Dynamic
tracing of intracellular telomerase activity plays a crucial
role in cancer cell recognition and correspondingly in earlier cancer
diagnosis and personalized precision therapy. However, due to the
complexity of the required reaction system and insufficient loading
of reaction components into cells, achieving a high-fidelity determination
of telomerase activity is still a challenge. Herein, an Aptamer-Liposome
mediated Telomerase activated poly-Molecular beacon Arborescent Nanoassembly(ALTMAN)
approach was described for direct high-fidelity visualization of telomerase
activity. Briefly, intracellular telomerase activates molecular beacons,
causing their hairpin structures to unfold and produce fluorescent
signals. Furthermore, multiple molecular beacons can self-assemble,
forming arborescent nanostructures and leading to exponential amplification
of fluorescent signals. Integrating the enzyme-free isothermal signal
amplification successfully increased the sensitivity and reduced interference
by leveraging the skillful design of the molecular beacon and the
extension of the telomerase-activated TTAGGG repeat sequence. The
proposed approach enabled ultrasensitive visualization of activated
telomerase exclusively with a prominent detection limit of 2 cells·μL–1 and realized real-time imaging of telomerase activity
in living cancer cells including blood samples from breast cancer
patients and urine samples from bladder cancer patients. This approach
opens an avenue for establishing a telomerase activity determination
and in situ monitoring technique that can facilitate
both telomerase fundamental biological studies and cancer diagnostics