BRCA1-mediated dual regulation of ferroptosis exposes a vulnerability to GPX4 and PARP co-inhibition in BRCA1-deficient cancers.

Resistance to poly (ADP-ribose) polymerase inhibitors (PARPi) limits the therapeutic efficacy of PARP inhibition in treating breast cancer susceptibility gene 1 (BRCA1)-deficient cancers. Here we reveal that BRCA1 has a dual role in regulating ferroptosis. BRCA1 promotes the transcription of voltage-dependent anion channel 3 (VDAC3) and glutathione peroxidase 4 (GPX4); consequently, BRCA1 deficiency promotes cellular resistance to erastin-induced ferroptosis but sensitizes cancer cells to ferroptosis induced by GPX4 inhibitors (GPX4i). In addition, nuclear receptor coactivator 4 (NCOA4)-mediated ferritinophagy and defective GPX4 induction unleash potent ferroptosis in BRCA1-deficient cancer cells upon PARPi and GPX4i co-treatment. Finally, we show that xenograft tumors derived from BRCA1-mutant breast cancer patients with PARPi resistance exhibit decreased GPX4 expression and high sensitivity to PARP and GPX4 co-inhibition. Our results show that BRCA1 deficiency induces a ferroptosis vulnerability to PARP and GPX4 co-inhibition and inform a therapeutic strategy for overcoming PARPi resistance in BRCA1-deficient cancers.

Sponge-like nano-system suppresses tumor recurrence and metastasis by restraining myeloid-derived suppressor cells-mediated immunosuppression and formation of pre-metastatic niche.

Tumor recurrence and metastasis still greatly limit the therapeutic efficiency on the majority of postoperative clinical cases. With the aim to realize more powerful treatment outcomes on postoperative malignant tumors, a sponge-like neutrophil membrane-coated nano-system (NM/PPcDG/D) was fabricated to inhibit tumor recurrence and metastasis by inhibiting the recruitment and functions of myeloid-derived suppressor cell (MDSCs), which reinforced anti-tumor immunity and also suppressed pulmonary metastasis by inhibiting the formation of pre-metastatic niche (PMN). Firstly, PPcDG/D nanoparticles (NPs) were formulated by the self-assembling and crosslinking of synthesized redox-responsive polymer (PPDG) with doxorubicin (DOX) loading in the nanocore (PPcDG/D), followed by coating with activated neutrophils membrane to fabricate biomimetic NM/PPcDG/D. The sponge-like NM/PPcDG/D not only showed obvious natural tropism to postoperative inflammatory site, but also inhibited the recruitment and functions of MDSCs, thus relieved MDSCs-mediated immunosuppression. Additionally, NM/PPcDG/D also suppressed the formation of PMN to inhibit pulmonary metastasis by reducing the recruitment of MDSCs, decreasing the permeability of pulmonary vessels and inhibiting the implantation of circulating tumor cell (CTCs). Eventually, this fabricated NM/PPcDG/D NPs significantly inhibited tumor recurrence and metastasis on postoperative triple negative breast cancer (TNBC) model, presenting a promising therapeutic strategy on postoperative malignant tumors. STATEMENT OF SIGNIFICANCE: Myeloid-derived suppressor cells (MDSCs) play important roles in accelerating tumor recurrence and metastasis by promoting the establishment of immunosuppression in postoperative inflammatory regions and facilitating the formation of pulmonary pre-metastasis niche (PMN). In order to achieve enhanced suppression of recurrence and metastasis, a sponge-like NM/PPcDG/D nano-system was designed and fabricated. This nano-system is also the first attempt to integrate the regulation effects of a nano-sponge and anti-inflammatory agent to achieve enhanced multi-mode manipulation of MDSCs. Ultimately, NM/PPcDG/D powerfully restrained the recurrence and spontaneous metastasis on TNBC model. This article also revealed the particular roles of MDSCs involved in the regulation networks of postoperative recurrence and metastasis, immunosuppression and inflammation.

Micellar nanoparticles inhibit breast cancer and pulmonary metastasis by modulating the recruitment and depletion of myeloid-derived suppressor cells.

