylamino)ethyl)-5-(4-methylbenzylidene)-2-thioxothiazolidin-4-one	C17H22N2OS2
3i		3-(2-(diethylamino)ethyl)-5-(2-methylbenzylidene)-2-thioxothiazolidin-4-one	C17H22N2OS2
3j		3-(2-(diethylamino)ethyl)-5-(4-isopropylbenzylidene)-2-thioxothiazolidin-4-one	C19H26N2OS2

In vitro antioxidant studies by DPPH assay

DPPH assay is based on the measurement of the scavenging capacity of antioxidants towards it. The odd electron of the nitrogen atom in DPPH is reduced by receiving a hydrogen atom from antioxidants to the corresponding hydrazine [26]. Concentrations ranging from 15.625µg/ml-500 µg/ml of the synthesized rhodanine derivatives were tested for their antioxidant activity by using the DPPH scavenging method. Ascorbic acid was used as the standard. The antioxidant activity was estimated by IC₅₀ value and the values are shown in table2. The scavenging activity of compounds 3a-3j is shown in fig. 2.

Among the compounds tested for antioxidant activity, compounds 3b, 3f and 3j exhibited the highest antioxidant activity with IC₅₀ values of 170.49, 184.39 and 31.21 µg/ml respectively while IC₅₀ of reference compound ascorbic acid was found to be less than 15.63µg/ml. Another moderately active compound, 3d showed an IC₅₀ value of 453.17 µg/ml. All other compounds (3a, 3c, 3e, 3g, 3h, 3i) were not considered to have anti-oxidant activity since their IC ₅₀ value for quenching DPPH was more than 500 µg/ml. A series of benzylidene rhodanines were reported to have antioxidant potential by DPPH radical scavenging assay [27]. In our study, 4-ethylbenzylidene and 4–isopropyl benzylidene group at the 5^th position of rhodanine showed highest antioxidant activity.

Table 2: Antioxidant activity of synthesized compounds

Compound	IC 50(µg/ml)
3a	>500
3b	170.49
3c	>500
3d	453.17
3e	>500
3f	184.39
3g	>500
3h	>500
3i	>500
3j	31.21
Ascorbic acid	<15.63

Fig. 2: Radical scavenging activity of compounds 3a-3j. Results are expressed as mean±SD (n = 3)

In vitro anticancer studies

The synthesized rhodanine derivatives were screened for their anticancer activity using an MTT assay against MDAMB-231 and HeLa cell lines. Untreated cells served as control. The positive control used for the study was Doxorubicin for MDAMB and Cisplatin for HeLa cells. The percentage of cell inhibition at different concentrations of compounds and IC₅₀ value was determined. IC₅₀ concentrations of the different compounds at 48 and 72 h on MDAMB-231 and HeLa cells are given in table 3. The percentage of cytotoxicity induced by the compounds (3a-3j) after 48 and 72 h on MDAMB-231 and HeLa cells are shown in fig. 3, 4, 5 and 6.

Fig. 3: Percentage cytotoxicity induced by the compounds (3a-3j) after 48 h on MDAMB-231 cells at different concentrations. Data given in mean±SD (n = 3)

Table 3: IC50 concentrations of the different compounds at 48 and 72 h on MDAMB-231 and HeLa cells

Compound	IC50 (µg/ml)
	MDAMB-231		HeLa cells
	48 h	72 h	48 h	72 h
3a	>1000	250-500	<62.5	<62.5
3b	>1000	296	208	622
3c	>1000	>1000	>1000	>1000
3d	>1000	>1000	700	820
3e	>1000	252	>1000	184
3f	>1000	984	488	>1000
3g	>1000	247	360	>62.5
3h	>1000	679	244	494
3i	>1000	>1000	185	>1000
3j	>1000	>1000	>1000	966

Fig. 4: Percentage cytotoxicity induced by the compounds (3a-3j) after 72 h on MDAMB-231 cells at different concentrations. Data given in mean±SD (n = 3)

Fig. 5: Percentage cytotoxicity induced by the compounds (3a-3j) after 48 h on HeLa cells at different concentrations. Data given in mean±SD (n = 3)

Molecular modelling

Molecular descriptor analysis and drug likeness of Rhodanine derivatives (3a-3j) are shown in Tables 4, 5 and 6. Molar volume was calculated based on group contributors and analysed the transport characteristics of a molecule mainly gastro intestinal absorption (HIA) or Blood brain barrier (BBB). It was found that the calculated values of molar volumes were within the range (table 4). The measure of the total polarizability of molecules describing the steric effects and predicted polarizability of the compounds are within the range compared to the standard. All the compounds were expected to have good BBB and skin permeability. All the compounds were found to have a molecular weight of less than 500 Daltons and Log P value ranges from 1.92-4.19 (table 5).

