Your search keyword '"Utsab R. Shrestha"' showing total 2 results

1. Generation of the configurational ensemble of an intrinsically disordered protein from unbiased molecular dynamics simulation

Author

Qiu Zhang, Utsab R. Shrestha, Loukas Petridis, Viswanathan Gurumoorthy, Volker S. Urban, Jose M. Borreguero, Xiaolin Cheng, Puneet Juneja, Sai Venkatesh Pingali, Jeremy C. Smith, and Hugh O'Neill

Subjects

Physics, Multidisciplinary, Phosphorylation sites, Protein Conformation, Energy landscape, Observable, Molecular Dynamics Simulation, Intrinsically disordered proteins, Intrinsically Disordered Proteins, Molecular dynamics, Order (biology), Models, Chemical, X-Ray Diffraction, PNAS Plus, Structural biology, Scattering, Small Angle, Humans, Statistical physics, Small-angle scattering

Abstract

Intrinsically disordered proteins (IDPs) are abundant in eukaryotic proteomes, play a major role in cell signaling, and are associated with human diseases. To understand IDP function it is critical to determine their configurational ensemble, i.e., the collection of 3-dimensional structures they adopt, and this remains an immense challenge in structural biology. Attempts to determine this ensemble computationally have been hitherto hampered by the necessity of reweighting molecular dynamics (MD) results or biasing simulation in order to match ensemble-averaged experimental observables, operations that reduce the precision of the generated model because different structural ensembles may yield the same experimental observable. Here, by employing enhanced sampling MD we reproduce the experimental small-angle neutron and X-ray scattering profiles and the NMR chemical shifts of the disordered N terminal (SH4UD) of c-Src kinase without reweighting or constraining the simulations. The unbiased simulation results reveal a weakly funneled and rugged free energy landscape of SH4UD, which gives rise to a heterogeneous ensemble of structures that cannot be described by simple polymer theory. SH4UD adopts transient helices, which are found away from known phosphorylation sites and could play a key role in the stabilization of structural regions necessary for phosphorylation. Our findings indicate that adequately sampled molecular simulations can be performed to provide accurate physical models of flexible biosystems, thus rationalizing their biological function.

Published

2019

2. Effects of pressure on the dynamics of an oligomeric protein from deep-sea hyperthermophile

Author

Juscelino B. Leão, John R. D. Copley, Xiang-Qiang Chu, Debsindhu Bhowmik, Madhusudan Tyagi, and Utsab R. Shrestha

Subjects

Multidisciplinary, biology, Chemistry, Archaeal Proteins, Protein dynamics, Relaxation (NMR), Energy landscape, Marine Biology, Biological Sciences, biology.organism_classification, Hyperthermophile, Thermococcus, Crystallography, Biopolymers, Chemical physics, Quasielastic neutron scattering, Pressure, Denaturation (biochemistry), Ambient pressure

Abstract

Inorganic pyrophosphatase (IPPase) from Thermococcus thioreducens is a large oligomeric protein derived from a hyperthermophilic microorganism that is found near hydrothermal vents deep under the sea, where the pressure is up to 100 MPa (1 kbar). It has attracted great interest in biophysical research because of its high activity under extreme conditions in the seabed. In this study, we use the quasielastic neutron scattering (QENS) technique to investigate the effects of pressure on the conformational flexibility and relaxation dynamics of IPPase over a wide temperature range. The β-relaxation dynamics of proteins was studied in the time ranges from 2 to 25 ps, and from 100 ps to 2 ns, using two spectrometers. Our results indicate that, under a pressure of 100 MPa, close to that of the native environment deep under the sea, IPPase displays much faster relaxation dynamics than a mesophilic model protein, hen egg white lysozyme (HEWL), at all measured temperatures, opposite to what we observed previously under ambient pressure. This contradictory observation provides evidence that the protein energy landscape is distorted by high pressure, which is significantly different for hyperthermophilic (IPPase) and mesophilic (HEWL) proteins. We further derive from our observations a schematic denaturation phase diagram together with energy landscapes for the two very different proteins, which can be used as a general picture to understand the dynamical properties of thermophilic proteins under pressure.

Published

2015