Immuno EM-OM correlative microscopy in solution by atmospheric scanning electron microscopy (ASEM)

摘要

In the atmospheric scanning electron microscope (ASEM), an inverted SEM observes the wet sample from beneath an open dish while an optical microscope (OM) observes it from above. The disposable dish with a silicon nitride (SiN) film window can hoJd afew milliliters of culture medium, and allows various types of cells to be cultured in a stable environment. The use of this system for in situ correlative OM/SEM immuno-microscopy is explored, the efficiency of the required dual-tagged labeling assessedand the imaging capabilities of the ASEM documented. We have visualized the cytoskeletons formed by actin and tubulin, the chaperone PDI that catalyses native disulfide bond formation of proteins in the endoplasmic reticulum (ER) and the calcium sensorSTIM1 that is integrated in ER membranes, using established cell lines. In particular, a dynamic string-like gathering of STIM1 was observed on the ER in Jurkat T cells in response to Ca2+ store depletion. We have also visualized filamentous actin (F-actin) and tubulin in the growth cones of primary-culture neurons as well as in synapses. Further, radially running actin fibers were shown to partly colocalize with concentric bands of the Ca2+ signaling component Homeric in the lamellipodia of neuron primary culture growth cones. After synapse formation, neurite configurations were drastically rearranged; a button structure with a fine F-actin frame faces a spine with a different F-actin framework. Based on this work, ASEM correlative microscopy promisesto allow the dynamics of various protein complexes to be investigated in the near future.