Fig. 6: Percentage cytotoxicity induced by the compounds (3a-3j) after 72 h on HeLa cells at different concentrations. Data given in mean±SD (n = 3)

Table 4: Molecular descriptor analysis by ACD lab chemsketch 12.0. Data given in mean±SD (n = 3)

Compound code	Molecular refractivity (cm3)	Molar volume (cm3)	Parachor (cm3)	Surface tension (dyne/cm)
3a	84.44±0.4	225.0±5.0	635.4±6.0	63.5±5.0
3b	93.69±0.4	257.1±5.0	713.7±6.0	59.3±5.0
3c	89.06±0.4	240.8±5.0	673.7±6.0	61.2±5.0
3d	102.95±0.4	289.5±5.0	793.9±6.0	56.5±5.0
3e	89.06±0.4	240.8±5.0	673.7±6.0	61.2±5.0
3f	98.30±0.4	273.9±5.0	751.8±6.0	56.7±5.0
3g	98.30±0.4	273.9±5.0	751.8±6.0	56.7±5.0
3h	98.32±0.4	273.3±5.0	753.8±6.0	57.8±5.0
3i	98.32±0.4	273.3±5.0	753.8±6.0	57.8±5.0
3j	98.32±0.4	273.3±5.0	753.8±6.0	57.8±5.0

Table 5: Analysis of lipinski rule of five using molinspiration

Compound code	mi LogP	Molecular Weight	nON	nOHNH	N rotb	N Violation
3a	1.92	292.43	3	0	4	0
3b	2.84	320.48	3	0	5	0
3c	2.37	306.46	3	0	4	0
3d	3.59	348.54	3	0	7	0
3e	2.32	306.46	3	0	4	0
3f	3.44	334.51	3	0	5	0
3g	2.67	320.48	3	0	6	0
3h	3.12	334.51	3	0	6	0
3i	3.08	334.51	3	0	6	0
3j	4.19	362.56	3	0	7	0

The compound that exceeds molecular weight (Mw)>500Da, calculated log P>5, Hydrogen bond donors>5 and Hydrogen bond acceptors>10 is unlikely to be considered as a potential drug candidate because it would likely lack properties essential for its absorption, distribution, metabolism and excretion.

Table 6: Analysis of drug-likeness using molinspiration

Compound code	GPCR ligand	Ion channel modulator	Kinase inhibitor	Nuclear receptor ligand	Protease inhibitor	Enzyme inhibitor
3a	-0.90	-1.84	-0.79	-1.22	-0.74	-0.40
3b	-0.73	-1.65	-0.70	-0.98	-0.57	-0.34
3c	-0.87	-1.84	-0.75	-1.14	-0.73	-0.43
3d	-0.63	-1.53	-0.65	-0.84	-0.48	-0.32
3e	-0.90	-1.84	-0.81	-1.08	-0.78	-0.50
3f	-0.68	-1.60	-0.63	-0.88	-0.54	-0.33
3g	-0.74	-1.70	-0.70	-1.00	-0.60	-0.37
3h	-0.73	-1.70	-0.69	-0.96	-0.60	-0.41
3i	-0.76	-1.70	-0.74	-0.90	-0.65	-0.47
3j	-0.60	-1.49	-0.60	-0.77	-0.47	-0.32

Molecular docking study with different anticancer targets

Ten compounds were selected for the study and 3D structures of standard drug and 5-Fluorouracil was downloaded from the PubChem database in. sdf format. The ligands were prepared to generate possible conformers and tautomers. 3D structures of proteins were procured from PDB. The protein structures was cleaned (water molecules and other hetero atoms removed), prepared and minimized before docking. The docking module LibDock using Discovery Studio 2021 was used to study the interaction between the protein and ligand molecules.

