Coexistence of long and short DNA constructs within adhesion plaques

Li, Long; Kamal, Mohammad Arif; Stumpf, Henning; Thibaudau, F.; Sengupta, Kheya; Smith, Ana‐Sunčana

doi:10.1101/2020.05.12.090357

Cited by 2 publications

(2 citation statements)

References 21 publications

(10 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The current implementation of the code can account for ligands, receptors, repellers, intermittent bridges (which can swap between membranes) and other protein types [ 23 ]. Besides trans interactions, it is also possible to account for direct lateral cis interactions, and several protein types (mobile or arrested binders, tethers, repellers), however, at the expense of additional parametrisation.…”

Section: Methods: Kinetic Monte Carlo Simulationsmentioning

confidence: 99%

“…On the other hand, for smaller affinities and smaller separations, adhesion proceeds through the formation of numerous and small, but mixed clusters that quickly merge (top right part of the phase diagram). The composition of the mixed state depends on the relative densities of the two ligands and receptors, as discussed recently [ 23 ].…”

Section: Effect Of the Difference In The Length Of Ligand-receptormentioning

confidence: 99%

See 1 more Smart Citation

Molecular Biomechanics Controls Protein Mixing and Segregation in Adherent Membranes

Stumpf

Smith

2021

IJMS

Self Cite

View full text Add to dashboard Cite

Cells interact with their environment by forming complex structures involving a multitude of proteins within assemblies in the plasma membrane. Despite the omnipresence of these assemblies, a number of questions about the correlations between the organisation of domains and the biomechanical properties of the involved proteins, namely their length, flexibility and affinity, as well as about the coupling to the elastic, fluctuating membrane, remain open. Here we address these issues by developing an effective Kinetic Monte Carlo simulation to model membrane adhesion. We apply this model to a typical experiment in which a cell binds to a functionalized solid supported bilayer and use two ligand-receptor pairs to study these couplings. We find that differences in affinity and length of proteins forming adhesive contacts result in several characteristic features in the calculated phase diagrams. One such feature is mixed states occurring even with proteins with length differences of 10 nm. Another feature are stable nanodomains with segregated proteins appearing on time scales of cell experiments, and for biologically relevant parameters. Furthermore, we show that macroscopic ring-like patterns can spontaneously form as a consequence of emergent protein fluxes. The capacity to form domains is captured by an order parameter that is founded on the virial coefficients for the membrane mediated interactions between bonds, which allow us to collapse all the data. These findings show that taking into account the role of the membrane allows us to recover a number of experimentally observed patterns. This is an important perspective in the context of explicit biological systems, which can now be studied in significant detail.

show abstract

Section: Methods: Kinetic Monte Carlo Simulationsmentioning

confidence: 99%

Section: Effect Of the Difference In The Length Of Ligand-receptormentioning

confidence: 99%

Molecular Biomechanics Controls Protein Mixing and Segregation in Adherent Membranes

Stumpf

Smith

2021

IJMS

Self Cite

View full text Add to dashboard Cite

show abstract

Synergistic Regulation Mechanism of Selectin and Integrin on Leukocyte Adhesion Under Shear Flow

Kang

Wang

2021

Journal of Applied Mechanics

View full text Add to dashboard Cite

In the process of inflammation, the hydrodynamic process of circulating leukocyte recruitment to the inflammatory site requires the rolling adhesion of leukocytes in blood vessels mediated by selectin and integrin molecules. Although a number of experiments have demonstrated that cooperative effects exist between selectins and integrins in leukocyte rolling adhesion under shear flow, the mechanisms underlying how the mechanics of selectins and integrins synergistically may govern the dynamics of cell rolling is not yet fully resolved. Here we present a mechanical model on selectin- and integrin- jointly mediated rolling adhesion of leukocyte in shear flow, by considering two pairs' binding/unbinding events as Markov processes and describing kinetics of leukocyte by the approach of continuum mechanics. Through examining the dynamics of leukocyte rolling as a function of relative fraction of selectin and integrin pairs, we show that, during recruitment, the elongation of intermittent weak selectin bonds consuming the kinetic energy of rolling leukocyte decelerates the rolling speed and enables the integrin pairs to form strong bonds, therefore achieving the arrestment of leukocyte (firm adhesion). The coexistence of selectins and integrins may also be required for effective phase transition from firm adhesion to rolling adhesion, due to dynamic competition in pairs' formation and elongation. These results are verified by the relevant Monte Carlo simulations and related to reported experimental observations.

show abstract

Coexistence of long and short DNA constructs within adhesion plaques

Cited by 2 publications

References 21 publications

Molecular Biomechanics Controls Protein Mixing and Segregation in Adherent Membranes

Molecular Biomechanics Controls Protein Mixing and Segregation in Adherent Membranes

Synergistic Regulation Mechanism of Selectin and Integrin on Leukocyte Adhesion Under Shear Flow

Contact Info

Product

Resources

About