High-density single-molecule maps reveal transient membrane receptor interactions within a dynamically varying environment

TL;DR

This paper introduces HiDenMap, a high-density single-molecule imaging method that achieves nanometric spatial and millisecond temporal resolution in live cells, revealing complex transient interactions of membrane receptors with the cytoskeleton.

Contribution

The study presents a novel analytical approach enabling high-density, high-resolution live-cell single-molecule imaging, allowing detailed analysis of dynamic molecular interactions.

Findings

Revealed heterogeneous organization of membrane proteins interacting with actin

Discovered transient trapping and nanoclustering of CD44

Linked receptor dynamics to actin cytoskeleton remodeling

Abstract

Over recent years, super-resolution and single-molecule imaging methods have delivered unprecedented details on the nanoscale organization and dynamics of individual molecules in different contexts. Yet, visualizing single-molecule processes in living cells with the required spatial and temporal resolution remains highly challenging. Here, we report on an analytical approach that extracts such information from live-cell single-molecule imaging at high-labeling densities using standard fluorescence probes. Our high-density-mapping (HiDenMap) methodology provides single-molecule nanometric localization accuracy together with millisecond temporal resolution over extended observation times, delivering multi-scale spatiotemporal data that report on the interaction of individual molecules with their dynamic environment. We validated HiDenMaps by simulations of Brownian trajectories in the presence of patterns that restrict free diffusion with different probabilities. We further generated and analyzed HiDenMaps from single-molecule images of transmembrane proteins having different interaction strengths to cortical actin, including the transmembrane receptor CD44. HiDenMaps uncovered a highly heterogenous and multi-scale spatiotemporal organization for all the proteins that interact with the actin cytoskeleton. Notably, CD44 alternated between periods of random diffusion and transient trapping, likely resulting from actin-dependent CD44 nanoclustering. Whereas receptor trapping was dynamic and lasted for hundreds of milliseconds, actin remodeling occurred at the timescale of tens of seconds, coordinating the assembly and disassembly of CD44 nanoclusters rich regions. Together, our data demonstrate the power of HiDenMaps to explore how individual molecules interact with and are organized by their environment in a dynamic fashion.