In Silico Exploration for New Antimalarials: Arylsulfonyloxy Acetimidamides as Prospective Agents.

A strategy is described to identify new antimalarial agents to overcome the drug resistance and/or failure issues through in silico screening of multiple biological targets. As a part of this, three enzymes namely CTPS, CK, and GST were selected, from among 56 drug targets of P. falciparum, and used them in virtual screening of ZINC database entries which led to the design and synthesis of arylsulfonyloxy acetimidamides as their consensus inhibitors. From these, two compounds showed good activity against sensitive (3D7; IC50, 1.10 and 1.45 µM) and resistant (K1; IC50, 2.10 and 2.13 µM) strains of the parasite, and they were further investigated through docking and molecular dynamics simulations. The findings of this study collectively paved the way for arylsulfonyloxy acetimidamides as a new class of antimalarial agents.

Pyridones as NNRTIs against HIV-1 mutants: 3D-QSAR and protein informatics.

CoMFA and CoMSIA based 3D-QSAR of HIV-1 RT wild and mutant (K103, Y181C, and Y188L) inhibitory activities of 4-benzyl/benzoyl pyridin-2-ones followed by protein informatics of corresponding non-nucleoside inhibitors' binding pockets from pdbs 2BAN, 3MED, 1JKH, and 2YNF were analysed to discover consensus features of the compounds for broad-spectrum activity. The CoMFA/CoMSIA models indicated that compounds with groups which lend steric-cum-electropositive fields in the vicinity of C5, hydrophobic field in the vicinity of C3 of pyridone region and steric field in aryl region produce broad-spectrum anti-HIV-1 RT activity. Also, a linker rendering electronegative field between pyridone and aryl moieties is common requirement for the activities. The protein informatics showed considerable alteration in residues 181 and 188 characteristics on mutation. Also, mutants' isoelectric points shifted in acidic direction. The study offered fresh avenues for broad-spectrum anti-HIV-1 agents through designing new molecules seeded with groups satisfying common molecular fields and concerns of mutating residues.

CP-MLR/PLS directed QSAR study on the glutaminyl cyclase inhibitory activity of imidazoles: rationales to advance the understanding of activity profile.

The glutaminyl cyclase inhibitory activity of a series of imidazoles has been analyzed through combinatorial protocol in multiple linear regressions (CP-MLR) and partial least square using different topological and structural descriptors. The QC activity was found to be correlated with 2D-autocorrelation (2DAUTO) and atom centered fragments (ACF) descriptors. The descriptor from 2DAUTO class showed that molecular structure frames of one, six and seven path length associated with atomic van der Waals volumes and polarizability hold scope for modulating QC inhibitory activity. The ACF descriptors suggested that the unsubstituted alkyl fragments and methyl substituted imidazole ring are favorable, while unsaturation in the same and C=N-C≡N are unfavorable for activity. The molar refractivity (MR) is conducive for activity. The descriptors identified in the study collectively highlight the significance of molecular volume and polarizability to the QC inhibitory activity of imidazoles. The models are statistically significant and showed good predictivity.

Molecular Dynamics Simulations of HDAC-ligand Complexes Towards the Design of New Anticancer Compounds.

Quantitative Structure-activity Relationship (QSAR) studies gained a foothold in the mid-1960s to rationalise the biological activity of medicinally important compounds. Since then, the advancements in computer hardware and software added many new techniques and areas to this field of study. Molecular dynamics (MD) simulations are one such technique in direct drug design approaches. MD simulations have a special place in drug design studies because they decode the dynamics of intermolecular interactions between a biological target and its potential ligands/inhibitors. The trajectories from MD simulations provide different non-bonding interaction parameters to assess the compatibility of the protein-ligand complex and thereby facilitate the design of prospective compounds prior to their wet-lab exploration. Histone deacetylases (HDACs) play a key role in epigenetics and they are promising drug targets for cancer and various other diseases. This review attempts to shed some light on the modelling studies of HDAC inhibitors as anticancer agents. In view of the advantages of MD simulations in direct drug design, this review also discusses the fragment-based approach in designing new inhibitors of HDAC8 and HDAC2, starting from the interaction energies of ligand fragments obtained from the MD simulations of respective protein-ligand complexes. Here, the design of new anticancer compounds from largazole thiol, trichostatin A, vorinostat, and several other prototype compounds are reviewed. These studies may stimulate the interest of medicinal chemists in MD simulations as a direct drug design approach for new drug development.

