Described are ligand-directed catalysts for live-cell, photocatalytic activation of bioorthogonal chemistry. Catalytic groups are localized via a tethered ligand either to DNA or to tubulin, and red-light (660 nm) photocatalysis is used to initiate a cascade of DHTz-oxidation, intramolecular Diels-Alder reaction, and elimination to release phenolic compounds. Silarhodamine (SiR) dyes, more conventionally used as biological fluorophores, serve as photocatalysts that have high cytocompatibility and produce minimal singlet oxygen. Commercially-available conjugates of Hoechst dye (SiR-H) and Taxol (SiR-T) are used to localize SiR to the nucleus and tubulin, respectively. Computation was used to assist the design of a new class of redox-activated photocage to release either phenol or n-CA4, a microtubule-destabilizing agent. In model studies, uncaging is complete within 5 min using only 2 µM of SiR and 40 µM of the photocage. In situ spectroscopic studies support a mechanism involving rapid intramolecular Diels-Alder reaction and a rate determining elimination step. In cellular studies, this uncaging process is successful at low concentration of both the photocage (25 nM) and the SiR-H dye (500 nM). Uncaging n-CA4 causes microtubule depolymerization and an accompanying reduction in cell area. Control studies demonstrate that SiR-H catalyzes uncaging inside the cell, and not in the extracellular environment. With SiR-T, the same dye serves as photocatalyst and the fluorescent reporter for tubulin depolymerization, and with confocal microscopy it was possible to visualize tubulin depolymerization in real time as the result of photocatalytic uncaging in live cells.