2014 - Fellow of Alfred P. Sloan Foundation
His primary scientific interests are in Thermodynamics, Crystallography, Molecular dynamics, Protein folding and Force field. His research in Thermodynamics intersects with topics in Mechanics and Statistical physics. His work carried out in the field of Crystallography brings together such families of science as Protein structure and Standard conditions for temperature and pressure.
His study brings together the fields of Protein secondary structure and Molecular dynamics. His Protein folding research is multidisciplinary, relying on both Dihedral angle, Dipole and Energy landscape. His biological study spans a wide range of topics, including Ramachandran plot, Side chain, Water model and Torsion.
His scientific interests lie mostly in Chemical physics, Molecular dynamics, Intrinsically disordered proteins, Biophysics and Thermodynamics. While the research belongs to areas of Chemical physics, Jeetain Mittal spends his time largely on the problem of Crystallography, intersecting his research to questions surrounding Protein folding, Protein secondary structure, Macromolecular crowding and Macromolecule. His work deals with themes such as Folding and Force field, which intersect with Protein folding.
Jeetain Mittal combines subjects such as Statistical physics, Nanotechnology, Carbon nanotube and Density functional theory with his study of Molecular dynamics. His work is dedicated to discovering how Intrinsically disordered proteins, Phase are connected with Work and other disciplines. The study of Thermodynamics is intertwined with the study of Atomic packing factor in a number of ways.
Jeetain Mittal mainly focuses on Intrinsically disordered proteins, Biophysics, Phase, Chemical physics and Liquid liquid. The Intrinsically disordered proteins study combines topics in areas such as Protein secondary structure, Molecular dynamics, Biomolecule, Composition dependence and Drug delivery. His studies deal with areas such as Force field and Small set as well as Protein secondary structure.
His Chemical physics research incorporates themes from Ion, Self-assembly, Low complexity and Phase diagram. His Liquid liquid study combines topics in areas such as Crystallography and Computational model. His Nanoparticle research is multidisciplinary, incorporating perspectives in Superlattice and Thermodynamics.
Intrinsically disordered proteins, Phase, Biophysics, Statistical physics and Biomolecule are his primary areas of study. His Intrinsically disordered proteins study combines topics from a wide range of disciplines, such as Liquid liquid, Living systems and Phase diagram. Jeetain Mittal has included themes like Chemical physics, Hydrophobic effect, Composition dependence and Drug delivery in his Phase study.
His Biophysics research includes themes of Lipid bilayer, Sequence and Protein–protein interaction. As a part of the same scientific study, Jeetain Mittal usually deals with the Statistical physics, concentrating on Protein structure and frequently concerns with Molecular dynamics. His Protein secondary structure study integrates concerns from other disciplines, such as Force field, Small set and Hydrogen bond.
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Optimization of the additive CHARMM all-atom protein force field targeting improved sampling of the backbone φ, ψ and side-chain χ(1) and χ(2) dihedral angles.
Robert B. Best;Xiao Zhu;Jihyun Shim;Pedro E. M. Lopes.
Journal of Chemical Theory and Computation (2012)
ALS Mutations Disrupt Phase Separation Mediated by α-Helical Structure in the TDP-43 Low-Complexity C-Terminal Domain.
Alexander E. Conicella;Gül H. Zerze;Jeetain Mittal;Nicolas L. Fawzi.
Balanced Protein–Water Interactions Improve Properties of Disordered Proteins and Non-Specific Protein Association
Robert B. Best;Wenwei Zheng;Jeetain Mittal.
Journal of Chemical Theory and Computation (2014)
Phosphorylation of the FUS low‐complexity domain disrupts phase separation, aggregation, and toxicity
Zachary Monahan;Veronica H Ryan;Abigail M Janke;Kathleen A Burke.
The EMBO Journal (2017)
Molecular interactions underlying liquid−liquid phase separation of the FUS low-complexity domain
Anastasia C. Murthy;Gregory L. Dignon;Yelena Kan;Yelena Kan;Gül H. Zerze;Gül H. Zerze.
Nature Structural & Molecular Biology (2019)
Sequence determinants of protein phase behavior from a coarse-grained model.
Gregory L. Dignon;Wenwei Zheng;Young C. Kim;Robert B. Best.
PLOS Computational Biology (2018)
Protein simulations with an optimized water model: cooperative helix formation and temperature-induced unfolded state collapse.
Robert B. Best;Jeetain Mittal.
Journal of Physical Chemistry B (2010)
Mechanistic View of hnRNPA2 Low-Complexity Domain Structure, Interactions, and Phase Separation Altered by Mutation and Arginine Methylation.
Veronica H. Ryan;Gregory L. Dignon;Gül H. Zerze;Charlene V. Chabata.
Molecular Cell (2018)
Layering and position-dependent diffusive dynamics of confined fluids
Jeetain Mittal;Thomas M. Truskett;Jeffrey R. Errington;Gerhard Hummer.
Physical Review Letters (2008)
Relation between single-molecule properties and phase behavior of intrinsically disordered proteins
Gregory L. Dignon;Wenwei Zheng;Robert B. Best;Young C. Kim.
Proceedings of the National Academy of Sciences of the United States of America (2018)
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