Identification and characterization of impurities in an insecticide, commercial chlorantraniliprole using liquid chromatography-tandem mass spectrometry.

RATIONALE: Ensuring the global safety and effectiveness of agrochemicals has become imperative. An in-depth understanding of impurity profiles of products is crucial, especially for high-demand agrochemicals, where impurities may be more toxic and persistent than original agrochemicals. This study focuses on the detection and identification of impurities in a commercial chlorantraniliprole (CAP), an anthranilic diamide class broad-spectrum insecticide. METHODS: Commercial CAP was collected from an agrochemical supplier in India and was analyzed using a high-performance liquid chromatography-photodiode array (HPLC-PDA) (Agilent 1260; wavelength, 220 nm) with a Zorbax RP SB-C18 (250 × 4.6 mm, 5 µm) column and liquid chromatography-mass spectrometry (LC-MS) (Agilent 6545 quadrupole time of flight (Q-TOF)) techniques to identify the impurities. The impurities were isolated by preparative HPLC using a Zorbax-DB C18 (250 × 9.4 mm, 5 µm) column. liquid chromatography- tandem mass spectrometry (LC-MS/MS) experiments (Q-TOF) were performed on CAP and its impurities to obtain their structural data. RESULTS: HPLC-PDA analysis of CAP showed four major impurities (IM-1 to IM-4) ranging from 0.76% to 4.1%. The positive ion electrospray ionization (ESI) mass spectra of CAP and its impurities showed dominant [M + H]+ ions in addition to [M + Na]+ , [M + K]+ , and [2M + Na]+ ions. High-resolution mass spectrometry (HRMS) data provided the elemental composition of the compounds, and isotopic distribution patterns revealed the number of Cl and/or Br atoms present in them. The structures of impurities were proposed based on the LC-MS/MS) data and further confirmed by nuclear magnetic resonance (NMR) data on isolated impurities/synthesis. CONCLUSION: The quality and impurities of CAP, a popular insecticide, must be assessed and described for its efficacy and safety. In this study, four impurities of CAP were detected using HPLC and successfully characterized using LC-HRMS, LC-MS/MS, and NMR data. The method is useful for verifying the purity of CAP as well as helping in the identification of its possible impurities.

N-Substituted piperazine-coupled imidazo[2,1-b]thiazoles as inhibitors of Mycobacterium tuberculosis: Synthesis, evaluation, and docking studies.

An innovative series of N-substituted piperazine-linked imidazothiazole derivatives 7(a-x) were synthesized, and their antitubercular effectiveness was evaluated. A three-step reaction sequence involving the condensation of 1,3-dichloroacetone and thiourea, coupling with substituted piperazines to give the intermediates 5(a-d) and cyclization with substituted α-bromoacetophenones produced the desired imidazothiazole derivatives 7(a-x) in excellent yields. In vitro screening of new derivatives against Mycobacterium tuberculosis H37Rv resulted in 7k (minimum inhibitory concentration [MIC]: 0.78 µg/mL) and 7g and 7h (MIC: 1.56 µg/mL) as potent hit compounds. Further, the docking studies of the promising compounds 7k, 7g, and 7h revealed that the best molecular interactions are with the DprE1 in complex with sulfonyl PBTZ of M. tuberculosis as the target protein (PDB ID: 6G83).

Dihydrobenzothiazole coupled N-piperazinyl acetamides as antimicrobial agents: Design, synthesis, biological evaluation and molecular docking studies.

