CAIXplatins: Highly Potent Platinum(IV) Prodrugs Selective Against Carbonic Anhydrase†IX for the Treatment of Hypoxic Tumors.

Hypoxia and the acidic microenvironment play a vital role in tumor metastasis and angiogenesis, generally compromising the chemotherapeutic efficacy. This provides a tantalizing angle for the design of platinum(IV) prodrugs for the effective and selective killing of solid tumors. Herein, two carbonic anhydrase IX (CAIX)-targeting platinum(IV) prodrugs have been developed, named as CAIXplatins. Based on their strong affinity for and inhibition of CAIX, CAIXplatins can not only overcome hypoxia and the acidic microenvironment, but also inhibit metabolic pathways of hypoxic cancer cells, resulting in a significantly enhanced therapeutic effect on hypoxic MDA-MB-231 tumors both in vitro and in vivo compared with cisplatin/oxaliplatin, accompanied with excellent anti-metastasis and anti-angiogenesis activities. Furthermore, the cancer selectivity indexes of CAIXplatins are 70-90 times higher than those of cisplatin/oxaliplatin with effectively alleviated side-effects.

Multifunctional low-temperature photothermal nanodrug with in vivo clearance, ROS-Scavenging and anti-inflammatory abilities.

Harsh photothermal temperatures, long-term body retention of nanoagents, elevated ROS and inflammation induction all threaten the normal tissues, thus hindering the translation of photothermal therapy (PTT) from bench to clinical practice. To resolve these problems, we have developed a disassembled theranostic nanodrug Qu-FeIIP based on the quercetin coordination. Herein, quercetin is not only the heat shock protein (Hsp 70) inhibitor but also the skeleton of Qu-FeIIP, realizing near-infrared light induced low-temperature PTT (45 °C) to ablate tumor completely without heat stress to normal tissues. Owing to the ROS scavenging ability of quercetin, Qu-FeIIP effectively reduces intracellular ROS and in vivo inflammatory factors (TNF-α, IL-6, IFN-γ) levels. Simultaneously, quercetin-Fe coordination is weakened when scavenging ROS, which triggers the Qu-FeIIP disassembling, resulting in effective clearance of nanoparticles from main organs 168 h post intravenous injection. Additionally, the photoacoustic and magnetic resonance dual-imaging capability of Qu-FeIIP offers excellent spatial resolution and imaging depth not only for precise tumor diagnosis but also for monitoring the nanodrug disassembling in vivo. Thus, Qu-FeIIP intrinsically integrates precise diagnosis, excellent low-temperature PTT efficacy, ROS elimination and anti-inflammatory action, dynamic disassembly and renal clearance ability into a single nanodrug, which is very promising for future clinical cancer treatment.

Charge-driven tripod somersault on DNA for ratiometric fluorescence imaging of small molecules in the nucleus.

Although fluorescence tracing of small bioactive molecules in living cells has been extensively studied, it is still a challenging task to detect their variations in the nucleus mainly due to the impermeable nuclear membrane and nucleic acid interference. Herein, we take advantage of the nucleic acid enriched environment in the nucleus to establish a strategy, named "charge-driven tripod somersault on DNA", for ratiometric fluorescence imaging of small bioactive molecules in the nucleus. Taking SO2 derivatives as a typical target analyte, a tripodal probe has been constructed by conjugating two DNA binding groups containing a SO2 derivative reaction site. Mechanism studies demonstrate that upon encountering and reacting with SO3 2-/HSO3 -, a charge variation occurs at the responsive arm of the tripodal probe, triggering a tripod somersault on DNA, resulting in the conformational rearrangement of the DNA binding modes with DNA-modulated fluorescence change, which allows the second emission feature to emerge. In this strategy, probe-DNA binding is not influenced by RNA or non-specific protein association, thus making it ideal for tracing nucleus-localized analytes. The application of this strategy has realized both in vitro and in vivo ratiometric fluorescence imaging of the variations of endogenous SO2 derivatives in the nucleus for the first time, with high specificity and selectivity. Also, in theory, this strategy opens up a new avenue for the design of fluorescence probes for the nucleus-localized biological analytes.

Red fluorescent probes for real-time imaging of the cell cycle by dynamic monitoring of the nucleolus and chromosome.

Two cationic molecular rotors, 1 and 2, capable of real-time cell-cycle imaging by specifically dynamic monitoring of nucleolus and chromosome changes were developed. A further study shows that fluorescence enhancements in the nucleolus and chromosome are attributed to a combination effect of interaction with nucleic acid and high condensation of the nucleolus and chromosome.