Single Molecular Spectroscopy and Atomic Force Manipulation of Protein Conformation and Dynamics

Cao, Jin

15 December 2014

No description available.

Chemistry

Physical Chemistry

Biophysics

Single Molecule

Atomic Force Microscopy

FRET

Calmodulin

EGFR

Protein conformational dynamics

Photon-stamping

Molecular Order and Dynamics in Nanostructured Materials by Solid-State NMR

Kharkov, Boris

January 2015

Organic-inorganic nanostructured composites are nowadays integrated in the field of material science and technology. They are used as advanced materials directly or as precursors to novel composites with potential applications in optics, mechanics, energy, catalysis and medicine. Many properties of these complex materials depend on conformational rearrangements in their inherently dynamic organic parts. The focus of this thesis is on the study of the molecular mobility in ordered nanostructured composites and lyotropic mesophases and also on the development of relevant solid-state NMR methodologies. In this work, a number of new experimental approaches were proposed for dipolar NMR spectroscopy for characterizing molecular dynamics with atomic-level resolution in complex solids and liquids. A new acquisition scheme for two-dimensional dipolar spectroscopy has been developed in order to expand the spectral window in the indirect dimension while using limited radio-frequency power. Selective decoupling of spin-1 nuclei for sign-sensitive determination of the heteronuclear dipolar coupling has been described. A new dipolar recoupling technique for rotating samples has been developed to achieve high dipolar resolution in a wide range of dipolar coupling strength. The experimental techniques developed herein are capable of delivering detailed model-independent information on molecular motional parameters that can be directly compared in different composites and their bulk analogs. Solid-state NMR has been applied to study the local molecular dynamics of surfactant molecules in nanostructured organic-inorganic composites of different morphologies. On the basis of the experimental profiles of local order parameters, physical motional models for the confined surfactant molecules were put forward. In layered materials, a number of motional modes of surfactant molecules were observed depending on sample composition. These modes ranged from essentially immobilized rigid states to highly flexible and anisotropically tumbling states. In ordered hexagonal silica, highly dynamic conformationally disordered chains with restricted motion of the segments close to the head group have been found. The results presented in this thesis provide a step towards the comprehensive characterization of the molecular states and understanding the great variability of the molecular assemblies in advanced nanostructured organic−inorganic composite materials. / <p>QC 20150225</p>

mesoporous materials

organic-inorganic nanocomposites

surfactants

liquid crystals

MCM-41

clays

conformational dynamics

solid-state NMR

local field spectroscopy

dipolar coupling

dipolar recoupling

spin decoupling.

Mechanistic studies of enzymes involved in DNA transactions

Stephenson, Anthony Aaron

07 November 2018

No description available.

Cellular Biology

Biophysics

Biology

Biochemistry

DNA replication

DNA repair

DNA polymerase lambda

BRCT

Gene editing

CRISPR-Cas9

enzymology

enzyme kinetics

pre-steady state kinetics

conformational dynamics

Using Molecular Simulations and Statistical Models to Understand Biomolecular Conformational Dynamics

Ge, Yunhui

January 2020

Conformational dynamics are important to the function of biological molecules. While many experimental techniques (e.g. X-ray crystallography and NMR spectroscopy) have been developed for providing the structure of functional conformations, it is exceptionally challenging to understand conformational dynamics from experimental characterization. Molecular dynamics (MD) simulations is a powerful tool for probing conformational dynamics. The timescale resolution of MD simulations enables people to investigate intermediate conformations and transition pathways in atomic detail. Recent advancements in computer hardware have increased the timescales accessible to MD simulations. Meanwhile, more accurate and specific force fields have been developed to accurately model a variety biological system of different sizes. My graduate research has been focused on using MD simulations to study the conformational dynamics of proteins. Markov State Model (MSM) based approaches are extensively applied to investigate a variety of folding and/or binding mechanisms in atomic detail. Another focus of my work has been developing a Bayesian inference-based approach called BICePs to reconcile experimental measurements with simulation data to determine conformational ensembles and to validate force fields. / Chemistry

Computational Chemistry

Biophysics

Chemistry, Physical

Conformational Dynamics

Drug Discovery

Markov State Models

Molecular Dynamics

Multi-disciplinary Investigation of the Kinetics and Protein Conformational Dynamics of DNA Replication and Oxidative DNA Damage Bypass and Repair

Maxwell, Brian Andrew

17 October 2014

No description available.

Biophysics

Nanoscale Brownian Dynamics of Semiflexible Biopolymers

Mühle, Steffen

16 July 2020

No description available.

571.4

complex systems

polymer dynamics

brownian motion

elasticity

differential geometry

single-molecule experiment

single-molecule experiments

biophysics

fluorescence correlation spectroscopy

loop formation

translational diffusion

stochastic dynamics

thermal equilibrium

overdamped hydrodynamics

conformational dynamics

protein dynamics

protein folding

loop closure kinetics

intrinsically disordered protein

PET-FCS

2fFCS

hydrodynamic radius

Biologie (PPN619462639)