Substituted saturated N-heterocycles have gained momentum as effective scaffolds for the development of new drugs. In this study, we coupled partly saturated benzothiazoles with substituted piperazines and evaluated their antimicrobial activity. Following a three-step reaction sequence from commercially available cyclic 1,3-diones, a series of novel 2-[4-substituted-1-piperazinyl]-N-(7-oxo-4,5,6,7-tetrahydrobenzo[d]thiazol-2-yl)acetamides (7a-af) were synthesised. 2-Amino-5,6-dihydro-benzo[d]thiazol-7(4H)-ones, obtained through the condensation of cyclohexane-1,3-diones with thiourea, were acetylated with chloroacetic chloride and then reacted with N-substituted piperazines 6a-p to give the desired products 7a-af in excellent yields. All 32 new compounds were fully characterised by their 1 H-nuclear magnetic resonance (NMR), 13 C-NMR and high-resolution mass spectrometry spectra. The synthetic compounds 7a-af were tested in vitro for their efficacy as antimicrobials against pathogenic strains of Gram-positive and Gram-negative bacteria, Streptococcus mutans and Salmonella typhi, respectively, as well as against fungal strains, including Candida albicans 3018 and C. albicans 4748. Ciprofloxacin and fluconazole served as the reference drugs. While compounds 7c and 7l showed inhibition against fungal strains with zones of inhibition of 11 and 1 mm, respectively, four analogues (7d, 7l, 7n, and 7r) demonstrated strong antibacterial action (zone of inhibition in the range of 10-15 mm). Three compounds (7j, 7l, and 7w) also exhibited moderate antitubercular activity (MIC: 6.25 µg/mL) against Mycobacterium tuberculosis H37Rv. Molecular docking investigations and the predicted physicochemical and ADMET (absorption, distribution, metabolism, excretion, and toxicity) properties for the potent compounds made this scaffold useful as a pharmacologically active framework for the development of potential antimicrobial hits.

Exploration of efficacy, cellular responses, and safety profile of novel 9-(3-Pyridyl) noscapine derivatives as promising anticancer candidates.

This study presented a novel derivative of the antitussive compound noscapine, named 9-3-Pyridyl noscapine (PYNos), to enhance its anticancer potential. Through in silico investigations, PYNos exhibited strong interactions with microtubules, inhibiting cancer cell proliferation both alone and in combination with docetaxel. Docking scores highlighted the affinity of PYNos -5.67 kcal/mol and docetaxel -4.94 kcal/mol to microtubules. When docked with tubulin-DOX co-complex, PYNos displayed a synergistic score of -8.99 kcal/mol. MTT assays on MCF-7 breast cancer cells showed PYNos IC50 values of 11.0 µM (48 h) and 8.4 µM (72 h), while docetaxel had three orders of magnitude lower IC50 values: 0.028 µM (48 h) and 0.015 µM (72 h). Combining PYNos (25 µM) and docetaxel (0.01 µM) reduced proliferation by 50% at both time points. Isobologram analysis confirmed strong antiproliferative synergy (sum FIC <1) at 48 and 72 h. Our comprehensive evaluation encompassing apoptosis and cell cycle arrest patterns further validated the synergistic advantages of this combination. In a xenograft mice model using MCF-7 cells, the PYNos-docetaxel co-treatment resulted in significant tumor regression, showcasing promising induction of apoptosis while mitigating docetaxel-associated toxicity. In summary, our findings underscore the substantial microtubule interactions facilitated by 9-3-Pyridyl noscapine, revealing its synergistic potential with docetaxel and establishing a solid foundation for advancing cancer therapeutic strategies.Communicated by Ramaswamy H. Sarma.

Rational design of novel microtubule targeting anticancer drugs N-imidazopyridine noscapinoids: Chemical synthesis and experimental evaluation based on in vitro using breast cancer cells and in vivo using xenograft mice model.

