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.

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.

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.

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.

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.

Synthesis, biological evaluation and molecular modeling studies of new 2,3-diheteroaryl thiazolidin-4-ones as NNRTIs.

In a focused exploration, thiazolidin-4-ones with different C-2 and N-3 substituent groups were synthesized and evaluated as non-nucleoside reverse transcriptase inhibitors against HIV-1. This has led to new active compounds sporting heteroaryls at both C-2 and N-3 positions prompting to view them in the backdrop of nevirapine. To assign the molecular attributes for the activity, the compounds are investigated by docking them into non-nucleoside inhibitor-binding pocket of HIV-1 reverse transcriptase (RT). The most active compounds of this series (7d and 7f) shared spatial features with nevirapine with added molecular flexibility. Furthermore, in molecular dynamics simulations carried out for up to 10 ns, the compounds 7d and 7f showed consistency in their interactions with non-nucleoside inhibitor-binding pocket of HIV-1 RT and suggested Tyr319 and Val106 as potential residues for H-bond interaction with these molecules. These results open new avenues for the exploration of 2,3-diheteroaryl thiazolidin-4-ones for prevention of HIV-1.

Target based drug design - a reality in virtual sphere.

The target based drug design approaches are a series of computational procedures, including visualization tools, to support the decision systems of drug design/discovery process. In the essence of biological targets shaping the potential lead/drug molecules, this review presents a comprehensive position of different components of target based drug design which include target identification, protein modeling, molecular dynamics simulations, binding/catalytic sites identification, docking, virtual screening, fragment based strategies, substructure treatment of targets in tackling drug resistance, in silico ADMET, structural vaccinology, etc along with the key issues involved therein and some well investigated case studies. The concepts and working of these procedures are critically discussed to arouse interest and to advance the drug research.

Synthesis of 2,3,6-trideoxy sugar triazole hybrids as potential new broad spectrum antimicrobial agents.

Here, we describe a molecular hybridization inspired design and synthesis of novel 6-triazolyl 2,3,6-trideoxy sugars as promising new broad-spectrum antimicrobial agents using click chemistry in key step. These compounds showed MIC between 0.39 and 50 µg/mL against different native and resistant bacteria and fungi with no toxicity. Among them, compound 29 was the most active molecule with MIC 0.78 µg/mL against Staphylococcus aureus and Klebsiella pneumoniae and 3.12 µg/mL against methicillin- and vancomycin-resistant S. aureus. Compound 26 was the most potent anti-fungal candidate with MIC 0.39 µg/mL against Trichophyton mentagrophytes. Compound 46 was found to be promising with broad-spectrum activity against both bacterial and fungal strains. The bioinformatic studies involving bacteria's protein co-crystals prompted penicillin binding protein-2 as the most likely target of these compounds.

Graph theory concepts in the rationales of anti HIV-1 compounds.

Drug research is a multidisciplinary as well as resource intensive endeavor. In this the center of attention is biological response of an agent which gives the first insight of the activity (or receptor) space in the backdrop of chemical landscape. Here, molecular topology has significant role in explaining and exploring different phenomena associated with the chemical entities. Thus it provides direction to the design of therapeutic agents. In the backdrop the review highlighted the contribution of topological indices from different concepts in the HIV-1 drug research. In this article selected reports dealing with the topological descriptors in the QSARs of the anti-HIV-1 compounds acting as reverse transcriptase, protease and integrase inhibitors are appraised and elaborated.

Topological and physicochemical characteristics of 1,2,3,4-Tetrahydroacridin- 9(10H)-ones and their antimalarial profiles: a composite insight to the structure-activity relation.

The study reports the QSAR rationales from multilateral approaches for the antimalarial activities (against W2 and TM90-C2B strains of Plasmodium falciparum) and physical properties (aqueous solubility, permeability and logD) of 1,2,3,4-tetrahydroacridin-9(10H)-one (THA) derivatives. A modification to Free-Wilson matrix (parameter set) is introduced to improve the compound to parameter ratio of the analysis carried out in the study. The models from modified Free-Wilson and physicochemical parameters suggest that 5(th) (R1) and 8(th) (R4) positions of THA scaffold should be free from substitution for the antimalarial activity against both the strains. The THA' s 6(th) (R2) and 7(th) (R3) positions' substituents with a blend of hydrophobicity and polarity offer scope to modulate the activities of these compounds. The substituent group contributions derived here gives opportunity to examine various combinations possible from these analogues. The models from the topological and other structural indices has suggested that MLOGP, LP1 and JGI6 as three common important features for activity against W2 and TM90 strains. The topological indices participated in the models suggested a preference for longer path lengths in molecules for better activity against both strains. The PLS analysis of the descriptors identified in the feature selection approach, combinatorial protocol in multiple linear regression (CP-MLR), has suggested that MATS3e and nRORPh are best suited to modulate the W2 activity, and Me, T(S..F) and ARR are best suited to modulate the TM90 activity. In these derivatives the analysis of aqueous solubility, permeability and logD has suggested that most of the R1 and R4 substituents have contributed with same arithmetic sign to theses properties. For all other variations in these compounds, the permeability increased with increasing logD and decreased with increasing aqueous solubility. The results suggest ways for the activity-property modulation in these analogues.