Myeloid-derived suppressor cells (MDSCs) are notorious for their pathological characteristics of immunosuppression and their promoting effect on cancers. They can induce the formation of pre-metastatic niche (PMN) characterized by inflammation, immunosuppression and vascular leakage, and promote pulmonary metastasis of breast cancer. Herein, a tumor targeting c(RGDfk) peptide modified low molecular-weight-heparin-all-trans-retinoic-acid (LMWH-ATRA) micellar nanoparticle loaded with chemotherapeutic drug doxorubicin (DOX) and immune adjuvant α-galactosylceramide (αGC) (RLA/DOX/αGC NP) was developed. The hydrophilic segment LMWH inhibited the recruitment of MDSCs by competitively binding with P-selectin on the surface of vascular endothelial cells (VECs), while the hydrophobic segment ATRA promoted the depletion of MDSCs by inducing their differentiation. Through the modulation of MDSCs, micelles can significantly improve the inflammatory and immunosuppressive microenvironment of the lung and tumor sites, and inhibit the formation of PMN. Not only this, the micelles also produced a synergistic effect with αGC, which effectively improved the anti-tumor immunity of tumor bearing mice and provided a promising therapeutic strategy for breast cancer and pulmonary metastasis.

Micellar nanoparticles inhibit the postoperative inflammation, recurrence and pulmonary metastasis of 4T1 breast cancer by blocking NF-κB pathway and promoting MDSCs depletion.

The progression of breast cancer can stimulate the production of myeloid-derived suppressor cells (MDSCs). These cells with significant immunosuppressive activity play a key role in promoting the formation of pulmonary inflammatory and immunosuppressive microenvironment, namely pre-metastatic niche (PMN). Surgical resection of tumors often leads to strong inflammatory reactions, and the produced circulating tumor cells (CTCs) can implant into PMN to promote the recurrence and pulmonary metastasis of breast cancer. Therefore, we developed a hyaluronic acid (HA)-coated chitosan oligosaccharide-all-trans-retinoic-acid (COS-ATRA) micellar nanoparticle loaded with chemotherapeutic drug doxorubicin (DOX) (HA@CA/DOX NPs). The hydrophilic segment COS and hydrophobic segment ATRA both blocked NF-κB inflammatory signaling pathway in 4T1 tumor cells and MDSCs and alleviated the inflammation after resection. Besides, ATRA also significantly depleted MDSCs in lungs and tumors, thereby regulating the inflammatory and immunosuppressive microenvironment and inhibiting the formation of PMN. HA coated on the surface of nanoparticles shielded the excessive positive charge and achieved tumor targeting through CD44 on the surface of tumor cells. This drug delivery system combined with anti-inflammation and chemotherapy significantly inhibited the postoperative recurrence and pulmonary metastasis of breast cancer.

Simultaneous inhibition of breast cancer and its liver and lung metastasis by blocking inflammatory feed-forward loops.

Inflammatory feed-forward loops including the steps of "inflammatory cell recruitment", "inflammatory signaling pathway activation" and "inflammatory factor production" are essential in the development of breast cancer and its metastasis. Herein, a doxorubicin-loaded micellar low-molecular-weight-heparin-astaxanthin nanoparticle (LMWH-AST/DOX, LA/DOX NP) was developed. The hydrophilic LMWH could decrease the recruitment of neutrophils in liver and myeloid-derived suppressor cells (MDSCs) in lung and tumor through P-selectin blockage. The hydrophobic AST could inhibit nuclear factor-κB (NF-κB) and signal transducer and activator of transcription 3 (STAT3) signaling pathways. Therefore, LA/DOX NPs could block these loops and suppress the liver metastasis by inhibiting the formation of neutrophil extracellular traps (NETs), inhibit the lung metastasis and alleviate the inflammatory and immunosuppressive microenvironment in tumor. This is the first functional nanoparticle reported to shut down inflammatory feed-forward loops and the formation of NETs, which provides a promising therapeutic strategy for breast cancer and its liver and lung metastasis.

Redox-responsive nanoassembly restrained myeloid-derived suppressor cells recruitment through autophagy-involved lactate dehydrogenase A silencing for enhanced cancer immunochemotherapy.