We present N-imidazopyridine-noscapinoids, a new class of noscapine derivatives that bind to tubulin and exhibit antiproliferative activity against triple positive (MCF-7) and triple negative (MDA-MB-231) breast cancer cells. The N-atom of the isoquinoline ring of noscapine scaffold was altered in silico by coupling the imidazo [(Ye et al., 1998; Ke et al., 2000) 1,21,2-a] pyridine pharmacophore to rationally develop a series of N-imidazopyridine-noscapinoids (7-11) with high tubulin binding affinity. The predicted ΔGbinding of the N-imidazopyridine-noscapinoids 7-11 varied from -27.45 to -36.15 kcal/mol, a much lower value than noscapine with ΔGbinding -22.49 kcal/mol. The cytotoxicity of N-imidazopyridine-noscapinoids was evaluated using hormone dependent MCF-7, triple negative MDA-MB-231 breast cancer cell lines and primary breast cancer cells. The cytotoxicity of these compounds (represented as IC50 concentration) ranges between 4.04 and 33.93 µM against breast cancer cells without affecting normal cells (IC50 value > 952 µM). All the compounds (7-11) perturbed the cell cycle progression at G2/M phase and triggered apoptosis. Among all the N-imidazopyridine-noscapinoids, N-5-Bromoimidazopyridine-noscapine (9) showed promising antiproliferative activity and was selected for detailed investigation. The onset of apoptosis treated with 9 using MDA-MB-231 revealed morphological changes like cellular shrinkage, chromatin condensation, membrane blebbing, and apoptotic bodies formation. Along with elevated reactive oxygen species (ROS), there was a loss of mitochondrial membrane potential, suggesting induction of apoptosis to cancer cells. Compound 9 was also found to significantly regress the implanted tumour in nude mice as xenografts of MCF-7 cells without any apparent side effects after drug administration. We conclude that N-imidazopyridine-noscapinoids possess excellent potential as a promising drug for treating breast cancers.

Identification and Characterization of the Isomeric Impurity of the Fungicide "Cyazofamid".

Identification and characterization of biproducts/ impurities present in agrochemicals are critical in view of their efficacy and safety towards public health. We herein present our study on identification and characterization of an impurity, 5-chloro-2-cyano-N,N-dimethyl-4-p-tolylimidazole-1-sulfonamide (2) present in the fungicide, "cyazofamid". Intermittent HPLC analysis of the reaction of substituted imidazole (1) with N,N-dimethylsulfamoyl chloride suggested that 2 is formed during the reaction. Isolation by preparative HPLC and characterization by NMR, LC/HRMS, MS/MS and single crystal XRD analysis confirmed 2 as an isomer of cyazofamid, wherein the N,N-dimethyl sulfonamide group was positioned on the other nitrogen of imidazole in close proximity to chloride group. Computational studies further supported the formation of 2 and ruled out the other possible isomeric structures.

Assessment of uremic toxins in advanced chronic kidney disease patients on maintenance hemodialysis by LC-ESI-MS/MS.

INTRODUCTION: In the advanced stage of chronic kidney disease (CKD), electrolytes, fluids, and metabolic wastes including various uremic toxins, accumulate at high concentrations in the patients' blood. Hemodialysis (HD) is the conventional procedure used worldwide to remove metabolic wastes. The creatinine and urea levels have been routinely monitored to estimate kidney function and effectiveness of the HD process. This study, first from in Indian perspective, aimed at the identification and quantification of major uremic toxins in CKD patients on maintenance HD (PRE-HD), and compared with the healthy controls (HC) as well as after HD (POST-HD). OBJECTIVES: The study mainly focused on the identification of major uremic toxins in Indian perspective and the quantitative analysis of indoxyl sulfate and p-cresol sulfate (routinely targeted uremic toxins), and phenyl sulfate, catechol sulfate, and guaiacol sulfate (targeted for the first time), apart from creatinine and urea in PRE-HD, POST-HD, and HC groups. METHODS: Blood samples were collected from 90 HD patients (both PRE-HD and POST-HD), and 74 HCs. The plasma samples were subjected to direct ESI-HRMS and LC/HRMS for untargeted metabolomics and LC-MS/MS for quantitative analysis. RESULTS: Various known uremic toxins, and a few new and unknown peaks were detected in PRE-HD patients. The p-cresol sulfate and indoxyl sulfate were dominant in PRE-HD, the concentrations of phenyl sulfate, catechol sulfate, and guaiacol sulfate were about 50% of that of indoxyl sulfate. Statistical evaluation on the levels of targeted uremic toxins in PRE-HD, POST-HD, and HC groups showed a significant difference among the three groups. The dialytic clearance of indoxyl sulfate and p-cresol sulfate was found to be < 35%, while that of the other three sulfates was 50-58%. CONCLUSION: LC-MS/MS method was developed and validated to evaluate five major uremic toxins in CKD patients on HD. The levels of the targeted uremic toxins could be used to assess kidney function and the effectiveness of HD.

