Long-Lasting Bioluminescence Imaging of the Fibroblast Activation Protein by an Amphiphilic Block Copolymer-Based Probe.

Long-term specific tracing of the fibroblast activation protein (FAP) has been of great importance because it is heavily expressed by stromal fibroblasts of multiple diseases, and several disorders associated with FAP are chronical. Bioluminescence (BL) imaging has its advantages to detect FAP in vivo since no external excitation is required, but the current FAP-responsive BL probe was constructed by covalently masking the firefly luciferase substrate and easily secreted out from the animal, resulting in transient BL imaging of FAP. To circumvent this problem, a peptide-linked amphiphilic block copolymer-based probe (PABC) was developed and applied to the long-lasting BL image of FAP in vivo. For this purpose, an amphiphilic block copolymer containing an FAP-responsive peptide was fabricated to self-assemble into micelles, which act as a depot to load amounts of d-luciferin for constructing the BL probe. Upon reaction with FAP, the micelle would be destroyed to release the internal d-luciferin for BL emission by a luciferase-catalyzed reaction. By virtue of the high loading capability of micelles, the FAP was determined from 0.5 to 10 ng/mL with a detection limit of 0.105 ng/mL, and the high sensitivity makes the PABC capable of distinguishing cancer cells from normal ones. Importantly, compared with free d-luciferin, PABC can be used to persistently image the FAP in living cells and in vivo. This characteristic of long-lasting specific tracing of the FAP makes us envision that this BL probe could be used for screening of FAP inhibitors and diagnosing various FAP-related diseases in future.

Noncovalently Caged Firefly Luciferins Enable Amplifiable Bioluminescence Sensing of Hyaluronidase-1 Activity in Vivo.

Hyaluronidase 1 (Hyal-1) is an important enzyme involved in intracellular hyaluronic acid (HA) catabolism for performing various physiological functions, and its aberrant level is closely associated with many malignant diseases. Bioluminescence imaging is advantageous for monitoring Hyal-1 activity in vivo, but it remains challenging to design an available probe for differentiating Hyal-1 from other isoforms by a traditional strategy that covalently masks the firefly luciferase substrate. Herein, we, for the first time, present a noncovalently caging approach to construct a Hyal-1-specific bioluminogenic nanosensor by entrapping d-luciferin (d-Luc) inside the cholesterylamine-modified HA (CHA) nanoassembly to inhibit the bioluminescence production. When encountered with intracellular Hyal-1, CHA could be fully dissembled to liberate multiple copies of the loaded d-Luc, thereby emitting light by the luciferase-catalyzed bioluminescence reaction. Because of its cascade signal amplification feature, d-Luc@CHA displayed a remarkable "turn-on" response (248-fold) to 5 µg/mL Hyal-1 with a detection limit of 0.07 ng/mL. Importantly, bioluminescence imaging results validated that d-Luc@CHA could be competent for dynamically visualizing endogenous Hyal-1 changes in living cells and animals and possessed the capability of discriminating between normal and cancer cells, thus offering a promising toolbox to evaluate Hyal-1 roles in biological processes as well as to diagnose Hyal-1-related diseases.

Differentiation of Intracellular Hyaluronidase Isoform by Degradable Nanoassembly Coupled with RNA-Binding Fluorescence Amplification.

Hyaluronidase has two cruical isoforms, hyaluronidase-1 (Hyal-1) and hyaluronidase-2 (Hyal-2), which are essential for cellular hyaluronic acid (HA) catabolism to generate different-sized oligosaccharide fragments for performing different physiological functions. In particular, Hyal-1 is the major tumor-derived hyaluronidase. Thus, specific detection of one hyaluronidase isoform, especially Hyal-1, in live cells is of scientific significance but remains challenging. Herein, by use of differentiated tolerance capability of an amphiphilic HA-based nanoassembly to Hyal-1 and Hyal-2, we rationally design a Hyal-1 specific nanosensor, consisting of cholesterylamine-modified HA nanoassembly (CHA) and RNA-binding fluorophores (RBF). The RBF molecules were entrapped in CHA to switch off their fluorescence via aggregation caused quenching. However, CHA can be disassembled by Hyal-1 to release RBF, resulting in fluorescence activation. Moreover, the fluorescence of the released RBF is further enhanced by cytoplasm RNA. Owing to this cascade signal amplification, this nanosensor RBF@CHA displays a significant change of signal-to-background-noise ratio (120-fold) toward 16 µg/mL Hyal-1 in cellular lysates. In contrast, it is resistant to Hyal-2. By virtue of its selective and sensitive characteristics under a complicated matrix, RBF@CHA had been successfully applied for specifically visualizing Hyal-1 over Hyal-2 inside live cells for the first time, detecting a low level of intracellular Hyal-1 and distinguishing normal and cancer cells with different expressions of Hyal-1. This approach would be useful to better understand biological functions and related diseases of intracellular Hyal-1.