Anuradha Cm

Exploring the molecular basis for selective binding of Mycobacterium tuberculosis Asp kinase toward its natural substrates and feedback inhibitors: A docking and molecular dynamics study

Tuberculosis (TB) is still a major public health problem, compounded by the human immunodeficiency virus (HIV)-TB co-infection and recent emergence of multidrug-resistant (MDR) and extensively drug resistant (XDR)-TB. In this context, aspartokinase of mycobacterium tuberculosis has drawn attention for designing novel anti-TB drugs. Asp kinase is an enzyme responsible for the synthesis of 4-phospho-L-aspartate from L-aspartate and involved in the branched biosynthetic pathway leading to the synthesis of amino acids lysine, threonine, methionine and isoleucine. An intermediate of lysine biosynthetic branch, mesodiaminopimelate is also a component of the peptidoglycan which is a component of bacterial cell wall. To interfere with the production of all these amino acids and cell wall, it is possible to inhibit Asp kinase activity. This can be achieved using Asp kinase inhibitors. In order to design novel Asp kinase inhibitors as effective anti-TB drugs, it is necessary to have an understanding of the binding sites of Asp kinase. As no crystal structure of the enzyme has yet been published, we built a homology model of Asp kinase using the crystallized Asp kinase from M. Jannaschii, as template structures (2HMF and 3C1M). After the molecular dynamics refinement, the optimized homology model was assessed as a reliable structure by PROCHECK, ERRAT, WHAT-IF, PROSA2003 and VERIFY-3D. The results of molecular docking studies with natural substrates, products and feedback inhibitors are in agreement with the published data and showed that ACT domain plays an important role in binding to ligands. Based on the docking conformations, pharmacophore model can be developed by probing the common features of ligands. By analyzing the results, ACT domain architecture, certain key residues that are responsible for binding to feedback inhibitors and natural substrates were identified. This would be very helpful in understanding the blockade mechanism of Asp kinase and providing insights into rational design of novel Asp kinase inhibitors for M.tuberculosis.

Synthesis and evaluation of resveratrol derivatives as new chemical entities for cancer.

Resveratrol has been shown to be active in inhibiting multistage carcinogenesis. The potential use of resveratrol in cancer chemoprevention or chemotherapy settings has been hindered by its short half-life and low bioavailability. Considering the above remarks, using resveratrol as a prototype, we have synthesized two derivatives of resveratrol. Their activity was evaluated using in vitro and in silico analysis. Biological evaluation of resveratrol analogues on U937 cells had shown that two synthesized analogues of resveratrol had higher rates of inhibition than the parental molecule at 10μM concentration. EMSA conducted for NF-kB revealed that these molecules significantly interfered in the DNA binding ability of NF-kB. It was found that these molecules suppressed the expression of TNFα, TNFR, IL-8, actin and activated the expression of FasL, FasR genes. To understand possible molecular mechanism of the action we performed docking and dynamic studies, using NF-kB as a receptor. Results showed that resveratrol, RA1 and RA2 interacted with the residues involved in DNA binding. Resveratrol analogues by interacting NF-kB might have prevented its translocation and also by interacting with the residues involved in DNA binding might have prevented the binding of NF-kB to DNA. This may be the reason for suppression of NF-kB binding to DNA.

Experimental and Computational Studies on Newly Synthesized Resveratrol Derivative: A New Method for Cancer Chemoprevention and Therapeutics?

Nature has been a provenance of medicinal agents for thousands of years. Resveratrol (RESL) is a naturally occurring polyphenolic compound in food stuffs such as peanuts, seeds, berries, grapes, and beverages (red wine). RESL has received significant attention due to a plethora of in vitro and in vivo reports on its cancer chemopreventive and therapeutic properties. In the present study, diacetate RESL derivative (RESL43) was synthesized. The RESL43 displayed potent cytotoxicity and triggered apoptosis in U937 cells as evidenced by poly (ADP-ribose) polymerase (PARP) cleavage, DNA fragmentation, morphological changes, and activation of FasR and FasL genes. The electrophoretic mobility shift assay revealed the suppression NFkB activity in U937 cells after treatment with RESL43 in corroboration with the deactivation of NFkB dependent genes such as IL-8, TNFR, and TNFα. Furthermore, molecular docking and dynamics studies have shown that RESL and RESL43 might exert their inhibitory activity on NFkB by altering the intramolecular binding abilities between DNA and NFkB. Taken together, RESL43 can have greater putative activity than parental RESL in a context of cancer chemoprevention and therapeutics. We suggest that the diacetate resveratrol derivative RESL43 warrants further evaluation in preclinical and clinical bridging studies in the near future.