Antiproliferative Noscapinoids Bearing an Amidothiadiazole Scaffold as Apoptosis Inducers: Design, Synthesis and Molecular Docking.

Noscapine an FDA-approved antitussive agent. With low cytotoxicity with higher concentrations, noscapine and its derivatives have been shown to have exceptional anticancer properties against a variety of cancer cell lines. In order to increase its potency, in this study, we synthesized a series of new amido-thiadiazol coupled noscapinoids and tested their cytotoxicity in vitro. All of the newly synthesised compounds demonstrated potent cytotoxic potential, with IC50 values ranging from 2.1 to 61.2 µM than the lead molecule, noscapine (IC50 value ranges from 31 to 65.5 µM) across all cell lines, without affecting normal cells (IC50 value is>300 µM). Molecular docking of all these molecules with tubulin (PDB ID: 6Y6D, resolution 2.20 Å) also revealed better binding affinity (docking score range from -5.418 to -9.679 kcal/mol) compared to noscapine (docking score is -5.304 kcal/mol). One of the most promising synthetic derivatives 6aa (IC50 value ranges from 2.5 to 7.3 µM) was found to bind tubulin with the highest binding affinity (ΔGbinding is -28.97 kcal/mol) and induced apoptosis in cancer cells more effectively.

Aryl-n-hexanamide linked enaminones of usnic acid as promising antimicrobial agents.

Lichen secondary metabolites are well explored medicinal agents with diverse pharmacological properties. One of the important antibiotic lichen secondary metabolites is usnic acid. Its diverse medicinal profiles prompted us to explore it as a potential antitubercular molecule. Towards this direction, continuing our efforts on the discovery and development of new analogs with potent antitubercular properties we designed, synthesized, and evaluated a set of 37 usnic acid enaminone-coupled aryl-n-hexanamides (3-39). The study yielded a 3,4-dimethoxyphenyl compound (13, 5.3 µM) as the most active anti-TB molecule. The docking studies were performed on 7 different enzymes to better understand the binding modes, where it was observed that compound 13 bound strongly with glucose dehydrogenase (Gscore: - 9.03). Further antibacterial investigations revealed compound 2 with potent inhibition on Salmonella typhi and Bacillus subtilis (MIC 3 µM) and MIC values of 7 and 14 µM on Streptococcus mutans and Escherichia coli respectively. Compound 19 (3-F-5-CF3-phenyl) displayed encouraging antibacterial profiles against E. coli, S. typhi and S. mutans with MIC values of 10 µM respectively. Interestingly, compound 20 (2,6-difluorophenyl) also displayed good antibacterial activity against E. coli with an MIC value of 6 µM. These encouraging pharmacological results will help for better designing and developing usnic acid-based semi-synthetic derivatives as potential antimicrobial agents. A set of 37 new usnic acid enaminone-coupled aryl-n-hexanamides were synthesized and evaluated as potential antimicrobial agents. Compound 13 was identified as the most active antitubercular molecule. 13 was further docked against 7 different enzymes of tuberculosis. The molecule displayed maximum binding energy with the enzyme Glucose dehydrogenase (Gscore: - 9.03), indicating that these hexanamides possibly act by inhibiting the glucose metabolic pathway of the bacterium. Surprisingly, the intermediate hexanoic acid 2 was identified as potent antibacterial agent, acting on both gram-positive and gram-negative bacterial strains (3-14 µM). The active compounds may be subjected to structural iterations to develop further leads.

Catalyst- and Additive-Free Methodical Ring Expansion Protocol to Access Benzooxepino-Fused Pyrroles.

An efficient metal-free, additive-free synthetic method was developed to access benzooxepino-fused pyrrole derivatives from alkynyl substituted aziridines. In this organic transformation, two new C-C bonds were formed via initial cleavage of C-C bond of aziridine ring by in situ generated azomethine ylides. Moderate to excellent yields of benzooxepino-fused pyrroles were obtained atom economically in the presence of t-BuOH in one-pot.

Substrate-directed Synthesis of Isocoumarin and 3-Ylidenephthalide Conjugated Noscapinoids and their Antiproliferative Activities.

