The epimutational event, i.e.; ectopic methylation in tumor suppressor genes, can lead to gene silencing, thus promoting prognosis of cancer. The progression of DNA methylation is a cycle of demethylation, de novo methylation, and maintenance methylation. The enzyme responsible for maintenance of methylation status is DNA methyltransferase 1 (DNMT1), the continuous activity of which is required to maintain the pattern of epimutation; thus, its inhibition is a promising strategy for the treatment of cancer. To the best of our knowledge, this study is the first to focus on the recently developed crystal structure of the catalytic site of DNMT1. Here in this study, we have used the crystal structure for the development of non-nucleoside DNMT1 inhibitors using virtual screening (VS), absorption, distribution, metabolism, elimination/toxicology analysis, and molecular docking studies. In this study, VS was carried out on 48,531 natural products to create a subset of lead-like natural products. Three of them were found to form hydrogen bonds with the catalytic site of the DNMT1 (Cys 1226). Thus, this study adumbrates potential lead compounds for treatment of epimutation. © 2013 Springer Science+Business Media New York.

Patel Trupti Navinchandra

Department of Integrative Biology

School of Bio Sciences and Technology

Vellore Campus

Chikan N.A

Bhavaniprasad V

Anbarasu K

Shabir N

Vellore Institute of Technology (VIT) is a private university located in&nbsp;Tamil Nadu, India. Founded in 1984, as Vellore Engineering College, the institution offers 20 undergraduate, 34 postgraduate, four integrated and four research programs. It has campuses in Vellore, Amravati, Bhopal and Chennai.

VIT is one of the top ranked private universities in India according to NIRF, THE and QS Rankings.&nbsp;Govt. of India has recognized&nbsp;VIT, Vellore as an&nbsp;Institution of Eminence. This has allowed VIT to take independent quality initiatives and move up in world ranking.

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VIT University

Applied Biochemistry and Biotechnology

The rapid spread of the Zika virus and its association with the abnormal brain development constitute a global health emergency. With a continuing spread of the mosquito vector, the exposure is expected to accelerate in the coming years. Despite number of efforts, there is still no proper vaccine or medicine to combat this virus. Of note, the NS2B-NS3 protein is proven to be the potential target for the Zika virus therapeutics. Hence, e-pharmacophore-based drug design strategy was employed to identify potent inhibitors of NS2B-NS3 protein from ASINEX database consisting of 467,802 molecules. A 3D e-pharmacophore model was generated using PHASE module of Schrödinger Suite. The generated model consists of one hydrogen bond acceptor (A), two hydrogen bond donors (D), and two aromatic rings (R), ADDRR. The model was further evaluated for its ability to screen actives using enrichment analysis. Subsequently, high-throughput virtual screening protocol was employed, and the resultant hit molecules were also examined for its binding free energies and ADME properties using Prime MM-GBSA and Qikprop module of Schrodinger packages, respectively. Finally, the screened hit molecule was subjected to molecular dynamics simulation to examine its stability. Overall, the results from our analysis suggest that compound BAS 19192837 could be a potent inhibitor for the NS2B-NS3 protein of the Zika virus. It is also noteworthy to mention that our results are in good agreement with literature evidences. We hope that this result is of immense importance in designing potential drug molecules to combat the spread of Zika virus in the near future. © 2018, Springer Science+Business Media, LLC, part of Springer Nature.

Exploring the Lead Compounds for Zika Virus NS2B-NS3 Protein: an e-Pharmacophore-Based Approach

The bindings of detemir [LysB29(Nε-tetradecanoyl)des(B30)-insulin] with two highly homologous albumins, HSA (human serum albumin) and BSA (bovine serum albumin), were investigated through CD, spectrofluorophotometry, and molecular docking analysis. The absence of any tryptophanyl residue in detemir makes albumin binding study possible by exclusive tryptophanyl spectral quenching at 340 nm (λem = 296 nm). The interactions found to be static (Kq &gt; 1010 M-1 s-1) with Stern-Volmer constants ≈103 M-1. The observed ΔG 0 that was negative in all cases concludes the reactions were spontaneous. Domains I and III of an albumin unfold with 5.0 M urea at pH 7.4, although domain II remains intact. Significant decreases in ΔH 0 and ΔS 0 were due to unfolding explicit that detemir binding may involve domains I and III of albumins. Temperature-dependent changes in binding were higher in HSA than BSA but after unfolding such changes were very less, further indicating the role of domains I and III in detemir binding. Pro28 and Tyr26 of insulin were found to be interacting with Arg114 and Val116 of HSA domain I, while myristate segment of detemir binds to Lys519 of domain III. Interactions seem to be predominantly hydrophobic and entropy driven. Although detemir binds to albumin through myristate, the peptide part shows involvement in binding.

Hydrophobic Interaction Between Domain I of Albumin and B Chain of Detemir May Support Myristate-Dependent Detemir-Albumin Binding

Gastric cancer, a malignant and highly proliferative condition, has significantly affected a large population around the globe and is known to be caused by various factors including genetic, epigenetic, and environmental influences. Though the global trend of these cancers is declining, an increase in its frequency is still a threat because of changing lifestyles and dietary habits. However, genetic and epigenetic alterations related to gastric cancers also have an equivalent contribution towards carcinogenic development. DNA methylation is one of the major forms of epigenetic modification which plays a significant role in gastric carcinogenesis. Methylation leads to inactivation of some of the most important genes like DNA repair genes, cell cycle regulators, apoptotic genes, transcriptional regulators, and signalling pathway regulators; which subsequently cause uncontrolled proliferation of cells. Mutations in these genes can be used as suitable prognostic markers for early diagnosis of the disease, since late diagnosis of gastric cancers has a huge negative impact on overall patient survival. In this review, we focus on the important epigenetic mutations that contribute to the development of gastric cancer and the molecular pathogenesis underlying each of them. Methylation, acetylation, and histone modifications play an integral role in the onset of genomic instability, one of the many contributory factors to gastric cancer. This article also covers the constraints of incomplete knowledge of epigenetic factors influencing gastric cancer, thus throwing light on our understanding of the disease. © 2017 the authors.

Fulltext

ecancermedicalscience

Gastric cancer and related epigenetic alterations

Journal of Biomolecular Structure and Dynamics

KAISO inhibition: an atomic insight

International Journal of Oncology

Epimutation and cancer: A new carcinogenic mechanism of Lynch syndrome

Structure of human DNMT1 (601-1600) in complex with Sinefungin

FEBS Letters

An overview of epigenetics and chemoprevention

Drug Discovery Today

Advances in the computational development of DNA methyltransferase inhibitors

Molecular Diversity

Natural products as DNA methyltransferase inhibitors: a computer-aided discovery approach

From Natural Products to Drugs for Epimutation Computer-Aided Drug Design

Journal	Data powered by TypesetApplied Biochemistry and Biotechnology
Publisher	Data powered by TypesetSpringer Science and Business Media LLC
ISSN	0273-2289
Open Access	0