Weak ergodicity breaking of receptor motion in living cells stemming from random diffusivity

TL;DR

This study demonstrates that the receptor DC-SIGN exhibits nonergodic subdiffusive motion on living cell membranes, driven by diffusion heterogeneity, with implications for understanding membrane dynamics and biological function.

Contribution

It provides experimental evidence of nonergodic subdiffusion in living cells, linking receptor structure to motion, and introduces a model of diffusion heterogeneity as the underlying mechanism.

Findings

DC-SIGN shows nonergodic subdiffusion on cell membranes.

Diffusivity changes are consistent with membrane heterogeneity.

Receptor structure influences its diffusive behavior.

Abstract

Molecular transport in living systems regulates numerous processes underlying biological function. Although many cellular components exhibit anomalous diffusion, only recently has the subdiffusive motion been associated with nonergodic behavior. These findings have stimulated new questions for their implications in statistical mechanics and cell biology. Is nonergodicity a common strategy shared by living systems? Which physical mechanisms generate it? What are its implications for biological function? Here, we use single particle tracking to demonstrate that the motion of DC-SIGN, a receptor with unique pathogen recognition capabilities, reveals nonergodic subdiffusion on living cell membranes. In contrast to previous studies, this behavior is incompatible with transient immobilization and therefore it can not be interpreted according to continuous time random walk theory. We show that the receptor undergoes changes of diffusivity, consistent with the current view of the cell membrane as a highly dynamic and diverse environment. Simulations based on a model of ordinary random walk in complex media quantitatively reproduce all our observations, pointing toward diffusion heterogeneity as the cause of DC-SIGN behavior. By studying different receptor mutants, we further correlate receptor motion to its molecular structure, thus establishing a strong link between nonergodicity and biological function. These results underscore the role of disorder in cell membranes and its connection with function regulation. Due to its generality, our approach offers a framework to interpret anomalous transport in other complex media where dynamic heterogeneity might play a major role, such as those found, e.g., in soft condensed matter, geology and ecology.