Your search keyword '"Lovika Mittal"' showing total 8 results

1. Characterizing (un)binding mechanism of <scp>USP7</scp> inhibitors to unravel the cause of enhanced binding potencies at allosteric checkpoint

Author

Mitul Srivastava, Lovika Mittal, Anita Kumari, Ashish Kumar Agrahari, Mrityunjay Singh, Rajani Mathur, and Shailendra Asthana

Subjects

Molecular Biology, Biochemistry

Published

2022

2. Binding mode characterization of 13b in the monomeric and dimeric states of SARS-CoV-2 main protease using molecular dynamics simulations

Author

Anita Kumari, Mitul Srivastava, Shailendra Asthana, and Lovika Mittal

Subjects

0303 health sciences, Polyproteins, Stereochemistry, Dimer, 030303 biophysics, General Medicine, Alanine scanning, Ligand (biochemistry), 03 medical and health sciences, chemistry.chemical_compound, Residue (chemistry), Molecular recognition, Protein structure, chemistry, Structural Biology, Binding site, Molecular Biology

Abstract

The main protease, Mpro/3CLpro, plays an essential role in processing polyproteins translated from viral RNA to produce functional viral proteins and therefore serve as an attractive target for discovering COVID-19 therapeutics. The availability of both monomer and dimer crystal bound with a common ligand, ‘13b’ (α-ketoamide inhibitor), opened up opportunities to understand the Mpro mechanism of action. A comparative analysis of both forms of Mpro was carried out to elucidate the binding site architectural differences in the presence and absence of ‘13b’. Molecular dynamics simulations suggest that the presence of ‘13b’ enhances the stability of Mpro than the unbound APO form. The N- and C- terminals of both the protomers stabilize each other, and making it's interface essential for the active form of Mpro. In comparison to monomer, the relatively high affinity of ‘13b’ is gained in dimer pocket due to the high stability of the pocket by the interaction of S1 residue of chain B with residues F140, E166 and H172 of chain A, which is absent in monomer. The comprehensive essential dynamics, protein structure network analysis and thermodynamic profiling highlight the hot-spots, pivotal in molecular recognition process at protein-ligand and protein-protein interaction levels, cross-validated through computational alanine scanning study. A comparative description of ‘13b’ binding mechanism in both forms illustrates valuable insights into the inhibition mechanism and the selection of critical residues suitable for the structure-based approaches for the identification of more potent Mpro inhibitors. Communicated by Ramaswamy H. Sarma

Published

2021

3. Discovery of non-nucleoside oxindole derivatives as potent inhibitors against dengue RNA-dependent RNA polymerase

Author

Venkatanarayana Chowdary Maddipati, Lovika Mittal, Jaskaran Kaur, Yogita Rawat, Chandra Prakash Koraboina, Sankar Bhattacharyya, Shailendra Asthana, and Rambabu Gundla

Subjects

Organic Chemistry, Drug Discovery, Molecular Biology, Biochemistry

Abstract

A series of thiazole linked Oxindole-5-Sulfonamide (OSA) derivatives were designed as inhibitors of RNA-dependent RNA polymerase (RdRp) activity of Dengue virus. These were synthesized and then evaluated for their efficacy in ex-vivo virus replication assay using human cell lines. Among 20 primary compounds in the series, OSA-15 was identified as a hit. A series of analogues were synthesized by replacing the difluoro benzyl group of OSA-15 with different substituted benzyl groups. The efficacy of OSA-15derivatives was less than that of the parent compound, except OSA-15-17, which has shown improved efficacy than OSA-15. The further optimization was carried out by adding dimethyl (DM) groups to both the sulfonamide and oxindole NH's to produce OSA-15-DM and OSA-15-17-DM. These two compounds were showing no detectable cytotoxicity and the latter was more efficacious. Further, both these compounds were tested for inhibition in all the serotypes of the Dengue virus using an ex-vivo assay. The EC

Published

2022

4. Molecular Dynamics Simulations Reveal the Interaction Fingerprint of Remdesivir Triphosphate Pivotal in Allosteric Regulation of SARS-CoV-2 RdRp

Author

Mitul Srivastava, Anita Kumari, Lovika Mittal, and Shailendra Asthana

Subjects

Coronavirus disease 2019 (COVID-19), QH301-705.5, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), viruses, Allosteric regulation, remdesivir, medicine.disease_cause, NTP entrance site, allosteric inhibition, Biochemistry, Genetics and Molecular Biology (miscellaneous), Biochemistry, Molecular dynamics, chemistry.chemical_compound, RNA polymerase, medicine, Molecular Biosciences, Biology (General), Molecular Biology, Original Research, Coronavirus, FEL, PCA, Chemistry, RNA, Cell biology, SARS-CoV-2 RNA-dependent RNA polymerase (RdRp), molecular dynamics simulation, Docking (molecular), RDV triphosphate (RTP)

