Add to ORKGWe use a single molecule atomic force spectroscopy combined with the steered molecular dynamics simulation to determine a mechanical behavior of neural cell adhesion protein contactin during its unfolding. Force curves typical for modular proteins were observed, showing at most four unfolding peaks. The analysis of force spectra performed within worm-like chain model of polymer elasticity showed the presence of three unfolding lengths. Small plateaus, most likely resulting from forced transitions within domains were observed for the first time. Steered molecular dynamics simulations help to determine atomistic picture of domain unfolding
The Atomic Force Microscope (AFM) is a 20 years old instrument that has proven valuable for the ultr...
Many processes in the body are effected and regulated by highly, specialized protein molecules: Thes...
Quantitative understanding of the mechanical behavior of biological liquid crystals such as proteins...
We use a single molecule atomic force spectroscopy combined with the steered molecular dynamics simu...
Abstract Computer simulations of protein unfolding sub-stantially help to interpret force-extension ...
Traditionally, adhesion interactions have been studied in reversible equilibrium conditions. Howeve...
none1noTraditionally, adhesion interactions have been studied in reversible equilibrium conditions. ...
Can molecular dynamics simulations predict the mechanical behavior of protein complexes? Can simulat...
International audienceThe mechanical properties of cells and of subcellular components are important...
Traditionally, adhesion interactions have been studied in reversible equilibrium conditions. Howeve...
AbstractRecent advances in atomic force microscopy allowed globular and membrane proteins to be mech...
Atomic force microscopy (AFM)-based single molecule force spectroscopy (SMFS) has emerged into a re...
The mechanical folding/unfolding of proteins is involved in many biological processes. However, the ...
Single molecule 'force spectroscopy' techniques (e.g., atomic force microscopy) that measure the for...
Atomic force microscopy (AFM) is a powerful technique that enables to study biological macromolecule...
The Atomic Force Microscope (AFM) is a 20 years old instrument that has proven valuable for the ultr...
Many processes in the body are effected and regulated by highly, specialized protein molecules: Thes...
Quantitative understanding of the mechanical behavior of biological liquid crystals such as proteins...
We use a single molecule atomic force spectroscopy combined with the steered molecular dynamics simu...
Abstract Computer simulations of protein unfolding sub-stantially help to interpret force-extension ...
Traditionally, adhesion interactions have been studied in reversible equilibrium conditions. Howeve...
none1noTraditionally, adhesion interactions have been studied in reversible equilibrium conditions. ...
Can molecular dynamics simulations predict the mechanical behavior of protein complexes? Can simulat...
International audienceThe mechanical properties of cells and of subcellular components are important...
Traditionally, adhesion interactions have been studied in reversible equilibrium conditions. Howeve...
AbstractRecent advances in atomic force microscopy allowed globular and membrane proteins to be mech...
Atomic force microscopy (AFM)-based single molecule force spectroscopy (SMFS) has emerged into a re...
The mechanical folding/unfolding of proteins is involved in many biological processes. However, the ...
Single molecule 'force spectroscopy' techniques (e.g., atomic force microscopy) that measure the for...
Atomic force microscopy (AFM) is a powerful technique that enables to study biological macromolecule...
The Atomic Force Microscope (AFM) is a 20 years old instrument that has proven valuable for the ultr...
Many processes in the body are effected and regulated by highly, specialized protein molecules: Thes...
Quantitative understanding of the mechanical behavior of biological liquid crystals such as proteins...