A series of new noscapinoids designed; synthesized and assessed whether its 3-ylidenephthalide and isocoumarin conjugates improved cytotoxicity. Cu-catalysed Sonogashira coupling of N-propargyl noscapine with 2-bromobenzoic acids followed by in-situ substrate-directed 5-exo-dig or 6-endo-dig cyclization produced 3-ylidenephthalide 6 a-6 f and isocoumarin 7 a-7 h analogues in very good yields. In comparison to the lead drug, noscapine, all the newly synthesised derivatives exhibited strong cytotoxic potential in vitro with IC50 ranging from 5.4 µM to 39.5 µM across the evaluated panel of cancer cell lines, without harming normal cells (IC50 >300 µM).

Autophagic and apoptotic cell death induced by the quinoline derivative 2-(6-methoxynaphthalen-2-yl)quinolin-4-amine in pancreatic cancer cells is via ER stress and inhibition of Akt/mTOR signaling pathway.

Pancreatic cancer (PC) is among the most lethal cancers and is resistant to existing therapies, which highlights the need for new and alternative therapeutic treatments. Autophagy is emerging as one of the alternative cell death mechanisms and is well known to cross-talk with apoptosis. Autophagy can act as a viable option to treat highly resistant PC. The current study investigates and provides insight into the autophagic and apoptotic cell death induced by quinoline derivative 2-(6-methoxynaphthalen-2-yl)quinolin-4-amine (6MN-4-AQ) in PC cell lines PANC-1 and MIA PaCa-2. Treatment with 6MN-4-AQ reduced cell viability in concentration dependent manner (2-16 µM) and inhibited the clonogenic potential of PC cells at a concentration of 4 µM for 24 h. Further, we found that 6MN-4-AQ induced both apoptosis and autophagic cell death simultaneously. We identified that 6MN-4-AQ induced autophagic cell death by forming cytoplasmic vacuoles, the elevation of autophagy flux, increase in LC3-II, Beclin-1 protein expression, and degradation of p62. Moreover, 6MN-4-AQ induced apoptosis via Caspase-3 activation and cleavage of PARP in PC cells. Upon investigating the underlying mechanism associated with 6MN-4-AQ induced cell death, it was observed that 6MN-4-AQ treatment is able to suppress the Akt/mTOR pathway and induced ER stress leading to the induction of autophagy. Also, 6MN-4-AQ treatment suppressed epithelial to mesenchymal transition by reducing the protein expression of SLUG, snail, and vimentin. Subsequently, 6MN-4-AQ inhibited cell migration and invasion by down regulating MMP-7 and MMP-9 protein expression, suggesting that 6MN-4-AQ may serve as a plausible therapeutic agent for PC.

9-Ethynyl noscapine induces G2/M arrest and apoptosis by disrupting tubulin polymerization in cervical cancer.

Noscapine is a phthalide isoquinoline alkaloid present in the latex of Papaver somniferum and has demonstrated potent antitumor activity in various cancer models. Structural changes in the core molecule of noscapine architecture have produced a number of potent analogs. We have recently synthesized the novel noscapine analogs (3, 4, and 5) with different functional groups appended at ninth position of natural noscapine. The anticancer activity of these compounds has been investigated using various human cancer cell lines such as HeLa (cervical cancer), DU-145 (prostate cancer), MCF-7 (breast cancer), and IMR-32 (neuroblastoma). One of the compounds in this series, 9-ethynyl noscapine (5), has demonstrated good anticancer activity against HeLa cells. Biological studies demonstrated that compound 5 decreased cell viability and colony formation in HeLa cells in a concentration dependent manner. To further uncover the mechanism in detail, we evaluated compound 5 effect on cell cycle progression, microtubule dynamics, and apoptosis. Cell cycle and western blotting analysis revealed that 9-ethynyl noscapine treatment resulted in cell cycle arrest at G2/M and decreased CDK1 and cyclinB1 protein expression. We also observed that 9-ethynyl noscapine (5) treatment leads to disruption in tubulin polymerization and induction of apoptosis by decreasing expression of bcl2, pro-caspase 3, and activation of cytochrome C. Taken together, our results indicate that 9-ethynyl noscapine (5) effectively supresses the growth of cervical cancer cells (HeLa) by disrupting tubulin polymerization, cell cycle progression leading to apoptosis.