Myeloid-derived suppressor cells (MDSCs) are the chief accomplices for assisting tumor's survival and suppressing anti-tumor immunity, which can be recruited by tumor-derived cytokines, such as granulocyte-colony stimulating factor (G-CSF) and granulocyte-macrophage colony stimulating factor (GM-CSF). The plentiful lactate dehydrogenase A (LDHA) in glycolysis is usually accompanied by abundant tumor-derived G-CSF and GM-CSF, further promoting MDSCs recruitment and immunosuppression. Herein, with the aim to achieve powerful anti-tumor immunity, an immunochemotherapy regimen basing on a redox-responsive nanoassembly (R-mPDV/PDV/DOX/siL) is developed, which integrates the combined strategy of restraining cytokines-mediated MDSCs recruitment through LDHA silencing and reinforcing tumor immunogenicity through anthracycline (DOX)-elicited immunogenic cell death (ICD) effects. This redox-responsive nanoassembly is self-assembled by three glutathione (GSH)-responsive polymers, which employ poly(δ-valerolactone) (PVL) as hydrophobic segment and 3, 3'-dithiodipropionic acid (DA) as linkage to connect hydrophilic segment. DOX is encapsulated in the core and LDHA siRNA (siL) is effectively compressed by cationic PAMAM. The cellular internalization and tumor-homing are strengthened by the specific recognition on integrin (αvß3) by c(RGDfk) (RGD) ligand. After escaping from endosomes/lysosomes, R-mPDV/PDV/DOX/siL is disintegrated through GSH-elicited cleavage of DA, realizing burst release of drugs and high-efficient LDHA silencing. The reduced expression of LDHA suppresses the generation of G-CSF and GM-CSF cytokines, restrains MDSCs recruitment and reinforces anti-tumor immunity. Eventually, this therapeutic regimen of DOX and siL on R-mPDV/PDV/DOX/siL nanoassembly achieved powerful anti-tumor efficiency on 4 T1 orthotopic tumor, opening the new horizons for immunochemotherapy.

Self-promoted Albumin-Based Nanoparticles for Combination Therapy against Metastatic Breast Cancer via a Hyperthermia-Induced "Platelet Bridge".

It has been a great challenge to simultaneously inhibit the outgrowth of both the primary tumor and metastasis in metastatic cancer treatment. Substantial studies have evidenced that the interaction of platelets and cancer cells supports tumor metastasis, and platelets are considered to have metastasis-targeting property. Inspired by injury-targeting and metastasis-targeting properties of platelets, we constructed a photothermal therapy strategy with activated platelet-targeting albumin-based nanoparticles, PSN-HSA-PTX-IR780, to amplify drug delivery in the primary tumor at mild temperatures and simultaneously inhibit metastasis via a "platelet bridge". Human serum albumin (HSA) was premodified with a P-selectin-targeting peptide (PSN peptide) or IR780 serving as a photosensitizer. Hybrid albumin nanoparticles were assembled via the disulfide reprogramming method and encapsulated paclitaxel (PTX) to formulate PSN-HSA-PTX-IR780. The PSN-modified albumin nanoparticles could bind with upregulated P-selectin on activated platelets and subsequently target cancer cells by using platelets as a "bridge". In addition, nanoparticle-generated hyperthermia induced tissue injury and increased tumor-infiltrating platelets, thereby recruiting more nanoparticles into the tumor in a self-promoted way. In vivo studies showed that the drug accumulation of PSN-HSA-PTX-IR780 was 2.86-fold higher than that of HSA-PTX-IR780 at the optimal temperature (45 °C), which consequently improved the therapeutic outcome. Moreover, PSN-HSA-PTX-IR780 also effectively targets and inhibits lung metastasis by binding with metastasis-infiltrating platelets. Altogether, the self-promoted nanoplatform provides a unique and promising strategy for metastatic cancer treatment with enhanced drug delivery efficacy.

Shield and sword nano-soldiers ameliorate rheumatoid arthritis by multi-stage manipulation of neutrophils.

Rheumatoid arthritis (RA) is characterized by the outbreak of inflammation. Neutrophils, the main culprit of the outbreak of inflammation, are the first inflammatory cells to be recruited to inflamed joints and facilitate the recruitment of themselves by stimulating the release of chemokines. Here, based on neutrophils, a novel anti-inflammatory "shield and sword soldiers" strategy is established with LMWH-TOS nanoparticles (LT NPs). The hydrophilic fragment low molecular weight heparin (LMWH) acts as a shield which block the transvascular movement of neutrophils through inhibiting the adhesion cascade by binding to P-selectin on inflamed endothelium. Synergistically, MMP-9, which is secreted by the recruited neutrophils and degrade the main component of articular cartilage, is reduced by the hydrophobic fragment d-α-tocopheryl succinate (TOS), functioning as a sword. In collagen-induced arthritis (CIA) mouse model, LT NPs show significant targeting effect, and exhibit prominent therapeutic efficacy after enveloping the first-line anti-RA drug methotrexate. Our work proves that the multi-stage manipulation of neutrophils is feasible and effective, providing a new concept for RA treatment.

