Litcius/Paper detail

MINFLUX reveals dynein stepping in live neurons

Jonas M. Schleske, Jasmine Hubrich, Jan Otto Wirth, Elisa D’Este, Johann Engelhardt, Stefan W. Hell

2024Proceedings of the National Academy of Sciences18 citationsDOIOpen Access PDF

Abstract

Dynein is the primary molecular motor responsible for retrograde intracellular transport of a variety of cargoes, performing successive nanometer-sized steps within milliseconds. Due to the limited spatiotemporal precision of established methods for molecular tracking, current knowledge of dynein stepping is essentially limited to slowed-down measurements in vitro. Here, we use MINFLUX fluorophore localization to directly track CRISPR/Cas9-tagged endogenous dynein with nanometer/millisecond precision in living primary neurons. We show that endogenous dynein primarily takes 8 nm steps, including frequent sideways steps but few backward steps. Strikingly, the majority of direction reversals between retrograde and anterograde movement occurred on the time scale of single steps (16 ms), suggesting a rapid regulatory reversal mechanism. Tug-of-war-like behavior during pauses or reversals was unexpectedly rare. By analyzing the dwell time between steps, we concluded that a single rate-limiting process underlies the dynein stepping mechanism, likely arising from just one adenosine 5'-triphosphate hydrolysis event being required during each step. Our study underscores the power of MINFLUX localization to elucidate the spatiotemporal changes underlying protein function in living cells.

Topics & Concepts

DyneinMillisecondMolecular motorMotor proteinBiologyMechanism (biology)ATP hydrolysisBiophysicsNeuroscienceCell biologyMicrotubulePhysicsBiochemistryEnzymeATPaseAstronomyQuantum mechanicsMicrotubule and mitosis dynamicsCellular transport and secretionAdvanced Fluorescence Microscopy Techniques