Docking with progesterone receptor (PDB ID: 1A28)

The three-dimensional structure of the human progesterone receptor ligand-binding domain was downloaded from the PDB database with PDB ID: 1A28 with crystallographic resolution 1.80 A° (fig. 7). The protein consists of two polypeptide chain A and B. The protein chains consists of a total of 500 amino acids and has a molecular weight of 57452.3 Daltons. In the present study, the active site of protein interacting with the standardized ligand molecules was selected as the binding site.

90 poses of each selected ligand in the docked complexes were generated. The interacting molecular complexes among these having high LibDock scores and a maximum number of hydrogen bonds and active residues were selected. All 10 compounds have shown good interaction with the progesterone receptor in comparison with the standard drug, Adriamycin (PubChem ID: 31703) and 5-Fluorouracil (PubChem ID: 3385). Table 7 shows the Libdock scores of the best conformers of the ligands.

 

Fig. 7: Crystallographic structure of human progesterone receptor from PDB database (PDB ID: 1A28)

Table 7: Libdock score of ligands against human progesterone receptor (PDB ID: 1A28)

S. No.	PubChem ID	Lib dock score
	3a	80.7518
	3b	87.8036
	3c	83.2175
	3d	94.8511
	3e	83.3321
	3f	91.6506
	3g	89.3985
	3h	93.8283
	3i	91.7942
	3j	98.6231
Standard	5-Fluorouracil (PubChem ID: 3385)	59.6716

The ligands 3j and 3d showed top binding affinity. The docked complex of progesterone receptor (PDB ID: 1A28) with top score ligands and Standard ligands are shown in fig. 8 were analyzed to study the interactions between the target and the ligand molecule. The interacting residues, the nature of the interacting bond and the bond distance are given in table 8.

Table 8: Interactions between human progesterone receptor (PDB ID: 1A28) and ligands

S. No.	PubChem ID	Lib dock score	Interacting residues	Bond distance	Nature of bonding
8468	3j	98.6231	A: MET756:SD–3j A: TYR890:C,O; CYS891:N–3j 3j: C20-A: LEU721 3j: C20-A: MET759 3j: C21-A: LEU763 3j: C23-A: LEU715 3j: C23-A: VAL903 3j: C24-A: CYS891 A: PHE778–3j: C21 A: PHE905–3j: C23 A: PHE905–3j: C24 3j-A: MET756 3j-A: VAL760 3j-A: MET801 3j-A: LEU887 3j-A: CYS891	5.45854 5.0035 4.28126 4.80199 3.45764 3.86146 5.0746 3.80059 4.78601 4.91859 4.1478 5.3591 5.39639 4.72525 4.9706 4.55172	Other Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic
78016	3d	94.8511	A: MET756:SD–3d A: TYR890:C,O; CYS891:N–3d 3d: C11-A: LEU721 3d: C11-A: LEU763 3d: C12-A: LEU721 A: PHE778–3d: C11 A: PHE905–3d: C20 3d-A: MET756 3d-A: MET801 3d-A: LEU887 3d-A: CYS891	5.55576 4.8023 4.82046 4.6011 3.85694 4.37467 4.57443 5.29031 4.76102 4.85436 4.21074	Other Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic
	5-Fluorouracil (PubChem ID: 3385)	59.6716	A: GLN725:HE21-3385:O3 A: ARG766:HH21-3385:O3 A: ARG766:HH22-3385:O3 3385:H11-A: GLN725:OE1 A: VAL760:HA-3385:O2 A: PHE778:HA-3385:O3 3385-A: MET759 3385-A: LEU763	2.48473 2.37618 2.29975 2.69285 2.2983 2.98497 4.91528 4.9889	Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrophobic Hydrophobic

Fig. 8: Surface view and 2D diagram of human progesterone receptor (PDB ID: 1A28) withligands 3j, 3d, and 5-Fluorouracil

The result showed that ligands such as 3j and 3dhave high binding affinity. The docking score 98.6231 corresponded to 3j showed a high binding affinity with the receptor compared with standard drug molecule 5-Fluorouracil. The Standard drug 5-Fluorouracil showedthe LibDock score of 59.6716 with six hydrogen bonds (GLN725, ARG766, VAL760 and PHE778).