Molecular characterization of Mtb-OMP decarboxylase by modeling, docking and dynamic studies

Tuberculosis (TB), the second most deadly disease in the world is caused by Mycobacterium tuberculosis (Mtb). In the present work a unique enzyme of Mtb orotidine 5′ monophosphate decarboxylase (Mtb-OMP Decase) is selected as drug target due to its indispensible role in biosynthesis of pyrimidines. The present work is focused on understanding the structural and functional aspects of Mtb-OMP Decase at molecular level. Due to absence of crystal structure, the 3D structure of Mtb-OMP Decase was predicted by MODELLER9V7 using a known structural template 3L52. Energy minimization and refinement of the developed 3D model was carried out with Gromacs 3.2.1 and the optimized homology model was validated by PROCHECK,WHAT-IF and PROSA2003. Further, the surface active site amino acids were quantified by WHAT-IF pocket. The exact binding interactions of the ligands, 6-idiouridine 5′ monophosphate and its designed analogues with the receptor Mtb-OMP Decase were predicted by docking analysis with AUTODOCK 4.0. This would be helpful in understanding the blockade mechanism of OMP Decase and provide a candidate lead for the discovery of Mtb-OMP Decase inhibitors, which may bring insights into outcome new therapy to treat drug resistant Mtb.

Exploring the Binding Affinity of Novel Syringic Acid Analogues and Critical Determinants of Selectivity as Potent Proteasome Inhibitors

Syringic acid, a known plant phenolic compound and its analogues are known to possess high proteasome inhibitory activity. In the current work, we describe synthesis, characterization, DFT, docking of syringic acid (SA) and analogues (SAA1 and SAA2) and biological effects were studied. Syringic acid and its analogues were docked for the first time with the crystal structures of β5 proteasome of diverse eukaryotic organisms. Among all proteasomes, the humanoid proteasome showed the highest degree of docking conformation and low inhibition constant (Ki). SAA2 specifically displayed binding to the N-terminal Thr1 residue in the S1 pocket of Mus musculus β5 proteasome along with threonine, lysine and arginine; conventionally involved major amino acid residues in ligand binding. The geometrical properties (B3LYP/6- 31g (d, p)) and electrostatic potentials of molecules were computed using DFT calculations. A detailed molecular picture of the compounds and its interactions was obtained from NBO analysis. SA-analogues elucidated potent antioxidant activities and good antibacterial activity. In-vitro DNA binding studies revealed that all molecules had strong binding at the major groove of dsDNA. In the view of medical applicability, proteasome inhibition is an important therapeutic strategy for various types of cancers. Therefore, current discoveries may encourage the rational design and development of new chemical entities of syringic acid based chemotherapeutics.

Syringic acid (SA) ‒ A Review of Its Occurrence, Biosynthesis, Pharmacological and Industrial Importance

The use of phytochemicals in control of human diseases have been considerable public and scientific interest in current days. Syringic acid (SA), a phenolic compound often found in fruits and vegetables and which is synthesized via shikimic acid pathway in plants. It shows a wide range of therapeutic applications in prevention of diabetes, CVDs, cancer, cerebral ischemia; as well as it possess anti-oxidant, antimicrobial, anti-inflammatory, antiendotoxic, neuro and hepatoprotective activities. It has an effective free radical scavenger and alleviates the oxidative stress markers. The therapeutic property of SA is attributed by the presence of methoxy groups onto the aromatic ring at positions 3 and 5. The strong antioxidant activity of SA may confer its beneficial effects for human health. SA has the potential to modulate enzyme activity, protein dynamics and diverse transcription factors involved in diabetes, inflammation, cancer and angiogenesis. In vivo experimental data and histopathological studies on SA activity has delineated its possible therapeutic mechanisms. Besides usage in biomedical field, SA has greater industrial applications in bioremediation, photocatalytic ozonation, and laccase based catalysis. The present review deals about SA natural sources, biosynthesis, bioavailability, biomedical applications (in vivo and in vito. The review addresses basic information about molecular mechanisms, therapeutic and industrial potential of SA.

Design, Synthesis and Evaluation of Pyrazolo-Pyrazole Derivatives onMethylisocitratelyase Of Pseudomonas aeruginosa:Insilico and invitro study.

Pseudomonas aeruginosa is an opportunistic micro-organism causing diseases both in animals and humans. In case of human pathology, the role of P. aeruginosa is one of the major concerns in intensive care septicemia. Presently, the drug resistance strains of P. aeruginosa are arising mainly by developing multiple mechanisms due to its natural and acquired resistance to many of the antimicrobial agents commonly used in clinical practice. As a result, there is a direct need to invent new drugs so that they may restrict the outbreak of multidrug resistant strains. Virtual high-throughput insilico screening, which helps to identify the chemical ligands that bind to the enzymes, is an important tool in drug discovery and the drugs discovered in this way are clinically tested. In this study, Methylisocitratelyase (MICL), which is essential for the survival of the bacterium and which doesn’t show any similarity with the humans, was selected to evaluate the functions of high-affinity inhibitors (PPI-analogs) that are identified using the virtual screening approach. By adopting the computational analysis tools, structural, functional, and inhibitor interactions of MICL against P. aeruginosa were identified. The PPIA-32 is found to be the best binding interactions with MICL. PPIA-32 reduces the binding affinity for substrate to residues required for MICL enzyme activity and also Root Mean Square Deviation simulations show the most stable nature of PPA32-MICL(complex) than that of MICL alone, thereby effectively inhibiting the growth of virulent P. aeruginosa. To our surprise, the same phenomenon is also identified with other gram-negative bacteria like Escherichia coli, Klebsiella pneumoniae, and Salmonella typhi.