Nanoscopic Imaging of Nucleolar Stress Enabled by Protein-Mimicking Carbon Dots

The nucleolus is a central hub for coordinating cellular stress responses during cancer development and treatment. Accurate identification of nucleolar stress response is crucially desired for nucleolus-based diagnostics and therapeutics but technically challenging due to the need to address the ultrastructural analysis. Here, we report a protein-like CD with the integration of fluorescent blinking domains and RNA-binding motifs, which offers the ability to perform enhanced super-resolution imaging of the nucleolar ultrastructure. This image allows extraction of multidimensional information from the nucleolus for accurate distinguishment of different cells from the same cell types. Furthermore, we demonstrate for the first time this CD-depicted nucleolar ultrastructure as a sensitive hallmark to identify and discriminate subtle responses to various stressors as well as to afford RNA-related information that has been inaccessible by conventional immunofluorescence methods. This protein-mimicking CD could become a broadly useful probe for nucleolar stress studies in cell diagnostics and therapeutics.

Automated summary

The nucleolus is a central hub for coordinating cellular stress responses during cancer development and treatment. Accurate identification of nucleolar stress response is crucially desired for nucleolus-based diagnostics and therapeutics, which is technically challenging due to the need to address ultrastructural analysis. A protein-like CD has been reported with the integration of fluorescent blinking domains and RNA-binding motifs, offering enhanced super-resolution imaging of the nucleolar ultrastructure for extracting multidimensional information and accurate distinguishment of different cell types. This CD-depicted nucleolar ultrastructure serves as a sensitive hallmark to identify and discriminate subtle responses to various stressors and provide RNA-related information inaccessible by conventional immunofluorescence methods, potentially becoming a broadly useful probe for nucleolar stress studies in cell diagnostics and therapeutics.