Conformational perturbation of SARS-CoV-2 spike protein using N-acetyl cysteine: an exploration of probable mechanism of action to combat COVID-19.

The infection caused by Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) resulted in a pandemic with huge death toll and economic consequences. The virus attaches itself to the human epithelial cells through noncovalent bonding of its spike protein with the angiotensin-converting enzyme-2 (ACE2) receptor on the host cell. Based on in silico studies we hypothesized that perturbing the functionally active conformation of spike protein through the reduction of its solvent accessible disulfide bonds, thereby disintegrating its structural architecture, may be a feasible strategy to prevent infection by reducing the binding affinity towards ACE2 enzyme. Proteomics data showed that N-acetyl cysteine (NAC), an antioxidant and mucolytic agent been widely in use in clinical medicine, forms covalent conjugates with solvent accessible cysteine residues of spike protein that were disulfide bonded in the native state. Further, in silico analysis indicated that the presence of the selective covalent conjugation of NAC with Cys525 perturbed the stereo specific orientations of the interacting key residues of spike protein that resulted in threefold weakening in the binding affinity of spike protein with ACE2 receptor. Interestingly, almost all SARS-CoV-2 variants conserved cystine residues in the spike protein. Our finding results possibly provides a molecular basis for identifying NAC and/or its analogues for targeting Cys-525 of the viral spike protein as fusion inhibitor and exploring in vivo pharmaco-preventive and its therapeutic potential activity for COVID-19 disease. However, in-vitro assay and animal model-based experiment are required to validate the probable mechanism of action.Communicated by Ramaswamy H. Sarma.

Non-bonding energy directed designing of HDAC2 inhibitors through molecular dynamics simulation.

Designing an inhibitor having strong affinity in the active site pocket is the cherished goal of structure based drug designing. To achieve this, it is considerably important to predict which structural scaffold is better suited for change to increase affinity. We have explored five HDAC2 co-crystals having PDB ligand code-SHH (vorinostat), LLX, 20Y, IWX (BRD4884) and 6EZ (BRD7232). For analyzing protein-ligand interaction at an atomistic level, we have employed the NAMD molecular dynamics (MD) package. The obtained 100 ns long MD trajectories were subjected to quantitative estimations of non-bonding energies (NBEs) for inferring their interactions with the whole protein or its composite active site (CAS). In addition, relative ΔGbind was calculated to rank the inhibitors. These inhibitors' NBEs reveal that the phenyl moieties are the major structural scaffold where modifications should be attempted. We designed new compounds (NCs) via introducing hydroxyl groups at 4,5 position of the phenyl moiety of 6EZ, called NC1. Improvement in NC1 further encouraged us for CAP modification by isochromane and isoindoline moieties in place of oxabicyclooctane in NC1, resulting in NC2 and NC3. We also explored trifluoromethyl oxadiazole in 6EZ (NC4 and NC5) and SHH (NC6 and NC7). This moiety acts as a ZBG in NC4 while acting as a part of the foot-pocket in the rest. NC2 and NC6 have highest favorable NBEs among all studied ligands due increased favorable electrostatic contribution. We expect these NBEs data will provide atomistic level insights and benefit in designing new and improved HDAC2 inhibitors. Communicated by Ramaswamy H. Sarma.

CoMFA and CoMSIA of diverse pyrrolidine analogues as dipeptidyl peptidase IV inhibitors: active site requirements.

