Most of the antitumor chemotherapeutic drugs execute the therapeutic performance upon eliciting tumor cell apoptosis, which may cause chemoresistance of tumors. Design of novel drugs to eradicate apoptosis-resistant tumors via non-apoptotic cell death pathways is promising for improving the long-term chemotherapeutic efficacy. Herein, a Fe(III)-Shikonin metal-polyphenol-coordinated supramolecular nanomedicine for combined therapy of tumor via ferroptosis and necroptosis is designed. The construction of the nanomedicine based on the coordinated self-assembly between Fe 3+ and Shikonin not only overcomes the shortcomings of Shikonin including its low bioavailability and high toxicity toward normal tissues, but also integrates the theranostics functions of Fe ions. Under the exposure of the high concentration of glutathione (GSH) in tumor cells, the as-prepared nanomedicine will disassemble into Fe 2+ and Shikonin, followed by stimulating the tumor cell death through ferroptosis and necroptosis. In addition, benefiting from the stealth effect of polyethylene glycol (PEG) and the targeting ability of cyclo(Arg-Gly-Asp-d-Phe-Lys) (cRGD) to 𝜶 v 𝜷 3 -integrin, NH 2 -PEG-cRGD-modified nanomedicine exhibits a GSH-responsive therapy toward 4T1 tumor in vivo and self-enhanced longitudinal relaxation (T 1 )-weighted imaging property. Since the self-assembly of natural Shikonin and human body-necessary Fe element is facile and feasible, the work may provide a promising supramolecular nanomedicine for next-generation chemotherapeutic applications.
Ferroptosis has been considered as a promising pathway
to overcome
apoptosis-induced tumor chemoresistance. However, the antitumor efficacy
of ferroptosis-inducing agents is still limited because of the complexity
and diversity of tumor microenvironments. Herein, we demonstrate a
triple ferroptosis amplification strategy for tumor therapy by associating
iron-based nanocarriers, ferroptosis molecular drugs, and H2O2-producing enzymes. Fe(III)-Shikonin (FeShik) metal-polyphenol-coordinated
networks are employed to load a ferroptosis inducer of sorafenib (SRF)
inside and glucose oxidase (GOx) outside, thus producing SRF@FeShik-GOx
supramolecular nanomedicines (SNs). After delivering into glutathione
(GSH)-overexpressed tumor cells, FeShik will disassemble and release
Fe2+ to induce cell death via ferroptosis. At the same
time, GOx executes its catalytic activity to produce an acid environment
and plenty of H2O2 for stimulating •OH generation via the Fenton reaction. Moreover, SRF will suppress
the biosynthesis of GSH by inhibiting system Xc–, further deactivating the enzymatic activity of glutathione peroxidase
4 (GPX4). Up-regulation of the oxidative stress level and down-regulation
of GPX4 expression can dramatically accelerate the accumulation of
lethal lipid peroxides, leading to ferroptosis amplification of tumor
cells. The current strategy that utilizes ferroptosis-inducing agents
as both nanocarriers and cargoes provides a pathway to enhance the
efficacy of ferroptosis-based tumor therapy.
Nanovaccine-based immunotherapy has been considered as a major pillar to stimulate the host immune system to recognize and eradicate tumor cells as well as establish a long-term immune memory to prevent tumor relapse and metastasis. However, the weak specificity and low crosspresentation of antigens, as well as the immunosuppressive microenvironments of tumor tissues, are still the major obstacles on exerting the therapeutic performance of tumor nanovaccines sufficiently. Herein, we design and construct cytosine guanine dinucleotide (CpG) oligodeoxynucleotide (ODN)-loaded aluminum hydroxyphosphate nanoparticles covered by Fe-Shikonin metal-phenolic networks (MPNs) (Alum-CpG@Fe-Shikonin NPs) as personalized in situ nanovaccines for antitumor immunity. Upon internalization by tumor cells, the shell of Fe-Shikonin MPNs will disassemble into Fe 2+ and Shikonin to elicit the immunogenic cell death of tumor cells through ferroptosis and necroptosis. Then, dying tumor cell-released autologous tumor cell lysates will be absorbed by Alum NPs and codelivered with CpG ODN to professional antigen-presenting cells temporally and spatially to activate multistep cascade antitumor immune responses, including dendritic cell maturation, antigen cross-presentation, natural killer cell and cytotoxic T lymphocyte infiltrations, and tumor-associated macrophage repolarization. Benefiting from the synergistic effects of Alum NPs, CpG ODN, and Fe-Shikonin MPNs, our Alum-CpG@Fe-Shikonin NPs exhibit drastic cytotoxicity and accurate selectivity on eradicating primary tumor, strong abscopal effect on inhibiting distant tumor, and a long-term immune memory effect on preventing tumor metastasis and recurrence. Because our report provides a feasible strategy to in situ make full use of autologous tumor cell lysates, which present an entire spectrum of the patient's personal epitopes without complicated ex vivo processes, such as extraction, purification, and sequencing, it may promote the development of personalized nanovaccines for antitumor immunity.
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