Docking with Estrogen receptor alpha (PDB ID: 3ERT)

The three-dimensional structure of Human estrogen receptor alpha ligand binding domain in complex with 4-hydroxytamoxifen was downloaded from PDB database with PDB ID: 3ERT with crystallographic resolution 1.90 A ° (fig. 9). The protein consists of one polypeptide chain A. The protein chain consists of 247 amino acids and has a molecular weight of 27596.2 Daltons. In the present study, the active site of protein interacting with the standardized ligand molecules was selected as the binding site.

90 poses of each selected ligand in the docked complexes were generated. The ligands 3j, 3d and 3i showed top binding affinity (fig. 10). Table 9 shows the Libdock score of best conformers of the ligands and table 10 shows Interactions between Estrogen receptor alpha (PDB ID: 3ERT) and Ligands.

Fig. 9: Crystallographic structure of Estrogen receptor alpha (PDB ID: 3ERT): from PDB database

Fig. 10: Surface view and 2D diagram of Estrogen receptor alpha (PDB ID: 3ERT) with ligands 3j, 3d and 5-Fluorouracil

Table 9: Libdock score of Ligands against Estrogen receptor alpha (PDB ID: 3ERT)

S. No.	PubChem ID	LibDock score
	3a	77.4554
	3b	80.6905
	3c	75.6753
	3d	88.3553
	3e	80.983
	3f	83.2322
	3g	84.3405
	3h	84.3602
	3i	88.446
	3j	90.6015
	5-Fluorouracil (PubChem ID: 3385)	61.5565

Docking with aurora kinase (PDB ID: 4ZTR)

The three-dimensional structure of Human aurora a catalytic domain bound to FK1141 was downloaded from PDB database with PDB ID: 4ZTR with crystallographic resolution 2.85A° (fig. 11). The protein consists of a single polypeptide chain A. The protein chain consists of 249 amino acids and has a molecular weight of 28030.1 Daltons. A. The active site of protein interacting with the standardized ligand molecules was selected as the binding site.

90 poses of each selected ligands in the docked complexes were generated. 3j and 3d showed the top binding affinity. Table 11 shows the Libdock score of best conformers of the ligands.

Fig. 11: Crystallographic structure of Aurora Kinase (PDB ID: 4ZTR) from PDB database

Table 10: Interactions between Estrogen receptor alpha (PDB ID: 3ERT) and Ligands

S. No.	PubChem ID	LibDock score	Interacting residues	Bond distance	Nature of bonding
8468	3d	88.3553	3d: H27-A: LEU387:O 3d: H28–3d: O6 3d: H29-A: GLU353:OE2 A: ALA350–3d: C20 3d: C11-A: LEU387 3d: C12-A: LEU391 A: PHE404–3d: C12 3d-A: LEU384 3d-A: MET388 3d-A: ALA350 3d-A: LEU525	2.22204 2.81497 2.4045 4.14062 3.81854 3.61711 5.31126 5.21945 4.83611 4.46021 4.40826	Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic
78016	3j	90.6015	A: THR347:HG1–3j: S5 3j: H28-A: ASP351:OD1 3j: H32-A: TRP383 A: MET343:SD–3j A: PHE404–3j A: LEU346:C,O; THR347:N–3j A: ALA350–3j: C11 3j: C22-A: LEU391 A: TRP383–3j: C11 3j-A: ALA350 3j-A: LEU525 3j-A: LEU346 3j-A: ALA350	3.08446 2.90345 2.94721 4.48851 5.80151 4.198 3.45513 3.6513 4.18593 4.18697 4.65689 4.11322 5.05707	Hydrogen Bond Hydrogen Bond Hydrophobic Other Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic
	5-Fluorouracil (PubChem ID: 3385)	61.5565	3385:H10-A: GLU353:O 3385:H11-A: PRO325:O A: GLU353:HA-3385:O3 3385-A: PRO324	1.98323 2.04067 2.77189 4.22361	Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrophobic

Fig. 12: Surface view and 2D diagram of Aurora Kinase (PDB ID: 4ZTR) with ligands 3j, 3d and 5-Fluorouracil

Table 11: Libdock score of ligands against aurora kinase (PDB ID: 4ZTR)