The inhibition of dipeptidyl peptidase IV (DPP-IV) has emerged as an attractive target in the treatment of type 2 diabetes. In view of this development, a critical analysis of structural requirements of the DPP-IV inhibitors is envisioned to identify the significant features toward design of selective inhibitors. The comparative molecular field analysis (CoMFA) and comparative molecular similarity indices analysis (CoMSIA) contour plots of pyrrolidine based analogues are used to analyze the structural requirements of a DPP-IV active site. The CoMFA model has shown a cross-validated q (2) of 0.651 with a non-cross-validated r (2) of 0.882 and explained 70.6% variance in the activity of external test compounds. In this, the steric and electrostatic fields have respectively contributed 59.8 and 40.2%, respectively, to the explained activity of the compounds. The CoMSIA model has shown optimum predictivity (cross-validated q (2) = 0.661; non-cross-validated r (2) = 0.803; external test set's predictive r (2) = 0.706) with four molecular fields namely, steric, electrostatic, hydrogen bond (HB)-donor, and HB-acceptor. The contour plots of molecular fields resulting from these studies have suggested: (i) steric restriction with small electron rich substituent at 2- and 3-position of pyrrolidine ring, (ii) presence of electropositive ring linker between the pyrrolidine head and aryl tail, (iii) presence of electron-rich groups around the aryl tail moiety, and (iv) presence of sulfonamide between the ring linker and aryl tail which would increase DPP-IV binding affinity of the compounds. These findings will help in the design of structurally related/new compounds as potential DPP-IV inhibitors.

CP-MLR/PLS directed QSAR study on apical sodium-codependent bile acid transporter inhibition activity of benzothiepines.

The apical sodium-codependent bile acid transporter (ASBT) inhibition activity of benzothiepine derivatives have been analyzed based on topological and molecular features. Analysis of the structural features in conjunction with the biological endpoints in Combinatorial Protocol in Multiple Linear Regression (CP-MLR) led to the identification of 21 descriptors for modeling the activity. The study clearly suggested that the role of Randic shape index (path/walk ratio 3) and topological charges of 2-, 5-, and 6-orders to optimize the ASBT inhibitory activity of titled compounds. The influence of atomic van der Waals volumes, masses, Sanderson electronegativities, and polarizabilities are indicated via different lags of Moran and Geary autocorrelations. Presence of tertiary aromatic amine functionality in molecular structure has also shown its relevance in rationalizing the biological actions of benzothiepines. The PLS analysis has confirmed the dominance of information content of CP-MLR identified descriptors for modeling the activity when compared to those of the leftover ones.

A QSAR study on 2-(4-methylpiperazin-1-yl)quinoxalines as human histamine H4 receptor ligands.

The histamine H(4) receptor binding affinity of 2-(4-methylpiperazin-1-yl)quinoxaline derivatives has been quantitatively analyzed in terms of Dragon descriptors. The derived QSAR models have provided rationales to explain the activity of titled derivatives. The descriptors identified in CP-MLR analysis have highlighted the role of path/walk 4-Randic shape index (PW4), mean square distance (MSD) index, topological charges (GGI9, JGI2, and JGI7), atomic properties in respective lags of 2D-autocorrelations (MATS7e, GATS7e, and MATS8p), and Burden matrix (BELm1) to explain the binding affinity. Certain structural fragments (C-002 and C-027) have also shown prevalence to optimize the H(4)R binding affinity of titled compounds. The PLS analysis has also confirmed the dominance of information content of CP-MLR-identified descriptors for modelling the activity.

Consensus features of CP-MLR and GA in modeling HIV-1 RT inhibitory activity of 4-benzyl/benzoylpyridin-2-one analogues.

