Interplay between membrane elasticity and active cytoskeleton forces regulates the aggregation dynamics of the immunological synapse

TL;DR

This study presents a physical model combining thermodynamic membrane interactions and active cytoskeleton forces to explain the formation and dynamics of the immunological synapse, validated by simulations matching experimental observations.

Contribution

It introduces a combined passive-active mechanism model for immunological synapse formation, highlighting the roles of membrane interactions and cytoskeleton forces in pattern dynamics.

Findings

Actin retrograde flow drives TCR-pMHC centripetal movement.

Membrane-mediated interactions promote microcluster formation.

Dynein motors are essential for the final concentric pattern.

Abstract

Adhesion between a T cell and an antigen presenting cell is achieved by TCR-pMHC and LFA1-ICAM1 protein complexes. These segregate to form a special pattern, known as the immunological synapse (IS), consisting of a central quasi-circular domain of TCR-pMHC bonds surrounded by a peripheral domain of LFA1-ICAM1 complexes. Insights gained from imaging studies had led to the conclusion that the formation of the central adhesion domain in the IS is driven by active (ATP-driven) mechanisms. Recent studies, however, suggested that passive (thermodynamic) mechanisms may also play an important role in this process. Here, we present a simple physical model, taking into account the membrane-mediated thermodynamic attraction between the TCR-pMHC bonds and the effective forces that they experience due to ATP-driven actin retrograde flow and transport by dynein motor proteins. Monte Carlo simulations of the model exhibit a good spatio-temporal agreement with the experimentally observed pattern evolution of the TCR-pMHC microclusters. The agreement is lost when one of the aggregation mechanisms is "muted", which helps to identify the respective roles in the process. We conclude that actin retrograde flow drives the centripetal motion of TCR-pMHC bonds, while the membrane-mediated interactions facilitate microcluster formation and growth. In the absence of dynein motors, the system evolves into a ring-shaped pattern, which highlights the role of dynein motors in the formation of the final concentric pattern. The interplay between the passive and active mechanisms regulates the rate of the accumulation process, which in the absence of one them proceeds either too quickly or slowly.