S. No.	PubChem ID	LibDock score
	3a	90.8378
	3b	95.2175
	3c	91.0061
	3d	101.101
	3e	95.7262
	3f	94.2389
	3g	91.4476
	3h	94.289
	3i	96.9217
	3j	100.83
11.	5-Fluorouracil (PubChem ID: 3385)	61.7531

Table 12: Interactions between aurora kinase (PDB ID: 4ZTR) and ligands

S. No.	PubChem ID	Lib dock score	Interacting residues	Bond distance	Nature of bonding
1. 8468	3j	100.83	3j: H26-A: ALA273:O 3j: H28-3j: O6 A: LYS162:NZ-3j A: ALA273-3j: C11 3j: C11-A: LEU194 3j: C12-A: LEU210 3j: C22-A: LEU139 3j: C22-A: LEU263 A: PHE275–3j: C12 3j-A: ARG285 3j-A: LEU139 3j-A: VAL147 3j-A: LEU263	2.6165 2.35338 4.61104 4.09951 4.66683 4.21396 3.92769 4.5939 4.99062 4.89025 5.41605 4.03521 5.22412	Hydrogen Bond Hydrogen Bond Electrostatic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic
2. 78016	3d	101.101	3d: H27–3d: O6 3d: C11-A: ARG285 3d: C12-A: ARG285 3d: C20-A: VAL182 3d: C20-A: LEU196 A: PHE144–3d: C11 A: PHE275–3d: C11 A: PHE275–3d: C20 3d-A: LEU194 3d-A: LEU210 3d-A: ALA273 3d-A: LEU196	2.49988 3.59196 3.37677 4.21815 4.26219 5.28838 5.00919 4.66244 5.37504 5.49187 3.99519 4.7084	Hydrogen Bond Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic Hydrophobic
3.	5-Fluorouracil (PubChem ID: 3385)	61.7531	A: ARG255:HH21-3385:O3 A: ASP274:HN-3385:O3 3385:H10-A: ASP274:O 3385:H11-A: LEU194:O A: ALA273:HA-3385:O3 3385:H12-A: LEU194:O 3385-A: LEU194 3385-A: ALA273	2.56561 2.42453 2.17877 2.20125 2.20819 2.71202 4.95219 4.94942	Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrogen Bond Hydrophobic Hydrophobic

The docked complex of Aurora Kinase (PDB ID: 4ZTR) with top score ligands and standard ligands as shown in fig. 12 wereanalysed to study the interactions between the target and the ligand molecule. The interacting residues, nature of interacting bond and the bond distance are given in table 12.

Docking studies were done with progesterone and estrogen receptors which are involved in the progression and development of breast cancer. Aurora kinase comes under the category of thyrosine kinases. They play an initial role as a regulator of cell growth. Aurora kinase is over expressed in numerous tumours like brain, lung, bladder, colon, breast, head and neck cancers etc.

Rhodanine is a well-known pharmacophore in drug discovery process. A library of compounds was designed and 10 compounds were selected for synthesis. Among the selected 10 derivatives, compounds 3j and 3d showed good docking score for all the 3 targets. Different interactions, bond distance and nature of bonding of 3j and 3d along with standard drug 5-Fluorouracil were studied with 3 different targets.

Docking studies show that all the 10 compounds are energetically favorable in terms of docking score values which ranges from 80.75 to 98.62 for PDBID: IA28 and 77.45 to 90.60 for PDBID: 3ERT and 90.83 to 101.10 for PDBID: 4ZTR

ADME and toxicity prediction

The ligands with comparable scores to other molecules were subjected to predict ADME properties using the toxicity prediction module of the software. The predicted ADME properties are tabulated in table 13.

The drug likeness studies of the ligands were calculated by ADMET descriptors in Discovery studio 2021. The results of ADMET screening showed that all the compounds possess good human intestinal absorption and blood brain barrier (BBB) penetration at 99% confidence levels.

ADMET property of compounds based on the logarithm of the partition coefficient between n-octanol and water (AlogP), polar surface area (PSA), aqueous solubility, plasma protein binding, cytochrome P450 (CYP2D6) binding, blood brain barrier (BBB) penetration, hepatotoxicity, intestinal absorption and ames mutagenicity.