The HIV-1 reverse transcriptase (RT) inhibitory activity of benzyl/benzoylpyridinones is modeled with molecular features identified in combinatorial protocol in multiple linear regression (CP-MLR) and genetic algorithm (GA). Among the features, nDB and LogP are found to be the most influential descriptors to modulate the activity. Although the coefficient of nDB suggested in favor of benzylpyridinones skeleton, the coefficient of LogP suggested the favorability of hydrophilic nature in compounds for better activity. The partial least squares analysis of the descriptors common to CP-MLR and GA has displayed their predictivity over the total descriptors identified in both the approaches. The back-propagation artificial neural networks model from the five most significant common descriptors (nDB, T(O..O), MATS8e, LogP, and BELp4) has explained 93.2% variance in the HIV-1 RT activity of the training set compounds and showed a test set r(2) of 0.89. The results suggest that the descriptors have the ability to identify the patterns in the compounds to predict potential analogues.

Investigation of HDAC8-ligands' intermolecular forces through molecular dynamics simulations: profiling of non-bonding energies to design potential compounds as new anti-cancer agents.

Histone deacetylases are zinc-dependent isoform enzymes and play important role in cellular homeostasis. Among these, HDAC8 is a potential anticancer drug target. To design new inhibitors using protein-ligand energy profiles, an all atom molecular dynamics (MD) simulations were carried out on nine HDAC8-ligand co-crystals (PDBs: 1T64, 1T69, 1T67, 3F07, 1W22, 1VKG, 5FCW, 3SFF and 3SFH). TSN, SHH, B3N, AGE, NHB, CRI, 5YA, 0DI and 1DI are ligands of PDBs, respectively. For these HDAC8-ligands, relative Gibbs binding free energy (ΔGbind) from MM/PBSA method and non-bonding energies (NBE) are in agreement with each other (r2=0.678). Therefore, the NBEs are used to analyze ligands' sub-structures, namely zinc-binding, linker and CAP groups. For linker/CAP regions, this identified carbonyl, amide, and sulfonamide moieties as desirable and alkyl/aryl moieties as electrostatically unfavourable. Using this information, systematically new compounds were designed and subjected to MD simulations. This resulted in seven compounds (NC-I to NC-VII) with encouraging energy profiles (NBE: -76.25 to -127.09 kcal/mol; ΔGbind: -17.21 to -57.42 kcal/mol) in comparison to that of the HDAC8 ligands (NBE: -46.25 to -106.29 kcal/mol; ΔGbind: -14.74 to -49.52 kcal/mol). From these, NC-VI showed best energy profile (NBE = -126.15 kcal/mol; ΔGbind = -57.42 kcal/mol) suggesting its binding affinity and thermodynamic stability. In addition to this, NC-II and NC-III have shown promising NBE and ΔGbind profiles. These may serve as lead molecules for exploration against HDAC8 in cancer therapy. This has provided a basis for designing new compounds with improved NBE and ΔGbind profiles by modifying the unfavourable or not so favourable regions of ligands. [Formula: see text] Communicated by Ramaswamy H. Sarma.

Chemometric descriptors in modeling the carbonic anhydrase inhibition activity of sulfonamide and sulfamate derivatives.

The carbonic anhydrase inhibition activities of sulfonamide and sulfamate derivatives have been quantitatively expressed in terms of MOE descriptors representing the 2D-features of compounds following combinatorial protocol in multiple linear regression (CP-MLR). The derived QSAR models have shown that partially charged and polarized surface areas in particular ranges, hydrophobicity, connectivity, information content, van der Waals surface area of the pharmacophore, and certain structural features such as the number of hydrogen and chlorine atoms, aromatic bonds of the molecules hold promise for rationalizing the different carbonic anhydrase inhibitory actions of titled compounds. The values, greater than 0.5 of parameters R(2)(p) and r(2)(m(test)), ensure that the predictions are reliable and acceptable. The derived significant models in such chemometric descriptors may be used to synthesize new potential compounds and to decipher possible mode of actions of these compounds at the molecular level.

Molecular dynamics study of HDAC8-largazole analogues co-crystals for designing potential anticancer compounds.