Abstract

The COVID-19 pandemic has now strengthened its hold on human health and coronavirus’ lethal existence does not seem to be going away soon. In this regard, the optimization of reported information for understanding the mechanistic insights that facilitate the discovery towards new therapeutics is an unmet need. Remdesivir (RDV) is established to inhibit RNA-dependent RNA polymerase (RdRp) in distinct viral families including Ebola and SARS-CoV-2. Therefore, its derivatives have the potential to become a broad-spectrum antiviral agent effective against many other RNA viruses. In this study, we performed comparative analysis of RDV, RMP (RDV monophosphate), and RTP (RDV triphosphate) to undermine the inhibition mechanism caused by RTP as it is a metabolically active form of RDV. The MD results indicated that RTP rearranges itself from its initial RMP-pose at the catalytic site towards NTP entry site, however, RMP stays at the catalytic site. The thermodynamic profiling and free-energy analysis revealed that a stable pose of RTP at NTP entrance site seems critical to modulate the inhibition as its binding strength improved more than its initial RMP-pose obtained from docking at the catalytic site. We found that RTP not only occupies the residues K545, R553, and R555, essential to escorting NTP towards the catalytic site, but also interacts with other residues D618, P620, K621, R624, K798, and R836 that contribute significantly to its stability. From the interaction fingerprinting it is revealed that the RTP interact with basic and conserved residues that are detrimental for the RdRp activity, therefore it possibly perturbed the catalytic site and blocked the NTP entrance site considerably. Overall, we are highlighting the RTP binding pose and key residues that render the SARS-CoV-2 RdRp inactive, paving crucial insights towards the discovery of potent inhibitors.

Published

2021

5. Conformational Characterization of the Co-Activator Binding Site Revealed the Mechanism to Achieve the Bioactive State of FXR

Author

Anita Kumari, Lovika Mittal, Mitul Srivastava, Dharam Pal Pathak, and Shailendra Asthana

Subjects

Agonist, QH301-705.5, medicine.drug_class, Chemistry, principal component analysis, Allosteric regulation, Rational design, binding free energy calculations, Biochemistry, Genetics and Molecular Biology (miscellaneous), Biochemistry, Metabolic pathway, Molecular dynamics, molecular dynamics simulation, medicine, Biophysics, Farnesoid X receptor, Molecular Biosciences, Biology (General), Binding site, Molecular Biology, Conformational ensembles, agonist, farnesoid X receptor, Original Research

Abstract

FXR bioactive states are responsible for the regulation of metabolic pathways, which are modulated by agonists and co-activators. The synergy between agonist binding and ‘co-activator’ recruitment is highly conformationally driven. The characterization of conformational dynamics is essential for mechanistic and therapeutic understanding. To shed light on the conformational ensembles, dynamics, and structural determinants that govern the activation process of FXR, molecular dynamic (MD) simulation is employed. Atomic insights into the ligand binding domain (LBD) of FXR revealed significant differences in inter/intra molecular bonding patterns, leading to structural anomalies in different systems of FXR. The sole presence of an agonist or ‘co-activator’ fails to achieve the essential bioactive conformation of FXR. However, the presence of both establishes the bioactive conformation of FXR as they modulate the internal wiring of key residues that coordinate allosteric structural transitions and their activity. We provide a precise description of critical residue positioning during conformational changes that elucidate the synergy between its binding partners to achieve an FXR activation state. Our study offers insights into the associated modulation occurring in FXR at bound and unbound forms. Thereafter, we also identified hot-spots that are critical to arrest the activation mechanism of FXR that would be helpful for the rational design of its agonists.

Published

2021

6. Identification of Potential Molecules Against COVID-19 Main Protease Through Structure-Guided Virtual Screening Approach

Author

Mrityunjay Singh, Anita Kumari, Shailendra Asthana, Mitul Srivastava, and Lovika Mittal

Subjects

Virtual screening, Drug, media_common.quotation_subject, medicine.medical_treatment, Computational biology, chemistry.chemical_compound, Molecular dynamics, Structural Biology, medicine, Protease Inhibitors, Molecular Biology, Coronavirus 3C Proteases, Repurposing, binding free energy, media_common, Protease, SARS-CoV-2, COVID-19, General Medicine, Mpro protease, Molecular Docking Simulation, Drug repositioning, Nelfinavir, chemistry, molecular docking analysis, Pepstatin, Research Article, medicine.drug