Chemotherapeutic Potential of 2-[Piperidinoethoxyphenyl]-3-Phenyl-2H-Benzo(b)pyran in Estrogen Receptor- Negative Breast Cancer Cells: Action via Prevention of EGFR Activation and Combined Inhibition of PI-3-K/Akt/FOXO and MEK/Erk/AP-1 Pathways.

Inhibition of epidermal growth factor receptor (EGFR) signaling is considered to be a promising treatment strategy for estrogen receptor (ER)-negative breast tumors. We have investigated here the anti-breast cancer properties of a novel anti-proliferative benzopyran compound namely, 2-[piperidinoethoxyphenyl]-3-phenyl-2H-benzo(b)pyran (CDRI-85/287) in ER- negative and EGFR- overexpressing breast cancer cells. The benzopyran compound selectively inhibited the EGF-induced growth of MDA-MB 231 cells and ER-negative primary breast cancer cell culture. The compound significantly reduced tumor growth in xenograft of MDA-MB 231 cells in nude mice. The compound displayed better binding affinity for EGFR than inhibitor AG1478 as demonstrated by molecular docking studies. CDRI-85/287 significantly inhibited the activation of EGFR and downstream effectors MEK/Erk and PI-3-K/Akt. Subsequent inhibition of AP-1 promoter activity resulted in decreased transcription activation and expression of c-fos and c-jun. Dephosphorylation of downstream effectors FOXO-3a and NF-κB led to increased expression of p27 and decreased expression of cyclin D1 which was responsible for decreased phosphorylation of Rb and prevented the transcription of E2F- dependent genes involved in cell cycle progression from G1/S phase. The compound induced apoptosis via mitochondrial pathway and it also inhibited EGF-induced invasion of MDA-MB 231 cells as evidenced by decreased activity of MMP-9 and expression of CTGF. These results indicate that benzopyran compound CDRI-85/287 could constitute a powerful new chemotherapeutic agent against ER-negative and EGFR over-expressing breast tumors.

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.

Modeling of LIM-Kinase 2 inhibitory activity of pyrrolopyrimidine analogues: useful in treatment of ocular hypertension and glaucoma.

The LIM-Kinase 2 (LIMK2) inhibitory activity of a series of pyrrolopyrimidine analogs has been analyzed through combinatorial protocol in multiple linear regressions (CP-MLR) and partial least square (PLS) using different descriptors obtained from DRAGON software. The empirical, topological and charge descriptors have led to statistically significant QSAR models and showed good external predictivity as reflected in test set R2 values (0.782 to 0.888). The obtained structure-activity correlations underlined the significance of bulkiness and molecular polarizability in improving the activity. The topological descriptors suggested that open chain or branched substituents are favorable while cyclic /ring substituents are unfavorable for the activity. The descriptors identified in the study showed that pyrrolopyrimidine scaffold holds scope for modulating LIMK2 inhibitory activity. The study gives a direction for further exploration of chemical space of pyrrolopyrimidine analogs as LIMK2 inhibitors.

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.

Discovery of triazine mimetics as potent antileishmanial agents.

The World Health Organization has classified the leishmaniasis as a major tropical disease. The discovery of new compounds for leishmaniasis is therefore a pressing concern for the anti-infective research program. We have synthesized 19 compounds of triazine dimers as novel antileishmanial agents. Most of the synthesized derivatives exhibited better activity against intracellular amastigotes (IC50 ranging from 0.77 to 10.32 µM) than the control, pentamidine (IC50 = 13.68 µM), and are not toxic to Vero cells. Compounds 14 and 15 showed significant in vivo inhibition of 74.41% and 62.64%, respectively, in L. donovani/hamster model. Moreover, expansion of Th1-type and suppression of Th2-type immune responses proved that compound 14 stimulates mouse macrophages to prevent the progression of leishmania parasite. The molecular docking studies involving PTR1 protein PDB further validated the concepts involved in the design of these compounds. Among the investigated analogues, compound 14 has emerged as the potential one to enlarge the scope of the study.