The X-ray crystal structures of HDAC8 complexed with largazole thiol (LAR, PubChem CID: 56663191) and its synthetic variants (Ligand ID in PDB, PubChem CID: L6G, 91667418; L7G, 91667421; L8G, 91667420) (PDB codes: 3RQD, 4RN0, 4RN2 and 4RN1) were analyzed using molecular dynamics simulations to comprehend protein-ligand nonbonding energies (NBEs). The NBEs of ligands' substructures vis-à-vis active site indicated that pyridyl fragment (F2B4) in L7G and L8G, and amide fragment (F2B5) in LAR and L6G are in high energy states. Based on ligands' substructures and active site residues properties new compounds were designed by introducing phenolic and amidine moieties, respectively, for F2B4 and F2B5. This improved NBEs of new compounds (NC2, -60.93 kcal/mol; NC3, -42.42 kcal/mol). Also, Zn2+ group (substructure F1) of largazoles was modified with that of SAHA and Trapoxin A. Here, the results indicated in favor of Zn2+ group of Trapoxin A. New compound NC6 incorporating aforesaid modifications i.e. phenolic moiety for F2B4, amidine moiety for F2B5 and Zn2+ group of Trapoxin A in F1, offered best interactions with HDAC8 (-89.75 kcal/mol). Thus, the study revealed new depsipeptides as potential HDAC8 inhibitors. AbbreviationsCAScomposite active siteCHARMMchemistry at Harvard Macromolecular MechanicsCUDAcompute unified device architectureHAThistone acetyletransferaseHDAChistone deacetylaseLARlargazole thiol (or) (2R,5R,8R,11R)-5-methyl-8-(propan-2-yl)-11-[(1E)-4-sulfanylbut-1-en-1-yl]-10-oxa-3,17-dithia-7,14,19,20-tetraazatricyclo[14.2.1.1 ∼ 2,5∼]icosa-1(18),16(19)-diene-6,9,13-trioneL6G(5R, 8S,11S)-5-methyl-8-(propan-2-yl)-11-[(1E)-4-sulfanylbut-1-en-1-yl]-3,17-dithia-7,10,14,19,20-pentaazatricyclo[14.2.1.1 ∼ 2,5∼]icosa-1(18),2(20),16(19)-triene-6,9,13-trione)L7G(5R,8S,11S)-5-methyl-8-(propan-2-yl)-11-[(1E)-4-sulfanylbut-1-en-1-yl]-3-thia-7,10,14,17,21-pentaazatricyclo[14.3.1.1 ∼ 2,5∼]henicosa-1(20),2 (21),16,18-tetraene-6,9,13-trioneL8G(5R,8S,11S)-5-methyl-8-(propan-2-yl)-11-[(1E)-4-sulfanylbut-1-en-1-yl]-3-thia-7,10,14,20,21-pentaazatricyclo[14.3.1.1 ∼ 2,5∼]henicosa-1(20),2(21),16,18-tetraene-6,9,13-trioneMDmolecular dynamicsMOEmolecular operating environmentNAMDnanoscale molecular dynamicsNBEnonbonding energyNBEEelectrostatic nonbonding energyNBEVVan der Waals nonbonding energyNBEFnonbonding energy of fragmentNBEFEelectrostatic nonbonding energy of fragmentNBEFVVan der Waals nonbonding energy of fragmentNCnew compound; Rg: radius of gyration;RMSDroot mean square deviationRMSFroot mean square fluctuationVMDvisual molecular dynamics.Communicated by Ramaswamy H. Sarma.

Synthesis and biological evaluation of 2,3,4-triarylbenzopyran derivatives as SERM and therapeutic agent for breast cancer.

A novel class of 2,3,4-triarylbenzopyrans has been synthesized and were evaluated for their selective estrogen receptor modulation activity and as a therapeutic agent for breast cancer. Among the compounds synthesized, compounds 11a and 12c exhibited 73.91% and 69.24% inhibition as estrogen antagonistic activity, respectively. Compound 12a showed the lowest IC(50) at 6.97 microM against MCF-7 and 11f showed the lowest IC(50) value of 5.6 microM against MDA-MB-231 cell line in spite of their low receptor binding affinity implicating these compounds probably act through ER independent mechanism.