Table 13: ADMET prediction of the ligands

Compounds	Solubility	BBB	CYP2D6	Hepato-toxic	Abs	PBB	A Log P	PSA	Ames mutagenicity
3a	2	1	False	False	0	True	3.186	24.005	Non-Mutagen
3b	2	0	False	True	0	True	4.128	24.005	Non-Mutagen
3c	2	1	False	False	0	True	3.672	24.005	Non-Mutagen
3d	2	0	False	False	0	True	4.826	24.005	Non-Mutagen
3e	2	1	False	True	0	True	3.672	24.005	Non-Mutagen
3f	2	0	False	True	0	True	4.38	24.005	Non-Mutagen
3g	2	1	False	False	0	True	3.883	24.005	Non-Mutagen
3h	2	0	False	False	0	True	4.369	24.005	Non-Mutagen
3i	2	0	False	True	0	True	4.369	24.005	Non-Mutagen
3j	2	0	False	True	0	True	5.077	24.005	Non-Mutagen

Molecular docking helps to find the binding geometry of two interacting molecules with known structures. Docking predicts the preferred orientation of receptor and ligand to each other to form a stable complex. The receptors selected for the in silico studies include ER, PR and Aurora kinase. ER and PR receptors are widely aberrant in breast cancers specifically and contribute significantly to the hormonal resistance to therapy.

In the present study, the docking score of 3j and 3d with ER, PR and Aurora kinase are significantly higher than with other compounds. In vitro studies reveal that 3j is a good anti-oxidant, but did not exert cytotoxicity in MDA-MB-231 cells. MDA-MB-231 cells are ER and PR negative as well as triple negative, rather kind of resistant and aggressive cancer and this possibly explains between the non-correlations with the in silico and in vitro data. The compound 3j and 3d may be active in hormone sensitive cell lines like MCF-7 which are ER and PR positive which will be explored in further studies. Compound 3j was moderately active in HeLa cells, but sometimes HeLa cells also follow aurora kinase independent pathway.

Other compounds which showed good cytotoxic responses in the cell lines need to be further investigated with more protein receptors other than ER, PR and Aurora kinase since cancer cells often follow alternate pathways due to mutations and aberrations which occur continuously. Further mechanistic studies are warranted to understand the molecular mechanism of the compounds in the interaction of genes in more sensitive breast and cervical cancer cell lines.

CONCLUSION

Ten novel rhodanine derivatives were evaluated for their antioxidant and anticancer activity. Antioxidant activity of the test compounds was done by DPPH radical scavenging method. The percentage cytotoxic activity and IC₅₀ values of all the synthesized compounds were predicted. Compound 3j was found to have potent antioxidant activity with an IC₅₀ value of 31.21µg/ml very close to the IC₅₀ value of ascorbic acid which was used as a positive control for the study. The anticancer activity of 5-benzylidene substituted rhodanine derivatives in HeLa and MDAMB-231 cell lines was investigated. Out of 10 compounds, 3a, 3b, 3g and 3h showed good anticancer inhibitory activity against MDAMB-231 cells at 1000 and 500 µg/ml concentrations. The compounds 3e, 3f and 3j showed moderate cytotoxic responses in the breast cancer cells.3b,3f, 3g and 3h showed prominent cytotoxicity at 1000 and 500 µg/ml concentrations on HeLa cells. The compounds 3a, 3c, 3d, 3e and 3j showed moderate cytotoxic responses on the cervical cancer cells. The overall biological and docking results reveals that the compound 3j acts as an excellent class of novel anticancer agents that may lead to the development of more potent anticancer drugs in the future.

ACKNOWLEDGMENT

We would like to thank Dr. Achuthsankar S. Nair, HOD, Department of Computational Biology and Bioinformatics for providing Molecular Docking facility.

FUNDING

Nil

AUTHORS CONTRIBUTIONS

Cici Mathew performed the experimental work and wrote the manuscript. Nandlal helped in drafting and revising the manuscript. Lakshmi S performed the in vitro antioxidant and anticancer evaluation and analysed the data statistically. Aswathy T R performed molecular modeling studies. Joyemma Varkey supervised the work and interpreted the results. All authors contributed accordingly and approved the final manuscript.