In silico design of novel tubulin binding 9-arylimino derivatives of noscapine, their chemical synthesis and cellular activity as potent anticancer agents against breast cancer.

We present a series of 9-arylimino derivatives of noscapine (an antitussive plant alkaloid) that binds to tubulin and displaying anticancer activity against a panel of breast cancer cells. These compounds were rationally designed by coupling of Schiff base containing imine groups at position-9 of the isoquinoline ring of noscapine. Based on a combination of Glide docking and free energy of binding (FEB) calculation, we have screened a panel of three 9-compounds, 12-14 with improved binding affinity with tubulin compared to noscapine. The predicted FEB is -6.166 kcal/mol for 12, -6.411 kcal/mol for 13 and -7.512 kcal/mol for 14. In contrast, the predicted FRB of noscapine is -5.135 kcal/mol. These novel derivatives were strategically synthesized and validated their anticancer activity based on cellular studies using two human breast adenocarcinoma, MCF-7 and MDAMB-231, as well as with a panel of primary breast tumor cells isolated from patients. Interestingly, all these derivatives inhibited cellular proliferation in all the cancer cells that ranged between 3.6 and 26.4 µM, which is 11.02-2.03 fold lower than that of noscapine. Unlike previously reported derivatives of noscapine that arrest cells in the S-phase, these novel derivatives effectively inhibit proliferation of cancer cells, arrest the cell cycle in the G2/M-phase and induced apoptosis. Thus, we conclude that 9-arylimino derivatives of noscapine have great potential to be a novel therapeutic agent for breast cancers.Communicated by Ramaswamy H. Sarma.

Development of 1,3-diynyl derivatives of noscapine as potent tubulin binding anticancer agents for the management of breast cancer.

We developed 1,3-diynyl derivatives of noscapine (an opium alkaloid) through in silico combinatorial approach and screened out a panel of promising derivatives that bind tubulin and display anticancer activity. The selected derivatives such as 9-4-tBu-Ph-Diyne (20p), 9-3,4-Di-Cl-Diyne (20k) and 9-3,4-Di-F-Diyne (22s) noscapinoids revealed improved predicted binding energy of -6.676 kcal/mol for 20p, -7.294 kcal/mol for 20k and -7.750 kcal/mol for 20s respectively in comparison to noscapine (-5.246 kcal/mol). These 1,3-diynyl derivatives (20p, 29k and 20s) were strategically synthesized in high yields by regioselective modification of noscapine scaffold and HPLC purified (purity is >96%). The decrease in intrinsic fluorescence of purified tubulin to 8.39%, 17.39% and 25.47% by 20p, 20k and 20s respectively, compared to control suggests their binding capability to tubulin. Their cytotoxicity activity was validated based on cellular studies using two human breast adenocarcinoma (MCF-7 and MDA-MB-231), a panel of primary breast tumor cells and one normal human embryonic kidney cell (293 T). The 1,3-diynyl noscapinoids, 20p, 20k and 20s inhibited cellular proliferation in all the cancer cells that ranged between 6.2 and 38.9 µM, without affecting the normal healthy cells (cytotoxicity is <5% at 100 µM). Further, these novel derivatives arrest cell cycle in the G2/M-phase, followed by induction of apoptosis to cancer cells. Thus, we conclude that 1,3-diynyl-noscapinoids have great potential to be a novel therapeutic agent for breast cancers.Communicated by Ramaswamy H. Sarma.

Combination of docetaxel and newly synthesized 9-Br-trimethoxybenzyl-noscapine improve tubulin binding and enhances antitumor activity in breast cancer cells.

