Single-Particle Tracking Photoactivated Localization Microscopy For Mapping Single-Molecule Dynamics

Recent developments in single-molecule localization techniques using photoactivatable fluorescent proteins have allowed the probing of single-molecule motion in a living cell with high specificity, millisecond time resolution, and nanometer spatial resolution. Analyzing the dynamics of individual molecules at high densities in this manner promises to provide new insights into the mechanisms of many biological processes, including protein heterogeneity in the plasma membrane, the dynamics of cytoskeletal flow, and clustering of receptor complexes in response to signaling cues. Here we describe the method of single-molecule tracking photoactivated localization microscopy (sptPALM) and discuss how its use can contribute to a quantitative understanding of fundamental cellular processes.

Single-Particle Tracking Photoactivated Localization Microscopy For Mapping Single-Molecule Dynamics

Time-Resolved Scanning Ion Conductance Microscopy and Single-Molecule Spectroscopy

Protocol for live imaging of intracellular nanoscale structures using atomic force microscopy with nanoneedle probes

Live-cell lipid biochemistry reveals a role of diacylglycerol side-chain composition for cellular lipid dynamics and protein affinities

Time-Resolved Scanning Ion Conductance Microscopy and Single-Molecule Spectroscopy

Protocol for live imaging of intracellular nanoscale structures using atomic force microscopy with nanoneedle probes

Live-cell lipid biochemistry reveals a role of diacylglycerol side-chain composition for cellular lipid dynamics and protein affinities