Add to ORKGThe role of mechanical force in cellular processes is increasingly revealed by single molecule experiments and simulations of force-induced transitions in proteins. How the applied force propagates within proteins determines their mechanical behavior yet remains largely unknown. We present a new method based on molecular dynamics simulations to disclose the distribution of strain in protein structures, here for the newly determined high-resolution crystal structure of I27, a titin immunoglobulin (IG) domain. We obtain a sparse, spatially connected, and highly anisotropic mechanical network. This allows us to detect load-bearing motifs composed of interstrand hydrogen bonds and hydrophobic core interactions, including parts distal to the sit...
The elastic I-band part of muscle protein titin contains two tandem immunoglobulin (Ig) domain regio...
ABSTRACT Steered molecular dynamics simulation of force-induced titin immunoglobulin domain I27 unfo...
Using molecular dynamics simulations, we have explored the mechanical strength of the titin Z1Z2-tel...
AbstractTitin, a 1-μm-long protein found in striated muscle myofibrils, possesses unique elastic and...
Titin is the largest protein in humans, composed of more than one hundred immunoglobulin (Ig) domain...
AbstractThe giant protein titin, which is responsible for passive elasticity in muscle fibers, is bu...
The functionally elastic, I-band part of the myofibrillar protein titin (connectin) contains differ-...
AbstractThe protein titin functions as a mechanical spring conferring passive elasticity to muscle. ...
Titin, a 1 m long protein found in striated muscle myobrils, pos-sesses unique elastic and extensibi...
89 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 2010.Titin is a mechanical protein ...
AbstractThe domains of the giant muscle protein titin (connectin) provide interaction sites for othe...
The mechanical unfolding of an immunoglobulin domain from the human muscle protein titin (TI I27) ha...
AbstractWe have studied the unfolding by force of one of the immunoglobulin domains of the muscle pr...
The mechanical stability of force-bearing proteins is crucial for their functions. However, slow tra...
The mechanical unfolding of an immunoglobulin domain from the human muscle protein titin (TI I27) ha...
The elastic I-band part of muscle protein titin contains two tandem immunoglobulin (Ig) domain regio...
ABSTRACT Steered molecular dynamics simulation of force-induced titin immunoglobulin domain I27 unfo...
Using molecular dynamics simulations, we have explored the mechanical strength of the titin Z1Z2-tel...
AbstractTitin, a 1-μm-long protein found in striated muscle myofibrils, possesses unique elastic and...
Titin is the largest protein in humans, composed of more than one hundred immunoglobulin (Ig) domain...
AbstractThe giant protein titin, which is responsible for passive elasticity in muscle fibers, is bu...
The functionally elastic, I-band part of the myofibrillar protein titin (connectin) contains differ-...
AbstractThe protein titin functions as a mechanical spring conferring passive elasticity to muscle. ...
Titin, a 1 m long protein found in striated muscle myobrils, pos-sesses unique elastic and extensibi...
89 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 2010.Titin is a mechanical protein ...
AbstractThe domains of the giant muscle protein titin (connectin) provide interaction sites for othe...
The mechanical unfolding of an immunoglobulin domain from the human muscle protein titin (TI I27) ha...
AbstractWe have studied the unfolding by force of one of the immunoglobulin domains of the muscle pr...
The mechanical stability of force-bearing proteins is crucial for their functions. However, slow tra...
The mechanical unfolding of an immunoglobulin domain from the human muscle protein titin (TI I27) ha...
The elastic I-band part of muscle protein titin contains two tandem immunoglobulin (Ig) domain regio...
ABSTRACT Steered molecular dynamics simulation of force-induced titin immunoglobulin domain I27 unfo...
Using molecular dynamics simulations, we have explored the mechanical strength of the titin Z1Z2-tel...