Bio-orthogonally Activatable Fluorescent Probe for Specific Imaging of Myeloid Cell Leukemia 1 Protein.

The antiapoptotic protein myeloid cell leukemia 1 (Mcl-1) has been increasingly identified as a promising potential therapeutic target attributed to its critical regulation effect in diverse cellar physiopathological events. Current fluorescence imaging strategies tend to be susceptible to the cellular microenvironment, and straightforward mapping of Mcl-1's level variation remains challenging. In this paper, an activatable "off-on" fluorescence strategy for Mcl-1 specific labeling was presented based on bio-orthogonal chemistry by introducing tetrazine-functionalized borondipyrromethene (TB) as a fluorescent reporter and trans-cyclooctyne-derived indole-2-carboxylic acid (TI) as an Mcl-1 targeting moiety. With the click pair of TB and TI, the Mcl-1 expression level in vitro and in vivo was successfully mapped straightforward. Also, the level changes of Mcl-1 upon drug challenge were demonstrated. This work provides a robust fluorescence strategy for Mcl-1 in situ imaging, and the results would further facilitate the comprehensive revelation of the Mcl-1 biological effect.

Exploration of Thermally Activated Delayed Fluorescence (TADF)-Based Photoredox Catalyst To Establish the Mechanisms of Action for Photodynamic Therapy.

The mechanisms of action (MoA) have been proposed to further reduce the O2 dependence of photodynamic therapy (PDT) significantly. However, the triplet states of traditional photosensitizers are relatively short and also are easily deactivated by the quenching of H2O or O2. This is not conducive for the electron transfer in the photocatalytic process and poses a great obstacle to establish the MoA. Therefore, we selected and synthesized a zirconium(IV) complex (Zr(MesPDPPh)2) reported by Milsmann to address this issue. The specific symmetric and intact geometry endowed Zr(MesPDPPh)2 NPs with long-lived triplet excited state (τ = 350 µs), desired sensitized ability, and improved anti-interfering performance on O2, which was matched with the requirements of photoredox catalyst significantly. The results showed that while PDT (I) and PDT (II) could be achieved simultaneously by leveraging Zr(MesPDPPh)2 NPs, it also could be served as a rare example of thermally activated delayed fluorescence (TADF)-based photoredox catalyst to implement the MoA of PDT. It involved the oxidation of NADH and the establishment of catalytic cycle collaborating by O2 and cytochrome c (cyt c) in normoxia and hypoxia, respectively. As a result, the oxygen-free PDT and tumor-growth inhibition was realized.

Mechanically Robust Hydrogels Facilitating Bone Regeneration through Epigenetic Modulation.

Development of artificial biomaterials by mimicking extracellular matrix of bone tissue is a promising strategy for bone regeneration. Hydrogel has emerged as a type of viable substitute, but its inhomogeneous networks and weak mechanics greatly impede clinical applications. Here, a dual crosslinked gelling system is developed with tunable architectures and mechanics to promote osteogenic capacity. Polyhedral oligomeric silsesquioxane (POSS) is designated as a rigid core surrounded by six disulfide-linked PEG shells and two 2-ureido-4[1H]-pyrimidinone (UPy) groups. Thiol-disulfide exchange is employed to fabricate chemical network because of the pH-responsive "on/off" function. While self-complementary UPy motif is capable of optimizing local microstructure to enhance mechanical properties. Taking the merits of biocompatibility and high-mechanics in periodontal ligament stem cells (PDLSCs) proliferation, attachment, and osteogenesis, hybrid hydrogel exhibits outstanding osteogenic potential both in vitro and in vivo. Importantly, it is the first time that a key epigenetic regulator of ten-eleven translocation 2 (Tet2) is discovered to significantly elevate the continuously active the WNT/ß-catenin through Tet2/HDAC1/E-cadherin/ß-catenin signaling cascade, thereby promoting PDLSCs osteogenesis. This work represents a general strategy to design the hydrogels with customized networks and biomimetic mechanics, and illustrates underlying osteogenic mechanisms that will extend the design rationales for high-functional biomaterials in tissue engineering.