Abstract

The pandemic caused by novel coronavirus disease 2019 (COVID-19) infecting millions of populations worldwide and counting, has demanded quick and potential therapeutic strategies. Current approved drugs or molecules under clinical trials can be a good pool for repurposing through in-silico techniques to quickly identify promising drug candidates. The structural information of recently released crystal structures of main protease (Mpro) in APO and complex with inhibitors, N3, and 13b molecules was utilized to explore the binding site architecture through Molecular dynamics (MD) simulations. The stable state of Mpro was used to conduct extensive virtual screening of the aforementioned drug pool. Considering the recent success of HIV protease molecules, we also used anti-protease molecules for drug repurposing purposes. The identified top hits were further evaluated through MD simulations followed by the binding free energy calculations using MM-GBSA. Interestingly, in our screening, several promising drugs stand out as potential inhibitors of Mpro. However, based on control (N3 and 13b), we have identified six potential molecules, Leupeptin Hemisulphate, Pepstatin A, Nelfinavir, Birinapant, Lypression and Octreotide which have shown the reasonably significant MM-GBSA score. Further insight shows that the molecules form stable interactions with hot-spot residues, that are mainly conserved and can be targeted for structure- and pharmacophore-based designing. The pharmacokinetic annotations and therapeutic importance have suggested that these molecules possess drug-like properties and pave their way for in-vitro studies. Communicated by Ramaswamy H. Sarma

Published

2020

7. Targeting cryptic-orthosteric site of PD-L1 for inhibitor identification using structure-guided approach

Author

Rajiv Kumar Tonk, Shailendra Asthana, Lovika Mittal, and Amit Awasthi

Subjects

Virtual screening, Binding Sites, Chemistry, Biophysics, Computational biology, Molecular Dynamics Simulation, Biochemistry, Small molecule, B7-H1 Antigen, Immune checkpoint, Molecular Docking Simulation, Small Molecule Libraries, Molecular dynamics, Docking (molecular), Humans, Thermodynamics, Molecule, Amino Acid Sequence, Immune Checkpoint Inhibitors, Molecular Biology, Chemical database, Protein Binding, ADME

Abstract

Approved mAbs that block the protein-protein interaction (PPI) interface of the PD-1/PD-L1 immune checkpoint axis have led to significant improvements in cancer treatment. Despite having drawbacks of mAbs only few a compounds are reported till date against this axis. Inhibiting PPIs using small molecules has emerged as a significant therapeutic opportunity, demanding for the identification of drug-like molecules at an accelerated pace under the hit-to-lead campaigns. Due to the PD-L1's cross-talk with PD-1/CD80 and its overexpression on cancer cells, as well as the availability of its crystal structures with small molecules, it is an enticing therapeutic target for structure-assisted small molecule design. Furthermore, the selection of chemical databases enriched with focused designing for PPI interfaces is crucial. Therefore, in this study we have utilized the Asinex signature library for structure-assisted virtual screening to find the potential PD-L1 inhibitors by targeting the cryptic PD-L1 interface, followed by induced fit docking for pose refinements in the pocket. The obtained hits were then subjected to interaction fingerprinting and ligand-based drug-likeness investigations in order to evaluate and analyze their drug-like qualities (ADME). Twelve compounds qualified for molecular dynamics simulations, followed by thermodynamic calculations for evaluation of their stability and energetics inside the pocket. Two novel compounds with different chemical moieties have been identified that are consistent throughout the simulation, mimicking the interactions and binding energies with BMS-1166. These compounds appear as potential therapeutic candidates to be explored experimentally, thereby paving the way for the development of novel leads as immunomodulators.

Published

2021

8. Insights into structural dynamics of allosteric binding sites in HCV RNA-dependent RNA polymerase

Author

Anita Kumari, Lovika Mittal, Shailendra Asthana, Charu Suri, and Sankar Bhattacharya

Subjects

viruses, Hepatitis C virus, 030303 biophysics, Allosteric regulation, Hepacivirus, Biology, Viral Nonstructural Proteins, medicine.disease_cause, Antiviral Agents, 03 medical and health sciences, chemistry.chemical_compound, Structural Biology, RNA polymerase, Genotype, medicine, Enzyme Inhibitors, Molecular Biology, Therapeutic strategy, 0303 health sciences, Binding Sites, General Medicine, RNA-Dependent RNA Polymerase, Virology, Chronic infection, chemistry, Allosteric Site

Abstract

Inhibition of the viral RNA-dependent RNA polymerase (RdRp) to resolve chronic infection is a useful therapeutic strategy against Hepatitis C virus (HCV). Non-nucleoside inhibitors (NNIs) of RdRp are small molecules that bind tightly with allosteric sites on the enzyme, thereby inhibiting polymerase activity. A large number of crystal structures (176) were studied to establish the structure–activity relationship along with the mechanism of inhibition and resistance between HCV RdRp and NNIs at different allosteric sites. The structure and the associated dynamics are the blueprint to understand the function of the protein. We have implemented the ligand-based pharmacophore and molecular dynamic simulations to extract the possible local and global characteristics of RdRp upon NNI binding and the structural–dynamical features possessed by the known actives. Our results suggest that the NNI binding induces significant fluctuations at the atomic level which are critical for enzymatic activity, with minimal global structural alterations. Residue-wise mapping of interactions of NNIs at different sites exhibited some conserved interaction patterns of key amino acids and water molecules. Here, the structural insights are explored to understand the correlation between the dynamics of protein’s subdomains and function at the molecular level, useful for genotype-specific rational designing of NNIs. Communicated by Ramaswamy H. Sarma

Published

2019