Limited therapeutic efficacy to hypoxic and refractory solid tumors has hindered the practical application of photodynamic therapy(PDT). Tw on ew benzothiophenylisoquinoline (btiq)-derived cyclometalated Ir III complexes, IrL1 and MitoIrL2,w ere constructed as potent photosensitizers, with the latter being designed for mitochondria accumulation. Both complexes demonstrated at ype IP DT process and caused photoinduced ferroptosis in tumor cells under hypoxia. This ferroptosis featured lipid peroxide accumulation, mitochondria shrinkage,d own-regulation of glutathione peroxidase 4(GPX4), and ferrostatin-1 (Fer-1)-inhibited cell death. Upon photoirradiation under hypoxia, mitochondria targeting MitoIrL2 caused mitochondria membrane potential (MMP) collapse,A TP production suppression, and induced cell apoptosis.T he synergetic effect of ferroptosis and apoptosis causes MitoIrL2 to outperform IrL1 in inhibiting the growth of MCF-7, PANC-1, MDA-MB-231 cells and multicellular spheroids.T his study demonstrates the first example of ferroptosis induced by photosensitizing Ir III complexes.Moreover,t he synergism of ferroptosis and apoptosis provides ap romising approach for combating hypoxics olid tumors through type IP DT processes.
Mitochondria–lysosome interactions are essential for maintaining intracellular homeostasis. Although various fluorescent probes have been developed to visualize such interactions, they remain unable to label mitochondria and lysosomes simultaneously and dynamically track their interaction. Here, we introduce a cell-permeable, biocompatible, viscosity-responsive, small organic molecular probe, Coupa, to monitor the interaction of mitochondria and lysosomes in living cells. Through a functional fluorescence conversion, Coupa can simultaneously label mitochondria with blue fluorescence and lysosomes with red fluorescence, and the correlation between the red–blue fluorescence intensity indicates the progress of mitochondria–lysosome interplay during mitophagy. Moreover, because its fluorescence is sensitive to viscosity, Coupa allowed us to precisely localize sites of mitochondria–lysosome contact and reveal increases in local viscosity on mitochondria associated with mitochondria–lysosome contact. Thus, our probe represents an attractive tool for the localization and dynamic tracking of functional mitochondria–lysosome interactions in living cells.
A photosensitizing monofunctional Pt complex, Pt‐BDPA, was prepared with a BODIPY chromophore. Apart from its DNA binding ability, this complex displays emission at ca. 578 nm and a singlet oxygen quantum yield of 0.133. Confocal imaging revealed that this complex was sequestered in lysosomes via endocytosis in the dark, preventing its access to the nucleus. Profiting from its photoinduced ROS generation ability, this complex undergoes lysosomal escape to access the nucleus upon photoirradiation. The photoinduced ROS still cause a drop in intracellular GSH, favoring the stability of Pt‐BDPA and contributing to its nuclear DNA accessibility. This complex displayed distinct cytotoxicity to all tested tumor cell lines upon photoirradiation, and the IC50 values were ca. 3–6 μm, which are distinctly lower than those found with only dark incubation (IC50>50 μm). These results are consistent with photoactivated lysosomal escape of this photosensitizing Pt complex to access the nucleus.
As the cleaners of cells, lysosomes play an important
role in circulating
organic matter within cells, recovering damaged organelles, and removing
waste via endocytosis. Because lysosome dysfunction is associated
with various diseaseslysosomal storage diseases, inherited
diseases, rheumatoid arthritis, and even shockit is vital
to monitor the movement of lysosomes in cells and in vivo. To that purpose, a method of optical imaging, super-resolution
imaging technology (e.g., SIM and STORM), can overcome the limitations
of traditional optical imaging and afford a range of possibilities
for fluorescence imaging. However, the short wavelength excitation
and easy photobleaching of super-resolution fluorescence probes somewhat
problematize super-resolution imaging. As described herein, we designed
a low-toxicity, photostable, near-infrared small molecule fluorescence
probe HD-Br for use in the super-resolution imaging of
lysosomes. The interaction of lysosomes and mitochondria was dynamically
traced while using the probe’s properties to label the lysosomes.
Because the probe has the optimal near-infrared excitation and emission
wavelengths, liver organoid 3D imaging and Caenorhabditis
elegans imaging were also performed. Altogether, our findings
indicate valuable approaches and techniques for super-resolution 3D
and in vivo imaging.
Zn2+ plays important roles in metabolism and signaling regulation. Subcellular Zn2+ compartmentalization is essential for organelle functions and cell biology, but there is currently no method to determine Zn2+ signaling relationships among more than two different organelles with one probe. Here, we report simultaneous Zn2+ tracking in multiple organelles (Zn-STIMO), a method that uses structured illumination microscopy (SIM) and a single Zn2+ fluorescent probe, allowing super-resolution morphology-correlated organelle identification in living cells. To guarantee SIM imaging quality for organelle identification, we develop a new turn-on Zn2+ fluorescent probe, NapBu-BPEA, by regulating the lipophilicity of naphthalimide-derived Zn2+ probes to make it accumulate in multiple organelles except the nucleus. Zn-STIMO with this probe shows that CCCP-induced mitophagy in HeLa cells is associated with labile Zn2+ enhancement. Therefore, direct organelle identification supported by SIM imaging makes Zn-STIMO a reliable method to determine labile Zn2+ dynamics in various organelles with one probe. Finally, SIM imaging of pluripotent stem cell-derived organoids with NapBu-BPEA demonstrates the potential of super-resolution morphology-correlated organelle identification to track biospecies and events in specific organelles within organoids.
Reversible NIR luminescent probes with negligible photocytotoxicity are required for long-term tracking of cycling hypoxia in vivo. However, almost all of the reported organic fluorescent hypoxia probes reported until now were irreversible. Here we report a reversible arylazo-conjugated fluorescent probe (HDSF) for cycling hypoxia imaging. HDSF displays an off-on fluorescence switch at 705 nm in normoxia-hypoxia cycles. Mass spectroscopic and theoretical studies confirm that the reversible sensing behavior is attributed to the two electron-withdrawing trifluoromethyl groups, which stabilizes the reduction intermediate phenylhydrazine and blocks the further reductive decomposition. Cycling hypoxia monitoring in cells and zebrafish embryos is realized by HDSF using confocal imaging. Moreover, hypoxic solid tumors are visualized and the ischemia-reperfusion process in mice is monitored in real-time. This work provides an effective strategy to construct organic fluorescent probes for cycling hypoxia imaging and paves the way for the study of cycling hypoxia biology.
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