Ramakrishna Dumpati scite author profile

The study considers the Suppressor of cytokine signaling 1 (SOCS1) protein as a novel Type 2 diabetes mellitus (T2DM) drug target. T2DM in human beings is also triggered by the over expression of SOCS proteins. The SOCS1 acts as a ubiquitin ligase (E3), degrades Insulin Receptor Substrate 1 and 2 (IRS1 and IRS2) proteins, and causes insulin resistance. Therefore, the structure of the SOCS1 protein was evaluated using homology-modeling and molecular dynamics methods and validated using standard computational protocols. The Protein-Protein docking study of SOCS1 with its natural substrates, IRS1 and IRS2, and subsequent solvent accessible surface area analysis gave insight into the binding region of the SOCS1 protein. The in silico active site prediction tools highlight the residues Val155 to Ile211 in SOCS1 being implicated in the ubiquitin mediated protein degradation of the proteins IRS1 and IRS2. Virtual screening in the active site region, using large structural databases, results in selective lead structures with 3-Pyridinol, Xanthine, and Alanine moieties as Pharmacophore. The virtual screening study shows that the residues Glu149, Gly187, Arg188, Leu191, and Ser205 of the SOCS1 are important for binding. The docking study with current anti-diabetic therapeutics shows that the drugs Glibenclamide and Glyclopyramide have a partial affinity towards SOCS1. The predicted ADMET and IC properties for the identified ligands are within the acceptable range with drug-like properties. The structural data of SOCS1, its active site, and the identified lead structures are expedient in the development of new T2DM therapeutics.

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Identification of New Lead Molecules Against UBE2NL Enzyme for Cancer Therapy

Ramatenki

Dumpati

Vadija

et al. 2017

Appl Biochem Biotechnol

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Cancer is characterized by abnormal growth of cells. Targeting ubiquitin proteins in the discovery of new anticancer therapeutics is an attractive strategy. The present study uses the structure-based drug discovery methods to identify new lead structures, which are selective to the putative ubiquitin-conjugating enzyme E2N-like (UBE2NL). The 3D structure of the UBE2NL was evaluated using homology modeling techniques. The model was validated using standard in silico methods. The hydrophobic pocket of UBE2NL that aids in binding with its natural receptor ubiquitin-conjugating enzyme E2 variant (UBE2V) was identified through protein-protein docking study. The binding site region of the UBE2NL was identified using active site prediction tools. The binding site of UBE2NL which is responsible for cancer cell progression is considered for docking study. Virtual screening study with the small molecular structural database was carried out against the active site of UBE2NL. The ligand molecules that have shown affinity towards UBE2NL were considered for ADME prediction studies. The ligand molecules that obey the Lipinski's rule of five and Jorgensen's rule of three pharmacokinetic properties like human oral absorption etc. are prioritized. The resultant ligand molecules can be considered for the development of potent UBE2NL enzyme inhibitors for cancer therapy.

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Targeting the ubiquitin-conjugating enzyme E2D4 for cancer drug discovery–a structure-based approach

et al. 2016

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Cancer progression is a global burden. The incidence and mortality now reach 30 million deaths per year. Several pathways of cancer are under investigation for the discovery of effective therapeutics. The present study highlights the structural details of the ubiquitin protein 'Ubiquitin-conjugating enzyme E2D4' (UBE2D4) for the novel lead structure identification in cancer drug discovery process. The evaluation of 3D structure of UBE2D4 was carried out using homology modelling techniques. The optimized structure was validated by standard computational protocols. The active site region of the UBE2D4 was identified using computational tools like CASTp, Q-site Finder and SiteMap. The hydrophobic pocket which is responsible for binding with its natural receptor ubiquitin ligase CHIP (C-terminal of Hsp 70 interacting protein) was identified through proteinprotein docking study. Corroborating the results obtained from active site prediction tools and protein-protein docking study, the domain of UBE2D4 which is responsible for cancer cell progression is sorted out for further docking study. Virtual screening with large structural database like CB_Div Set and Asinex BioDesign small molecular structural database was carried out. The obtained new ligand molecules that have shown affinity towards UBE2D4 were considered for ADME prediction studies. The identified new ligand molecules with acceptable parameters of docking, ADME are considered as potent UBE2D4 enzyme inhibitors for cancer therapy.

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Suppressor of Cytokine Signalling‐3 as a Drug Target for Type 2 Diabetes Mellitus: A Structure‐Guided Approach

et al. 2016

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The present study treats Suppressor of cytokine signalling 3 (SOCS-3) as a novel target for type 2 diabetes mellitus (T2DM) drug discovery. An in silico 3D structural evaluation and validation of the SOCS-3 and its cognate receptor, Insulin Receptor Beta (IRÀB) was carried out. The active site of SOCS-3 was identified using computational tools and Protein-Protein docking with IRÀB. The docking study with T2DM drugs and corroborating with the results of virtual screening using small molecules, ratify the residues of the catalytic site of SOCS-3, i. e. Arg-71 along with Asp-72, Ser-73, Ser-74, and Asp-92, to facilitate the binding. The T2DM drugs which belong to Sulfonylureas class show partial affinity towards SOCS-3. The ligands show acceptable pharmacokinetic properties in terms of Lipinski's rule of 5, Jorgensen's rule of 3, brain/blood partition coefficient, binding to human serum albumin and skin permeability. The identified ligands show good predicted IC 50 values and hence can act as SOCS-3 antagonists. The structural data of SOCS-3 active site and the identified ligands are useful in development of new T2DM therapeutics.

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