Surpassing the Background Barrier for Multidimensional Single-Molecule Localization Super-Resolution Imaging: A Case of Lysosome-Exclusively Turn-on Probe

The background barrier restricts the dimensionality of live-cell single-molecule localization super-resolution imaging. Ideally, a probe exclusively turned on by its target, without any nonspecific fluorescence signals from off-target molecules, constitutes a practical solution to surpass this barrier. Yet, few such fluorophores have been developed. A lysosome with a unique acidic lumen was chosen as the target for demonstrating the concept advantage. A representative lyso-tracker Lyso-R (piperazine rhodamine) with high brightness has been spirocyclized with o-phenylenediamine to form Lyso-Ropa. This probe shifted its bright-dark spirocyclization balance to a strong acidity domain (pK_a = -0.18). Consequently, under no-wash conditions, Lyso-Ropa showed almost undetectable background photons (only one-sixtieth of that of Lyso-R) in a neutral cellular environment, and it formed sparsely brightened molecules at a low ratio (∼1 × 10^-3%) in lysosomes. This background-free probe enabled super-resolution imaging and modeling of live-cell lysosomes in four dimensions at 2 s resolution, with quantitative determination of lysosomal volume expansion and deformation at starvation. Our molecular approach sheds new light on surpassing the background barrier for multidimensional super-resolution imaging.

Quaternary Piperazine-Substituted Rhodamines with Enhanced Brightness for Super-Resolution Imaging

Insufficient brightness of fluorophores poses a major bottleneck for the advancement of super-resolution microscopes. Despite being widely used, many rhodamine dyes exhibit sub-optimal brightness due to the formation of twisted intramolecular charge transfer (TICT) upon photoexcitation. Herein, we have developed a new class of quaternary piperazine-substituted rhodamines with outstanding quantum yields (Φ = 0.93) and superior brightness (ε × Φ = 8.1 × 10⁴ L·mol^-1·cm^-1), by utilizing the electronic inductive effect to prevent TICT. We have also successfully deployed these rhodamines in the super-resolution imaging of the microtubules of fixed cells and of the cell membrane and lysosomes of live cells. Finally, we demonstrated that this strategy was generalizable to other families of fluorophores, resulting in substantially increased quantum yields.