Molecular Dynamics Study of Talin-Vinculin Binding

Lee, S.E.; Chunsrivirot, Surasak; Kamm, Roger D.; Mofrad, Mohammad R. K.

doi:10.1529/biophysj.107.124487

Cited by 45 publications

(50 citation statements)

References 39 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…There are several sites on the talin rod that bind the vinculin head [Ziegler et al, 2008]. The majority of these sites are cryptic (buried inside the rod), but can be opened by unfolding the talin molecule, as was proposed in structural studies [Fillingham et al, 2005; Gingras et al, 2006; Papagrigoriou et al, 2004], verified by steered molecular dynamic simulations [Hytonen and Vogel, 2008 ; Lee et al, 2007, 2008], and finally directly demonstrated in experiments involving the stretching of talin rods in vitro [del Rio et al, 2009]. Notably, binding of the vinculin head to talin promotes binding of the vinculin tail to the actin filament [Bois et al, 2006].…”

Section: Adhesion-dependent Mechanosensitivity: Phenomenology and Elementioning

confidence: 99%

The heel and toe of the cell's foot: A multifaceted approach for understanding the structure and dynamics of focal adhesions

Wolfenson

Henis

Geiger

et al. 2009

Cell Motil. Cytoskeleton

115

105

View full text Add to dashboard Cite

Focal adhesions (FAs) are large clusters of transmembrane receptors of the integrin family and a multitude of associated cytoplasmic ''plaque'' proteins, which connect the extracellular matrix-bound receptors with the actin cytoskeleton. The formation of nearly stationary FAs defines a boundary between the dense and highly dynamic actin network in lamellipodium and the sparser and more diverse cytoskeletal organization in the lamella proper, creating a template for the organization of the entire actin network. The major ''mechanical'' and ''sensory'' functions of FAs; namely, the nucleation and regulation of the contractile, myosin-IIcontaining stress fibers and the mechanosensing of external surfaces depend, to a major extent, on the dynamics of molecular components within FAs. A central element in FA regulation concerns the positive feedback loop, based on the most intriguing feature of FAs; that is, their dependence on mechanical tension developing by the growing stress fibers. FAs grow in response to such tension, and rapidly disassemble upon its relaxation. In this article, we address the mechanistic relationships between the process of FA development, maturation and dissociation and the dynamic molecular events, which take place in different regions of the FA, primarily in the distal end of this structure (the ''toe'') and the proximal ''heel,'' and discuss the central role of local mechanical forces in orchestrating the complex interplay between FAs and the actin system. Cell Motil. Cytoskeleton

show abstract

Section: Adhesion-dependent Mechanosensitivity: Phenomenology and Elementioning

confidence: 99%

The heel and toe of the cell's foot: A multifaceted approach for understanding the structure and dynamics of focal adhesions

Wolfenson

Henis

Geiger

et al. 2009

Cell Motil. Cytoskeleton

115

105

View full text Add to dashboard Cite

show abstract

“…3 Altered conformations of the tandem repeats may trigger downstream signaling cascades, for instance by modulating binding to filamin interacting protein and downstream pathways. 3 Furthermore, phosphorylation of filamin A at Ser 21,52 appears to promote force-induced unfolding and affinity for integrin. 18 A recent single-molecule experiment with optical tweezers on filamin A showed another potential mechanism for mechanosensing based on force-induced cis–trans proline isomerization of the force sensing domain pair 20–21 in filamin A.…”

Section: Atomistic Scale: Forces and Structurementioning

confidence: 99%

Multiscale mechanobiology: computational models for integrating molecules to multicellular systems

Mak

Kim

Zaman

et al. 2015

Integrative Biology

View full text Add to dashboard Cite

Mechanical signals exist throughout the biological landscape. Across all scales, these signals, in the form of force, stiffness, and deformations, are generated and processed, resulting in an active mechanobiological circuit that controls many fundamental aspects of life, from protein unfolding and cytoskeletal remodeling to collective cell motions. The multiple scales and complex feedback involved present a challenge for fully understanding the nature of this circuit, particularly in development and disease in which it has been implicated. Computational models that accurately predict and are based on experimental data enable a means to integrate basic principles and explore fine details of mechanosensing and mechanotransduction in and across all levels of biological systems. Here we review recent advances in these models along with supporting and emerging experimental findings.