To strategically design and frame the novel 9-Br-Trimethoxybenzyl noscapine (BTN) with rigorous binding affinity with tubulin, the structure of noscapine (an antitussive plant alkaloid) was amended with a 3,4,5-trimethoxybenzyl group linked at the seventh position on the lower isobenzofuran unit. Molecular modelling and cellular studies were used to assess the single and combined effects of BTN and docetaxel (DOX). Based on MM-GBSA, the individual calculated free energies of binding (ΔGbind, pred) for BTN and DOX with tubulin was found to be -25.69 and -38.17 kcal/mol, respectively, and -29.11 and -36.60 kcal/mol based on MM-PBSA. Furthermore, the ΔGbind,pred of BTN was dramatically reduced (-30.02 and -33.54 kcal/mol using MM-GBSA and MM-PBSA) in presence of DOX on its binding pocket. Parenthetically, the ΔGbind,pred of DOX was substantially decreased (-39.17 and -35.80 kcal/mol using MM-GBSA and MM-PBSA) in the presence of BTN on its binding pocket. The synergistic activity of both compounds on tubulin dimmer was also analysed using purified tubulin, where a combined regimen of BTN and DOX attenuated tubulin intensity to a higher value (50%) particularly in comparison to the single regimen. In comparison to the single regimen, the combination of BTN and DOX effectively prevents cell cycle progression during the G2/M phase and induces breast cancer cell death. Female athymic nude mice were xenografted with MCF-7 cells and the efficacy of (150 mg/kg/day), DOX (1.5 mg/kg/week, i.v.), or in combination (BTN 300 mg/kg/day + DOX 1.0 mg/kg/week, i.v) were evaluated.

Synergistic interaction of N-3-Br-benzyl-noscapine and docetaxel abrogates oncogenic potential of breast cancer cells.

Noscapine, an opium alkaloid, was discovered to bind tubulin, arrest dividing cells at mitosis, and selectively induce apoptosis to cancer cells. N-3-Br-Benzyl-Noscapine (Br-Bn-Nos), one of the derivatives of noscapine, was demonstrated to have improved anticancer potential compared with noscapine. We approached to evaluate the single and combined effect of Br-Bn-Nos and docetaxel (DOX) based on molecular modeling and cellular study. The individual predicted free energy of binding (∆Gbind,pred ) for Br-Bn-Nos and DOX with tubulin was found to be -28.89 and -36.07 kcal/mol based on molecular mechanics generalized Born solvation area (MM-GBSA) as well as -26.21 and -34.65 kcal/mol based on molecular mechanics Poisson Boltzmann solvation area (MM-PBSA), respectively. However, the ∆Gbind,pred of Br-Bn-Nos was significantly reduced (-33.02 and -30.24 kcal/mol using MM-GBSA and MM-PBSA) in the presence of DOX on its binding pocket. Parenthetically, the ∆Gbind,pred of DOX was significantly reduced (-37.17 and -32.80 kcal/mol using MM-GBSA and MM-PBSA) in the presence of Br-Bn-Nos on its binding pocket. The reduced ∆Gbind,pred in the presence of Br-Bn-Nos and DOX together indicated a combination effect of both the ligands. The combined interaction of both the agents onto tubulin dimmer was also determined experimentally using purified tubulin, in which a combination regimen of Br-Bn-Nos and DOX reduced the fluorescence intensity of tubulin to a higher value (68%) compared with the single regimen. Further, isobologram analysis revealed the synergistic effect of Br-Bn-Nos and DOX in antiproliferative activity using MCF-7 cell line at 48 hr (sum FIC = 0.49) and at 72 hr (sum FIC = 0.62). The combination dose regimen of Br-Bn-Nos and DOX blocks the cell cycle progression at the G2/M phase and induces apoptosis to cancer cells more effectively compared with the single regimen. Taken together, our study provides compelling evidence that the anticancer potential of noscapine derivatives may be substantially improved when it is used in a combined application with DOX for breast cancer.

Rational design of novel N-alkyl amine analogues of noscapine, their chemical synthesis and cellular activity as potent anticancer agents.