Cypermethrin induces astrocyte apoptosis by the disruption of the autocrine/paracrine mode of epidermal growth factor receptor signaling.

Cypermethrin is reported to affect astrocytes in rat brain; however, its mechanism of action is obscure. Here, we observed an increase in apoptosis in the cortical astrocytes upon treatment of rats with cypermethrin. We then characterized the mechanism governing the apoptosis. Because the epidermal growth factor receptor (EGFR) signaling regulates the survival of astrocytes, we investigated the effect of cypermethrin on EGFR activation. The astrocytes exhibited an early and irreversible attenuation in the basal EGFR phosphorylation. Supportively, molecular docking studies revealed considerable homology in the docking mode of cypermethrin and the known EGFR inhibitors, erlotinib and AG1478, to the kinase domain of EGFR. Furthermore, treatment with cypermethrin demonstrated a downregulation in the intracellular and secreted levels of heparin-binding epidermal growth factor (HB-EGF), an EGFR ligand. AG1478 reduced the synthesis of HB-EGF, suggesting the dependence of HB-EGF on EGFR activation. In addition, a neutralizing antibody against HB-EGF diminished the basal EGFR levels, indicating ligand-dependent expression of EGFR. Likewise, cypermethrin caused irreversible suppression in the basal EGFR levels, which induced apoptosis in astrocytes. The apoptosis was prevented by exogenous HB-EGF. These data imply an autocrine/paracrine mode of action of HB-EGF-EGFR in astrocyte survival. Consequently, cypermethrin induced a mitochondria-mediated apoptosis, characterized by rise in Bax/Bcl-2 ratio and cleavage of caspase-9, -3, and -7, and the effect was prevented by HB-EGF. HB-EGF activated the extracellular signal-regulated kinases and AKT pathways that protected against apoptosis. Together, these data demonstrate that cypermethrin induces astrocyte apoptosis by disrupting the autocrine/paracrine mode of HB-EGF-EGFR signaling at two levels, irreversible loss of basal EGFR and downregulation of HB-EGF.

Specific targeting of insulin-like growth factor 1 receptor signaling in human estrogen dependent breast cancer cell by a novel tyrosine-based benzoxazepine derivative.

The present study sought to investigate the in vitro and in vivo effects of a tyrosine-based benzoxazepine, 4-[4-(toluene-4-sulfonyl)-2,3,4,5-tetrahydro-benzo[f][1,4]oxazepin-3-ylmethyl]-phenol) [THBP] in human breast cancer cells, with a focus on determining its molecular target. THBP had growth inhibitory effect on MCF-7 and MDA-MD-231 cells. At IC(50) value (∼20 µM), THBP resulted in G1 arrest, decrease in cyclin D1 levels and induction of apoptosis of MCF-7 cells. Mechanistically, activation of caspase 8 contributes critically to the induction of apoptotic cell death as copresence of selective inhibition of caspase 8 effectively abrogates the cytotoxic effect of THBP in MCF-7 cells. Further, THBP increased pro-apoptotic protein, Bax; decreased anti-apoptotic protein, Bcl-2; and decreased mitochondrial membrane potential in MCF-7 cells, indicating involvement of an intrinsic pathway of apoptosis following caspase 8 activation. Out of the various growth factors/hormones, THBP selectively abrogated increased viability of MCF-7 cells by insulin-like growth factor 1 (IGF-1). Molecular docking studies revealed that THBP occupied the ATP binding pocket of IGF-1 receptor (IGF-1R). Accordingly THBP was found to inhibit IGF-1-induced phosphorylation of IGF-1R and insulin receptor substrate-1 (IRS-1) without inhibiting insulin signaling in MCF-7 cells. In athymic nude mice, compared with vehicle, THBP treatment significantly reduced the growth of MCF-7 xenograft tumors through inhibition of cancer cell proliferation as well as promotion of cell death that correlated with reduced phospho-IGF-1R levels. We suggest that interfering with the IGF-1R signaling by the benzoxazepine THBP offers a novel and selective therapeutic strategy for estrogen receptor-positive, postmenopausal breast cancer patients.