Magnetic manipulation of axonal endosome transport in live neurons

Noninvasive control of axonal cargos in live neurons is a challenging prospect that can enable novel research on the mechanisms of axonal cargo transport, cargo-mediated signaling and axonal traffic jams in neurons. However, conventional techniques for force manipulation such as optical traps are limited to a few micronsized cargos and are not applicable to the small axonal cargos in live neurons. Here, we present a new methodology that permits the external control of axonal endosome transport via tailored magnetic forces. By culturing neurons in a microfluidic device made up of microfabricated magnetic arrays, we can exert 3 to 48 pN forces on retrograde axonal endosomes carrying fluorescent magnetic nanoparticles, 100 to 260 nm in size. The magnetic force counters the forces exerted by molecular motors driving the endosomes and results in a wide range of perturbations on endosome transport in axons. These perturbations, captured by oblique illumination fluorescence imaging, reveal new insights on the collective function of dyneins and the nature of paused and stationary states during retrograde endosome transport in axons. Most notably, we demonstrate controllable capture and release of retrograde endosomes in axons by toggling the external magnetic field. This technical advance has great potential to elucidate the spatiotemporal origins of long-distance endosome signaling pathways as well as the ramifications of axonal traffic jams in neurons.