Topological descriptors in modelling antimalarial activity: N(1)-(7-chloro-4-quinolyl)-1,4-bis(3-aminopropyl)piperazine as prototype.

The QSAR of antimalarial activity of two distinct series of N(1)-(7-chloro-4-quinolyl)-1,4-bis(3-aminopropyl) piperazine analogues are investigated with DRAGON descriptors in order to rationalize their activity. Of these two series of compounds, one has amide characteristics and the other has amine characteristics. Both the analogues have shared radial centric information (ICR) as common modelling descriptor with increased centricity in the molecules as preferred feature for antimalarial activity. Apart from this, the models of amide analogues suggested in favor of distantly placed nitrogen(s) and unfavorable nature of carbonyl moieties adjacent to nitrogen in the varying portion of the molecule for the activity. Moreover, for these analogues, the regression models have preferred the lone pair electrons on heteroatoms (N and O) for purposes other than H-bonds for better activity. In case of amine analogues, the models suggested in favor of compact structural moieties in the varying parts of the molecule for improved activity. Also, for these analogues, hydrophobicity of the compound is an important factor for influencing activity. The variations in the models of amide and amine analogues are attributed to the characteristic functional differences of these analogues.

[Technology of analysis of epigenetic and structural changes of epithelial tumors genome with NotI-microarrays by the example of human chromosome].

New comparative genome hybridization technology on NotI-microarrays is presented (Karolinska Institute International Patent WO02/086163). The method is based on comparative genome hybridization of NotI-probes from tumor and normal genomic DNA with the principle of new DNA NotI-microarrays. Using this method 181 NotI linking loci from human chromosome 3 were analyzed in 200 malignant tumor samples from different organs: kidney, lung, breast, ovary, cervical, prostate. Most frequently (more than in 30%) aberrations--deletions, methylation,--were identified in NotI-sites located in MINT24, BHLHB2, RPL15, RARbeta1, ITGA9, RBSP3, VHL, ZIC4 genes, that suggests they probably are involved in cancer development. Methylation of these genomic loci was confirmed by methylation-specific PCR and bisulfite sequencing. The results demonstrate perspective of using this method to solve some oncogenomic problems.

QSAR study about ATP-sensitive potassium channel activation of cromakalim analogues using CP-MLR approach.

The structure-activity models of the myorelaxant activity of the cromakalim analogues have been investigated with nearly 470 topological descriptors from DRAGON software using Combinatorial Protocol in Multiple Linear Regression (CP-MLR). Among the descriptor classes considered in the study, the binding affinity is correlated with simple functional (FUN), topological (TOPO), atom centered fragments (ACF), empirical (EMP), modified Burden eigenvalues (BCUT), Galvez topological charge indices (GVZ), 2D-autocorrelation (2D-AUTO) and constitutional (CONS) descriptors. The models developed, and the participating descriptors suggest that the substituent groups of 4,6-disubstituted-2,2-dimethylchromans hold scope for further modification in the optimization of activity. The higher path lengths rich in polarizability and lower path length rich in atomic mass in addition to the lower charge indices of the molecule are beneficiary to the activity. The participating descriptors also suggested that certain structural features such as carbon atoms attached to the heteroatom by single or multiple bonding, and lesser or 'no' branching in a molecule are helpful to augment the activity.

QSAR studies on benzoylaminobenzoic acid derivatives as inhibitors of beta-ketoacyl-acyl carrier protein synthase III.