The scaffold structure of noscapine (an antitussive plant alkaloid) was modified by inducting N-aryl methyl pharmacophore at C-9 position of the isoquinoline ring to rationally design and screened three novel 9-(N-arylmethylamino) noscapinoids, 15-17 with robust binding affinity with tubulin. The selected 9-(N-arylmethylamino) noscapinoids revealed improved predicted binding energy of -6.694 kcal/mol for 15, -7.118 kcal/mol for 16 and -7.732 kcal/mol for 17, respectively in comparison to the lead molecule (-5.135 kcal/mol). These novel derivatives were chemically synthesized and validated their anticancer activity based on cellular studies using two human breast adenocarcinoma, MCF-7 and MDA-MB-231, as well as with a panel of primary breast tumor cells. These derivatives inhibited cellular proliferation in all the cancer cells that ranged between 3.2 and 32.2 µM, which is 11.9 to 1.8 fold lower than that of noscapine. These novel derivatives effectively arrest the cell cycle in the G2/M phase followed by apoptosis and appearance of apoptotic cells. Thus, we conclude that 9-(N-arylmethyl amino) noscapinoids, 15-17 have a high probability to be a novel therapeutic agent for breast cancers.

Rational design, chemical synthesis and cellular evaluation of novel 1,3-diynyl derivatives of noscapine as potent tubulin binding anticancer agents.

We present a new class of derivatives of noscapine, 1,3-diynyl-noscapinoids of an antitussive plant alkaloid, noscapine based on our in silico efforts that binds tubulin and displays anticancer activity against a panel of breast cancer cells. Structure-activity analyses pointed the C-9 position of the isoquinoline ring which was modified by coupling of 1,3-diynyl structural motifs to rationally design and screened a series of novel 1,3-diynyl-noscapinoids (20-22) with robust binding affinity with tubulin. The selected 1,3-diynyl-noscapinoids, 20-22 revealed improved predicted binding energy of -6.568 kcal/mol for 20, -7.367 kcal/mol for 21 and -7.922 kcal/mol for 22, respectively in comparison to the lead molecule (-5.246 kcal/mol). These novel derivatives were chemically synthesized and validated their anticancer activity based on cellular studies using two human breast adenocarcinoma, MCF-7 and MDAMB-231, as well as with a panel of primary breast cancer cells isolated from patients. Interestingly, all these derivatives inhibited cellular proliferation in all the cancer cells that ranged between 6.2 to 38.9 µM, which is 6.7 to 1.5 fold lower than that of noscapine. Unlike previously reported derivatives of noscapine that arrests cells in the S-phase, these novel derivatives effectively inhibit proliferation of cancer cells, arrests cell cycle in the G2/M-phase followed by apoptosis and appearance of apoptotic cells. Thus, we conclude that 1,3-diynyl-noscapinoids have great potential to be a novel therapeutic agent for breast cancers.

Induction of microtubule hyper stabilization and robust G2 /M arrest by N-4-CN in human breast carcinoma MDA-MB-231 cells.

AIM: Elucidation of the antiproliferative efficacy and mechanism of action of a design-optimized noscapine analog, N-4-CN. METHODS: Cell viability was studied using an MTT assay. The drug-tubulin interactions were investigated using spectrofluorometry. The architectural defects, hyper stabilization, and recovery competence of cellular microtubules were studied using immunofluorescence microscopy. DCF-DH and rhodamine 123 were used as probes to to examine the levels of reactive oxygen species and the loss of mitochondrial membrane potential, respectively. Flow cytometry revealed the cell cycle progression pattern of the drug-treated cells. KEY FINDINGS: Among the cell lines tested, N-4-CN showed the strongest inhibition of the viability of the triple-negative breast cancer (TNBC) cell line MDA-MB-231(IC50 , 2.7 ± 0.1 µmol/L) and weakest inhibition of the noncancerous epithelial cell line, VERO (IC50 , 60.2 ± 3 µmol/L). It perturbed tertiary structure of tubulin and stabilized colchicine binding to the protein. In cells, N-4-CN hyperstabilized the microtubules, and prevented the recovery of cold-depolymerized microtubules. Its multitude of effects on tubulin and microtubules facilitated cell cycle arrest and subsequent cell death that were complemented by elevated levels of reactive oxygen species (ROS). SIGNIFICANCE: Owing to its ability to perturb a well-defined cancer drug target, tubulin, and to promote ROS-facilitated apoptosis, N-4-CN could be investigated further as a potential therapeutic against many neoplasms, including TNBC.