Interdisciplinary studies to understand in-depth molecular level mechanism of drug resistance involving NS3-4A protease of HCV.

Hepatitis C virus (HCV) causes hepatitis, a life-threatening disease responsible for liver cirrhosis. Urgent measures have been taken to develop therapeutics against this deadly pathogen. NS3/4A protease is an extremely important target.

study of cox protein from P2 type enteric bacteriophages based on sequence, structure and dynamics to understand its functional integrity.

Cox protein plays a critical role in deciding the lytic-lysogenic switch of P2 enteric phages. This phenomenon makes Cox protein one of the most important candidates in developing novel phage-based therapeutics against antibacterial resistant pathogens. The principle focus concerning protein and its decision making is a DNA binding event, which helps to regulate differential promoter expression.

N-terminal truncation of VC0395_0300 protein from Vibrio cholerae does not lead to loss of diguanylate cyclase activity.

The bacterial secondary messenger bis-(3',5')-cyclic-dimeric-guanosine monophosphate (c-di-GMP) has been implicated in the pathogenesis of Vibrio cholerae, due to its significant role in regulating the virulence, biofilm formation and motility of the host organism. The VC0395_0300 protein from V. cholerae, possessing a GGEEF sequence has been established as a diguanylate cyclase (DGC) capable of catalyzing the conversion of two GTP molecules to form cyclic-di-GMP.

PI3Kα-regulated gelsolin activity is a critical determinant of cardiac cytoskeletal remodeling and heart disease.

Biomechanical stress and cytoskeletal remodeling are key determinants of cellular homeostasis and tissue responses to mechanical stimuli and injury. Here we document the increased activity of gelsolin, an actin filament severing and capping protein, in failing human hearts. Deletion of gelsolin prevents biomechanical stress-induced adverse cytoskeletal remodeling and heart failure in mice.

Putative protein VC0395_0300 from Vibrio cholerae is a diguanylate cyclase with a role in biofilm formation.

The hallmark of the lifecycle of Vibrio cholerae is its ability to switch between two lifestyles - the sessile, non-pathogenic form and the motile, infectious form in human hosts. One of these changes is in the formation of surface biofilms, when in sessile aquatic habitats. The cell-cell interactions within a V.

In Silico Designing of an Industrially Sustainable Carbonic Anhydrase Using Molecular Dynamics Simulation.

Carbonic anhydrase (CA) is a family of metalloenzymes that has the potential to sequestrate carbon dioxide (CO) from the environment and reduce pollution. The goal of this study is to apply protein engineering to develop a modified CA enzyme that has both higher stability and activity and hence could be used for industrial purposes. In the current study, we have developed an in silico method to understand the molecular basis behind the stability of CA.

Effect of site-directed mutagenesis at the GGEEF domain of the biofilm forming GGEEF protein from Vibrio cholerae.

Vibrio cholerae, the cause of seven noted pandemics, leads a dual lifecycle-one in the human host in its virulent form, and the other as a sessile, non-virulent bacterium in aquatic bodies in surface biofilms. Surface biofilms have been attributed to be associated with a ubiquitous protein domain present in all branches of bacteria, known as the GGD(/E)EF domain. While the diguanlyate cyclase activities of these proteins are universally established, the role of these proteins as diguanlyate-specific phosphodiesterases in conjunction with a EAL domain has also been reported.

Comparative molecular dynamics simulation studies for determining factors contributing to the thermostability of chemotaxis protein "CheY".

Comparative molecular dynamics simulations of chemotaxis protein "CheY" from thermophilic origin Thermotoga maritima and its mesophilic counterpart Salmonella enterica have been performed for 10 ns each at 300 and 350 K, and 20 ns each at 400 and 450 K. The trajectories were analyzed in terms of different factors like root-mean-square deviation, root-mean-square fluctuation, radius of gyration, solvent accessible surface area, H-bonds, salt bridge content, and protein-solvent interactions which indicate distinct differences between the two of them. The two proteins also follow dissimilar unfolding pathways.