Fatty acid biosynthesis is essential for most of the bacterial survival. Components of this biosynthetic pathway have been identified as attractive targets for the development of new antibacterial agents. FabH, beta-ketoacyl-ACP synthase III, is a attractive target since it is central to the initiation of fatty acid biosynthesis. Quantitative structure-activity relationship (QSAR) studies have been carried out on a series of benzoylaminobenzoic acid derivatives as potent inhibitors of FabH and antibacterial activity against Staphylococcus aureus, Streptococcus pneumoniae, Streptococcus pyogenes, Enterococcus faecalis, Neisseria meningitidis and Escherichia coli, which demonstrate FabH inhibitory activity in cell free and whole cell system. The QSAR studies revealed that inhibitory activity increases with increase in hydrophobicity, molar refractivity, aromaticity, and presence of OH group (on x position of the nucleus). On the other side presence of hetero-atoms like N, O, or S at R(1) position of the nucleus decreases the inhibitory activity. The comparison of QSAR between the FabH inhibitory activity and antibacterial activity against S. aureus, S. pneumoniae, S. pyogenes, E. faecalis, N. meningitidis also demonstrates that the hydrophobicity, aromaticity and presence of OH group (on x position of the nucleus) are conducive for the inhibitory activity.

C-3 alkyl/arylalkyl-2,3-dideoxy hex-2-enopyranosides as antitubercular agents: synthesis, biological evaluation, and QSAR study.

A series of C-3 alkyl and arylalkyl 2,3-dideoxy hex-2-enopyranoside derivatives were synthesized by Morita-Baylis-Hillman reaction using enulosides 4, 5, and 6 and various aliphatic and aromatic aldehydes. The compounds were evaluated in vitro for the complete inhibition of growth of Mycobacterium tuberculosis H37Rv. They exhibited moderate to good activity in the range of 25-1.56 mug/mL. Among these, 4d, 4h, 5c, and 4hr showed activity at minimum inhibitory concentrations, 3.12, 6.25, 1.56, and 1.56 mug/mL, respectively. These compounds were safe against cytotoxicity in VERO cell line and mouse macrophage cell line J 744A.1. A QSAR analysis by CP-MLR with alignment-free 3D-descriptors indicated the relevance of structure space comparable to the minimum energy conformation (from conformational analysis) of 5c to the activity. The study indicates that the compounds attaining the conformational space of 5c and reflecting some symmetry, minimum eccentricity, and closely placed geometric and electronegativity centers therein are favorable for activity.

Spiro-oxindole derivative 5-chloro-4',5'-diphenyl-3'-(4-(2-(piperidin-1-yl) ethoxy) benzoyl) spiro[indoline-3,2'-pyrrolidin]-2-one triggers apoptosis in breast cancer cells via restoration of p53 function.

Breast cancer remains a significant health problem due to the involvement of multiple aberrant and redundant signaling pathways in tumorigenesis and the development of resistance to the existing therapeutic agents. Therefore, the search for novel chemotherapeutic agents for effective management of breast cancer is still warranted. In an effort to develop new anti-breast cancer agents, we have synthesized and identified novel spiro-oxindole derivative G613 i.e. 5-chloro-4',5'-diphenyl-3'-(4-(2-(piperidin-1-yl) ethoxy) benzoyl) spiro[indoline-3,2'-pyrrolidin]-2-one, which has shown growth inhibitory activity in breast cancer cells. The present study was aimed to explore the mechanism of anti-tumorigenic action of this newly identified spiro-oxindole compound. Compound G613 inhibited the Mdm2-p53 interaction in breast cancer cells and tumor xenograft. It caused restoration of p53 function by activating its promoter activity, triggering its nuclear accumulation and preventing its ubiquitination and proteasomal degradation. Supportively, molecular docking studies revealed considerable homology in the docking mode of G613 and the known Mdm2 inhibitor Nutlin-3, to p53 binding pocket of Mdm2. The activation of p53 led to upregulation of p53 dependent pro-apoptotic proteins, Bax, Pumaα and Noxa and enhanced interaction of p53 with bcl2 member proteins thus triggering both transcription-dependent and transcription-independent apoptosis, respectively. Additionally, the compound decreased estrogen receptor activity through sequestration of estrogen receptor α by p53 thereby causing a decreased transcriptional activation and expression of proliferation markers. In conclusion, G613 represents a potent small-molecule inhibitor of the Mdm2-p53 interaction and can serve as a promising lead for developing a new class of anti-cancer therapy for breast cancer patients.