CONFLICT OF INTERESTS

Declared none

REFERENCES

1. Sagar P, Cleistanthin RR, Shows B. Apotent cytotoxic activity against colorectal cancer cells. Asian J Pharm Clin Res. 2022 Mar 7;15(3):94-8.

2. Michael RZ. Evaluation of in vitro anticancer activity of aerial parts of Avicennia alba plant methanolic extract against hela and mcf-7 cell lines. Asian J Pharm Clin Res. 2021 Jul 29;14(6):73-9.

3. Sung H, Ferlay J, Siegel RL, Laversanne M, Soerjomataram I, Jemal A. Global cancer statistics 2020: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J Clin. 2021;71(3):209-49. doi: 10.3322/caac.21660, PMID 33538338.

4. Yin LJ, Bin Ahmad Kamar AKD, Fung GT, Liang CT, Avupati VR. Review of anticancer potentials and structure-activity relationships (SAR) of rhodaninederivatives. Biomed Pharmacother. 2022 Jan;145:112406. doi: 10.1016/j.biopha.2021.112406. Epub 2021 Nov 13. PMID 34785416.

5. Mermer A. The importance of rhodanine scaffold in medicinal chemistry: a comprehensive overview. Mini Rev Med Chem. 2021;21(6):738-89. doi: 10.2174/1389557521666201217144954, PMID 33334286.

6. Azizmohammadi M, Khoobi M, Ramazani A, Emami S, Zarrin A, Firuzi O. 2H-chromene derivatives bearing thiazolidine-2,4-dione, rhodanine or hydantoin moieties as potential anticancer agents. Eur J Med Chem. 2013;59:15-22. doi: 10.1016/j.ejmech.2012.10.044. PMID 23202485.

7. Ramesh V, Ananda Rao B, Sharma P, Swarna B, Thummuri D, Srinivas K. Synthesis and biological evaluation of new rhodanine analogues bearing 2-chloroquinoline and benzo[h]quinoline scaffolds as anticancer agents. Eur J Med Chem. 2014;83:569-80. doi: 10.1016/j.ejmech.2014.06.013. PMID 24996143.

8. Ali Muhammad S, Ravi S, Thangamani A. Synthesis and evaluation of some novel N-substituted rhodanines for their anticancer activity. Med Chem Res. 2016;25(5):994-1004. doi: 10.1007/s00044-016-1545-7.

9. Senkiv J, Finiuk N, Kaminskyy D, Havrylyuk D, Wojtyra M, Kril I. 5-Ene-4-thiazolidinones induce apoptosis in mammalian leukemia cells. Eur J Med Chem. 2016;117:33-46. doi: 10.1016/j.ejmech.2016.03.089. PMID 27089210.

10. Szychowski KA, Leja ML, Kaminskyy DV, Binduga UE, Pinyazhko OR, Lesyk RB. Study of novel anticancer 4-thiazolidinone derivatives. Chem Biol Interact. 2017;262:46-56. doi: 10.1016/j.cbi.2016.12.008. PMID 27965178.

11. Min G, Lee SK, Kim HN, Han YM, Lee RH, Jeong DG. Rhodanine-based PRL-3 inhibitors blocked the migration and invasion of metastatic cancer cells. Bioorg Med Chem Lett. 2013;23(13):3769-74. doi: 10.1016/j.bmcl.2013.04.092. PMID 23726031.

12. Havrylyuk D, Mosula L, Zimenkovsky B, Vasylenko O, Gzella A, Lesyk R. Synthesis and anticancer activity evaluation of 4-thiazolidinones containing benzothiazole moiety. Eur J Med Chem. 2010;45(11):5012-21. doi: 10.1016/j.ejmech.2010.08.008. PMID 20810193.

13. Moorthy BT, Ravi S, Srivastava M, Chiruvella KK, Hemlal H, Joy O. Novel rhodanine derivatives induce growth inhibition followed by apoptosis. Bioorg Med Chem Lett. 2010;20(21):6297-301. doi: 10.1016/j.bmcl.2010.08.084. PMID 20832305.

14. James JP, Aiswarya TC, Priya S, Jyothi D, Dixit SR. Structure-based multitargeted molecular docking analysis of pyrazole-condensed heterocyclics against lung cancer. Int J App Pharm. 2021 Nov 7;13(6):157-69. doi: 10.22159/ijap.2021v13i6.42801.

