We introduce far-red, fluorogenic probes that combine minimal cytotoxicity with excellent brightness and photostability for fluorescence imaging of actin and tubulin in living cells. Applied in stimulated emission depletion (STED) microscopy, they reveal the ninefold symmetry of the centrosome and the spatial organization of actin in the axon of cultured rat neurons with a resolution unprecedented for imaging cytoskeletal structures in living cells.
The interaction of lipids and proteins plays an important role in plasma membrane bioactivity, and much can be learned from their diffusion characteristics. Here we present the combination of super-resolution STED microscopy with scanning fluorescence correlation spectroscopy (scanning STED-FCS, sSTED-FCS) to characterize the spatial and temporal heterogeneity of lipid interactions. sSTED-FCS reveals transient molecular interaction hotspots for a fluorescent sphingolipid analogue. The interaction sites are smaller than 80 nm in diameter and lipids are transiently trapped for several milliseconds in these areas. In comparison, newly developed fluorescent phospholipid and cholesterol analogues with improved phase-partitioning properties show more homogenous diffusion, independent of the preference for liquid-ordered or disordered membrane environments. Our results do not support the presence of nanodomains based on lipid-phase separation in the basal membrane of our cultured nonstimulated cells, and show that alternative interactions are responsible for the strong local trapping of our sphingolipid analogue.
SignificancePopular localization of single molecules through calculating the centroid of the diffraction pattern produced by molecular fluorescence on a camera is typically limited to spatiotemporal resolutions of >10 nm per >10 milliseconds. By requiring at least 10–100 times fewer detected photons and being free of bias due to molecular orientation, the localization concept called MINFLUX propels molecular tracking to the hitherto-unachievable regime of single-digit nanometer precision within substantially less than a millisecond. Our experiments herald the feasibility to detect molecular interactions and conformational changes at microsecond timescales.
Here we present a
far-red, silicon-rhodamine-based fluorophore (SiR700) for live-cell
multicolor imaging. SiR700 has excitation and emission maxima at 690
and 715 nm, respectively. SiR700-based probes for F-actin, microtubules,
lysosomes, and SNAP-tag are fluorogenic, cell-permeable, and compatible
with superresolution microscopy. In conjunction with probes based
on the previously introduced carboxy-SiR650, SiR700-based probes permit
multicolor live-cell superresolution microscopy in the far-red, thus
significantly expanding our capacity for imaging living cells.
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