show abstract

“…Specifically, it is important to characterize how the three-dimensional structural rigidity of DNA, RNA and proteins control their deformation under various loading conditions—stretching, twisting, bending and shear conditions—and how such deformation alters DNA condensation, gene replication and transcription, DNA–protein/RNA–protein interactions, protein function, protein–protein interaction, and protein–ligand interaction 5–7,14,48,51,53,71. These research topics encompass bond formation, reaction rates, and the thermodynamics and kinetics of biomolecular interactions.…”

Section: Molecular Biomechanics: An Emergent Fieldmentioning

confidence: 99%

“…To date, the molecular mechanisms of force sensing and mechanotransduction remain elusive. While numerous mechanisms have been proposed, a strong candidate for the molecular mechanism of mechanosensing and mechanotransduction is protein deformation, or protein conformational change under force 41,51,53,87,95,96. The unique three-dimensional structure (i.e., conformation) of a protein largely determines its function.…”

Section: Major Issues and New Opportunitiesmentioning

confidence: 99%

Molecular Biomechanics: The Molecular Basis of How Forces Regulate Cellular Function

et al. 2010

View full text Add to dashboard Cite

Recent advances have led to the emergence of molecular biomechanics as an essential element of modern biology. These efforts focus on theoretical and experimental studies of the mechanics of proteins and nucleic acids, and the understanding of the molecular mechanisms of stress transmission, mechanosensing and mechanotransduction in living cells. In particular, singlemolecule biomechanics studies of proteins and DNA, and mechanochemical coupling in biomolecular motors have demonstrated the critical importance of molecular mechanics as a new frontier in bioengineering and life sciences. To stimulate a more systematic study of the basic issues in molecular biomechanics, and attract a broader range of researchers to enter this emerging field, here we discuss its significance and relevance, describe the important issues to be addressed and the most critical questions to be answered, summarize both experimental and theoretical/ computational challenges, and identify some short-term and long-term goals for the field. The needs to train young researchers in molecular biomechanics with a broader knowledge base, and to bridge and integrate molecular, subcellular and cellular level studies of biomechanics are articulated. KeywordsMechanobiology; Force; Cytoskeleton; Mechanotransduction; Protein conformational change; Molecular motors MOLECULAR BIOMECHANICS: AN EMERGENT FIELDLiving cells are dynamic systems that perform integrated functions including metabolism, control, sensing, communication, growth, remodeling, reproduction and apoptosis (programed cell death). During the past few decades, extensive studies have elucidated the structure, mechanical responses and biological functions of cells in different organs and tissues including, for example, lung, bone, cartilage, blood vessels, and skeletal and cardiac © 2010 Biomedical Engineering Society Address correspondence to Gang Bao, Department of Biomedical Engineering, Georgia Institute of Technology and Emory University, Atlanta, GA 30332, USA. gang.bao@bme.gatech.edu. NIH Public Access Author ManuscriptMol Cell Biomech. Author manuscript; available in PMC 2010 August 9. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript muscles. These studies have led to a better understanding of how the biological functions of a cell are regulated by mechanical forces or deformation. They have also demonstrated the central role that forces play in the initiation and progression of numerous diseases such as atherosclerosis, arthritis, asthma, to name a few. However, to decipher the fundamental mechanisms of force-induced control of cellular function, more systematic studies of deformation, structural dynamics and mechanochemical transduction in living cells and biomolecules are needed.As the basic unit of life, living cells perform an enormous variety of functions through synthesis, sorting, storage and transport of biomolecules; expression of genetic information; recognition, transmission and transduction of signals; and conversion between different for...

show abstract

Molecular Dynamics Study of Talin-Vinculin Binding

Cited by 45 publications

References 39 publications

The heel and toe of the cell's foot: A multifaceted approach for understanding the structure and dynamics of focal adhesions

The heel and toe of the cell's foot: A multifaceted approach for understanding the structure and dynamics of focal adhesions

Multiscale mechanobiology: computational models for integrating molecules to multicellular systems

Molecular Biomechanics: The Molecular Basis of How Forces Regulate Cellular Function

Contact Info

Product

Resources

About