15. Li W, Zhai X, Zhong Z, Li G, Pu Y, Gong P. Design, synthesis and evaluation of novel rhodanine-containing sorafenib analogs as potential antitumor agents. Arch Pharm (Weinheim). 2011;344(6):349-57. doi: 10.1002/ardp.201000326, PMID 21433057.

16. El Nezhawy AOH, Ramla MM, Khalifa NM, Abdulla MM. Synthesis and antioxidant activity of some thiazolidin-4-one derivatives. Monatsh Chem. 2009;140(5):531-9. doi: 10.1007/s00706-008-0085-3.

17. Chen YH, Yang ZS, Wen CC, Chang YS, Wang BC, Hsiao CA. Evaluation of the structure-activity relationship of flavonoids as antioxidants and toxicants of zebrafish larvae. Food Chem. 2012;134(2):717-24. doi: 10.1016/j.foodchem.2012.02.166. PMID 23107683.

18. Berczynski P, Kładna A, Piechowska T, Kruk I, Bozdag Dundar O, Aboul Enein HY. Studies on the antioxidant activity of some thiazolidinedione, imidazolidinedione and rhodanine derivatives having a flavone core. Luminescence. 2014;29(8):1107-12. doi: 10.1002/bio.2667, PMID 24733694.

19. Murphy MP, Holmgren A, Larsson NG, Halliwell B, Chang CJ, Kalyanaraman B. Unraveling the biological roles of reactive oxygen species. Cell Metab. 2011;13(4):361-6. doi: 10.1016/j.cmet.2011.03.010. PMID 21459321.

20. Mathew C, Saraswati B, Lal N, Varkey J. Design, synthesis and antimicrobial studies of 5-benzylidene substituted rhodanine containing heterocycles. Int J Pharm Pharm Sci. 2021;13(5):28-34. doi: 10.22159/ijpps.2021v13i5.40106.

21. Sunitha D. A review on antioxidant methods. Asian J Pharm Clin Res. 2016;9(8):14-32. doi: 10.22159/ajpcr.2016.v9s2.13092.

22. Diller DJ, Merz KM. High throughput docking for library design and library prioritization. Proteins. 2001;43(2):113-24. doi: 10.1002/1097-0134(20010501)43:2<113::aid-prot1023>3.0.co;2-t. PMID 11276081.

23. Lipinski CA, Lombardo F, Dominy BW, Feeney PJ. Experimental and computational approaches to estimate solubility and permeability in drug discovery and development settings. Adv Drug Deliv Rev. 2001;46(1-3):3-26. doi: 10.1016/s0169-409x(00)00129-0, PMID 11259830.

24. Tamilvanan T, Hopper W. High-throughput virtual screening and docking studies of matrix protein vp40 of Ebola virus. Bioinformation. 2013;9(6):286-92. doi: 10.6026/97320630009286, PMID 23559747.

25. Szumilak MA, Lewgowd WA, Stanczak A. In silico adme studies of polyamine conjugates as potential anticancer drugs. Acta Pol Pharm. 2016;73(5):1191-200. PMID 29638059.

26. Kedare SB, Singh RP. Genesis and development of DPPH method of antioxidant assay. J Food Sci Technol. 2011;48(4):412-22. doi: 10.1007/s13197-011-0251-1, PMID 23572765.

27. Khare N, Kapoor A. Antioxidant evaluation of 2,4-thiazolidinedione and rhodanine derivatives. Pharm Lett. 2016;8(14):38-46.

28. Ozen C, Ceylan Unlusoy M, Aliary N, Ozturk M, Bozdag Dundar O. Thiazolidinedione or rhodanine: a study on synthesis and anticancer activity comparison of novel thiazole derivatives. J Pharm Pharm Sci. 2017;20(1):415-27. doi: 10.18433/J38P9R, PMID 29197428.

29. Krithika U, Prabitha P, Mandal SP, Yuvaraj S, Priya D, Wadhwani AD. Development of novel rhodanine analogs as anticancer agents: design, synthesis, evaluation and CoMSIA study. Med Chem. 2021;17(3):216-29. doi: 10.2174/1573406416666200610191002, PMID 32520692.