Phenylboronic acid modified nanoparticles simultaneously target pancreatic cancer and its metastasis and alleviate immunosuppression.

Pancreatic ductal adenocarcinoma is one of the most lethal malignant tumors, its drug resistance, immunosuppression and metastasis makes the traditional chemotherapy and immunotherapy inefficient. Here we confirmed a 3-aminophenylboronic acid-modified low molecular weight heparin-D-α-tocopheryl succinate micellar nanoparticle (PBA-LMWH-TOS NP, PLT NP) could inhibit orthotopic pancreatic tumor and its spontaneous metastases. The small particle size and high affinity of PBA to sialic acid residue (SA) made PLT/PTX NPs significantly targeted and accumulated in both pancreatic tumor tissues and metastases. The immunosuppressive microenvironment of pancreatic tumor was most caused by the infiltration of immunosuppressive cells, mainly myeloid-derived suppressor cells (MDSCs). We first reported that P-selectin glycoprotein ligand-1 (PSGL-1) was expressed on the surfaces of MDSCs in pancreatic tumor tissues. Meanwhile, we found that LMWH could inhibit the early stage of adhesion cascade between vascular endothelial cells (VECs) and MDSCs by interfering with P-selectin/PSGL-1 binding, thus inhibiting MDSC recruitment to pancreatic tumor tissues. The therapeutic results indicated that PLT/PTX NPs could significantly improve the immune microenvironment of pancreatic tumor and inhibit spontaneous metastases. This nanosystem provides a new immune microenvironment regulation mechanism based on carrier materials in pancreatic tumor, and has high clinical application potential.

Rapid pH-responsive self-disintegrating nanoassemblies balance tumor accumulation and penetration for enhanced anti-breast cancer therapy.

The dilemma of tumor accumulation and deep penetration has always been a barrier in antitumor therapy. Stimuli-responsive size changeable drug delivery systems provide possible solutions. Nevertheless, the low size-shrinkage efficiency limited the antitumor effects. In this study, an instant pH-responsive size shrinkable nanoassemblies named self-aggregated DOX@HA-CD (SA-DOX@HA-CD) was formulated using small-sized hyaluronic acid modified carbon dots (HA-CD) as monomers, which could self-aggregate into raspberry-like structure via hydrophobicity force in neutral pH and rapidly disassemble into shotgun-like DOX-loaded CD monomer in simulated tumor microenvironment (pH 6.5), owing to the transformation in electrical charge and hydrophobicity/hydrophilicity of this system. The transmission electron microscopy showed that the clustered SA-DOX@HA-CD had a diameter of ~150 nm, and thoroughly disassembled into ~30 nm nanoparticles in response to acidic environment. The disassemble efficiency was approximately 100%. Attributed to this property, SA-DOX@HA-CD led to enhanced cellular internalization and accumulation in 4T1 cells in simulated tumor microenvironment, as well as deep tumor penetration in 3D tumor spheroid model. Besides, the imine bond between DOX and HA-CD endowed DOX with pH-responsive release profile in the acidic lysosome environment. Furthermore, in the orthotopic 4T1 tumor-bearing mouse model, SA-DOX@HA-CD demonstrated higher tumor accumulation than non-aggregated DOX-HA-CD. Meanwhile, in response to the acid tumor microenvironment, the dissociated DOX-HA achieved deep tumor penetration, which consequently resulted in 2.5-fold higher antitumor efficiency. The formulation of self-aggregated SA-DOX@HA-CD provides a simple and effective alternative to prepare pH-responsive size-shrinkable nanodrug delivery systems. STATEMENT OF SIGNIFICANCE: The heterogeneity of tumor vasculature and the high tumor interstitial pressure lead to the barriers in tumor accumulation and deep penetration, which calls for opposite properties (e.g. size) of drug delivery systems. To address this dilemma, various size changeable nanoparticles have been developed utilizing special features of tumor microenvironment, such as pH, enzyme and reactive oxygen species. Nevertheless, the current strategies face the problems of incomplete hydrolysis of chemical bonds or insufficient enzyme degradation, which result in only partial size shrinkage, hindering the tumor deep penetration effects. Here we developed a self-assembled nanocluster, which could respond to acidic pH rapidly and thoroughly disassemble into small nanodots due to the alteration of hydrophobicity/hydrophilicity/charge, leading to approximately 100% dissociation. This strategy provides a new concept for design of size changeable drug delivery systems.

