Faculty Publications

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Author: search.filters.author.Chakraborty, D.Subject: search.filters.subject.Hydrophilicity

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    Hydrophilicity of the hydrophobic group: Effect of cosolvents and ions
    (Elsevier B.V., 2019) Dilip, H.N.; Chakraborty, D.
    Classical molecular dynamics simulations were performed to study the effect of cosolvents and ions on the solvation structure of zwitterionic glycine in liquid water. Simulations were carried out for 2 M and 1 M concentration of TMAO, Urea, KCl and LiCl solutions to observe the changes in liquid structure of water near the glycine molecule. Radial distribution functions and spatial distribution functions showed the presence of protective hydration layer near the C ? in presence of TMAO which gets reduced in case of urea, KCl and minimum in case of LiCl. LiCl is found to disrupt severely the solvation structure near the glycine molecule. For LiCl system, a small hydration layer is found near C ? unit at higher distances which is mainly due to the first hydration shell of lithium ion bonded to the carboxylate group. Presence of these hydration layers gives extra stabilization energy to the glycine water system. Stabilizing and destabilizing effect of water near the glycine molecule is calculated in terms of Potential Mean Force. The anomalous behaviour of lithium salts with respect to Group I cation salts in protein stabilization can be explained on the basis of this behaviour. We found maximum hydrogen bond lifetime for water molecules in presence of TMAO followed by LiCl, KCl and least in case of urea. The higher lifetimes in presence of ions are found mainly due to their electrostatic force. The stabilization of the hydrophobic part of the glycine molecule can be correlated with the stabilization of proteins in presence of these cosolvents. © 2019 Elsevier B.V.
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    Preferential binding affinity of ions and their effect on structure and dynamics of water near antimicrobial peptide
    (Elsevier B.V., 2021) Singh, O.; Chakraborty, D.
    Water containing dissolved salts is often found to play important roles in many chemical and biological processes. They affect the stability of the amino acids and proteins by altering the liquid water structure. The formation of a mixture of non-uniform density regions in liquid water; commonly known as Low-density water and High-density water is a well-known fact experimentally; which lends uniqueness to the ubiquitous water. The behavior of these different types of water at the interface and the bulk region of the biomolecules around the hydrophobic and hydrophilic residues under the influence of different alkali metal ions, such as LiCl, NaCl, and KCl is an important unexplored question in understanding of many biomolecular processes. To address this, we carried out MD simulation of antimicrobial peptide (PDB ID: 5Z32) for two different model potentials (CHARMM-SPC/E and AMBER-TIP4P) and performed the structural analysis of water in terms of the radial distribution function, number of hydrogen bonds, orientation, tetrahedral order parameter, voids analysis to analyze the related dynamical properties like preferential binding affinity, diffusion, hydrogen bond dynamics, entropy. The water molecules around the hydrophilic environment are found to be more disruptive containing more broken hydrogen bonds in comparison to the hydrophobic environment. It is also found that the water molecules present near the protein surface are of low density and that near the bulk is of high density. This leads to the higher self-diffusion coefficient of the water molecules and less hydrogen bond lifetime at the bulk. The maximum difference is found for the solutions containing high charge density, Lithium ions. Lithium ions have a strong preferential binding affinity towards protein surface resulting in strong solvation shells containing more tetrahedral-like water structure which has low diffusion, low entropy, and higher hydrogen bond lifetime. The diffusion of the water molecules, however, increases towards the higher solvation shells. Potassium on the other hand has less preference to live on protein surfaces resulting in similar diffusion values in the bulk and interface water molecules. © 2021 Elsevier B.V.
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    Designing Reaction Coordinate for Ion-Induced Pore-Assisted Mechanism of Halide Ions Permeation through Lipid Bilayer by Umbrella Sampling
    (American Chemical Society, 2023) Mathath, A.V.; Das, B.K.; Chakraborty, D.
    Ion permeation mechanism through lipid membranes helps to understand cellular processes. We propose new reaction coordinates that allow ions to permeate according to their water affinity and interaction with the hydrophilic layer. Simulations were done for three different halides (F-, Cl-, and I-) in two different lipid bilayers, 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) and 1,2-dinervonoyl-sn-glycero-3-phosphocholine (DNPC). It is found that the involvement of the water molecules decreases the free energy barrier. The ions were found to follow different pathways for permeation. Formation of proper pores required a collaboration effort of the hydration shell water molecules and the hydrophilic lipid layer, which was favored in the case of Cl- ions. The optimum charge density and good water affinity of Cl- with respect to F- and I- ions helped to form the pore. The effect was prominently seen in the case of DNPC membrane because of its higher hydrophobic thickness. The umbrella sampling results were compared with other methods such as the Markov state model (MSM) and well-tempered metadynamics (WT-metaD). © 2023 American Chemical Society.