Enhanced stability and efficacy of GEM-TOS prodrug by co-assembly with antimetastatic shell LMWH-TOS.

Chemotherapy agents have been widely used for cancer treatment, while the insolubility, instability and toxicity seriously restrict their efficacy. Thus, prodrug strategy was devised. Since some prodrugs are still with poor solubility or stability, a synergy strategy is needed to enhance their efficacy. Gemcitabine (GEM) is a prescribed anticancer drug, however, the rapid clearance, growing resistance and serious side effects limit its clinical efficacy. Conjugating GEM with d-α-tocopherol succinate (TOS) is an effective solution, while the GEM-TOS (GT) is unstable in aqueous solution. d-α-Tocopherol polyethylene glycol succinate (TPGS) has been used to enhance the stability, but GT stabilized by TPGS (GTT) has limited effect on tumor metastases. Tumor metastases lead to high mortality in patients suffering from cancers. In order to further achieve antimetastatic effect, an amphiphilic polymer (LT) was synthesized by connecting low-molecular-weight heparin (LMWH) with TOS, and eventually obtained desired self-delivery micellar NPs (GLT) by co-assembly GT with LT. The GLT not only possessed excellent stability, but also inhibited the metastases by acting on different phases of the metastatic cascade. The hydrophobic TOS inhibited the secretion of matrix metalloproteinase-9 (MMP-9), the hydrophilic LMWH inhibited the interaction between tumor cells and platelets. As a result, GLT reduced tumor cells entering the blood and implanting at the distant organs, leading to a much more excellent inhibitory effect on the lung metastasis than GEM and GTT.

On-Demand Autophagy Cascade Amplification Nanoparticles Precisely Enhanced Oxaliplatin-Induced Cancer Immunotherapy.

Chemoimmunotherapy-induced antitumor immune response is highly dependent on tumor autophagy. When tumor cells are treated with chemoimmunotherapy, timely overactivated autophagy can not only lead more tumor cells to death, but also participate in the endogenous antigen presentation and immune stimulators secretion of dying cells, thus plays a vital role. However, timely and accurately overactivated tumor autophagy during chemoimmunotherapy is of great difficulty. Here, an on-demand autophagy cascade amplification nanoparticle (ASN) is reported to boost oxaliplatin-induced cancer immunotherapy. ASN is prepared by self-assemble of autophagy-responsible C-TFG micelle and is followed by electrostatic binding of oxaliplatin prodrug (HA-OXA). After entering tumor cells, the HA-OXA shell of ASN first responds to the reduction microenvironment and releases oxaliplatin to trigger tumor immunogenic cell death and mildly stimulates tumor autophagy. Then, the exposed C-TFG micelle can sensitively respond to oxaliplatin-induced autophagy and release a powerful autophagy inducer STF-62247, which precisely transforms autophagy to "overactivated" condition, leading tumor cells to autophagic death and enhance subsequent tumor antigen processing of the dying cells. In CT26 tumor-bearing mice, ASN exhibits optimal immune stimulation and antitumor efficiency due to its on-demand autophagy induction ability.

Autophagy inhibition changes the disposition of non-viral gene carriers during blood-brain barrier penetration and enhances TRAIL-induced apoptosis in brain metastatic tumor.

Non-viral gene delivery systems have proven to be a promising approach in the treatment of brain metastatic cancers but facing delivery difficulties. Due to the existence of blood-brain barrier, non-viral gene carriers must pass through brain capillary endothelial cells to accumulate at the brain tumor sites. However, during this process, most of them trap into brain capillary endothelial cells and fail to penetrate to the brain tumor sites. Autophagy is involved in dynamic disposition of both intracellular and extracellular components, which theoretically affects intracellular fate of non-viral gene carriers during BBB penetration. In the present study, R6dGR peptide-modified PEGylated polyethyleneimine that carry therapeutic gene encoding human tumor necrosis factor-related apoptosis-inducing ligand (PPR/pTRAIL) are established as model non-viral gene delivery system and applied in breast cancer brain metastasis therapy. Autophagy-mediated lysosome degradation pathway is found to be involved in the degradation of PPR/pTRAIL in brain capillary endothelial cells and prevents them from BBB penetration. Pre-inhibiting BBB autophagy level by wortmannin loaded liposomes (Wtmn-Lip) can increase brain accumulation of non-viral gene carrier PPR without damaging BBB tight junctions. Besides, Wtmn-Lip synergistically induces apoptosis with TRAIL via different signaling pathways. Herein, pre-treatment of Wtmn-Lip might solve delivery difficulties of non-viral gene carriers in the treatment of brain metastatic cancers.

Self-Delivery Micellar Nanoparticles Prevent Premetastatic Niche Formation by Interfering with the Early Recruitment and Vascular Destruction of Granulocytic Myeloid-Derived Suppressor Cells.

Distal metastases of tumors result from the interaction between "seeds" (circulating tumor cells, CTCs) and "soil" (premetastatic niche, PMN). Various strategies focus on CTC inhibition, but only a few strategies inhibit PMN formation. The main predisposition of PMN formation in melanoma lies in the pulmonary recruitment of granulocytic myeloid-derived suppressor cells (G-MDSCs, CD11b+Ly6G+ cells) induced by tumors, which increase vascular permeability by secreting matrix metalloproteinase-9 (MMP-9) and result in immunosuppression by secreting interleukin-10 (IL-10) in premetastatic lungs. Here, a micellar hypotoxic low molecular weight heparin-tocopherol succinate nanoparticle (LMWH-TOS nanoparticle, LT NP) was established and investigated for its influence on PMN formation in this study. We first demonstrated that the hydrophilic segment LMWH in LT NPs can inhibit early pulmonary recruitment of G-MDSCs through interrupting their extravasation by inhibiting P-selectin/PSGL-1-mediated adhesion between vascular endothelial cells and G-MDSCs. In addition, the hydrophobic segment (TOS) in LT NPs significantly inhibited the expression of MMP-9 in G-MDSCs. As a result, the drug-free nanoparticles could maintain the normal microenvironment of lungs, thus effectively inhibiting implantation and colonization of CTCs. Further, phenylboronic acid (PBA)-modified and doxorubicin/immunopotentiator α-galactosylceramide (αGC)-coloaded nanoparticles (PLT/DOX/αGC NPs) were exploited. PBA modification achieved targeted chemotherapy by binding to overexpressed sialic acid residues on the tumor cell surface. This nanosystem effectively inhibited the postoperative metastasis and tumor recurrence simultaneously. Our work provides a proof of concept that the prevention of PMN formation through interfering G-MDSCs with self-delivery nanosystems is a safe and effective antimetastasis strategy.

Enhanced Melanoma-Targeted Therapy by "Fru-Blocked" Phenyboronic Acid-Modified Multiphase Antimetastatic Micellar Nanoparticles.

Metastasis remains the main driver of mortality in patients suffering from cancer because of the refractoriness resulting from the multi-phase metastatic cascade. Herein, a multifunctional self-delivering PBA-LMWH-TOS nanoparticle (PLT NP) is established that acts as both nanocarrier and anti-metastatic agent with effects on most hematogenous metastases of cancers. The hydrophilic segment (low molecular weight heparin, LMWH) inhibits the interactions between tumor cells and platelets. The hydrophobic segment (d-α-tocopheryl succinate, TOS) could inhibit the expression of matrix metalloproteinase-9 (MMP-9) in B16F10 cells which is first reported in this article. Surprisingly, even the blank NPs showed excellent anti-metastatic capacity in three mouse models by acting on different phases of the metastatic cascade. Moreover, the overexpression of sialic acid (SA) residues on tumor cells is implicated in the malignant and metastatic phenotypes of cancers. Thus, these 3-aminophenylboronic acid (PBA)-modified doxorubicin (DOX)-loaded NPs offer an efficient approach for the treatment of both solid melanomas and metastases. Furthermore, a simple pH-sensitive "Fructose (Fru)-blocking" coping strategy is established to reduce the NP distribution in normal tissues and distinctly increases the accumulation in melanoma tumors. These micellar NPs consisting of biocompatible materials offer a promising approach for the clinical therapy of highly invasive solid tumors and metastases.

Enhanced chemo-immunotherapy against melanoma by inhibition of cholesterol esterification in CD8+ T cells.

Cholesterol facilitated the formation of T cell receptor on cytotoxic CD8+ T lymphocytes (CTLs). However, the activation of CD8+ T cells always resulted in the upregulation of acetyl-CoA acetyltransferase-1 (ACAT-1) and enhanced the esterification of cholesterol. To relieve the suppression on CD8+ T cells, an ACAT-1 inhibitor avasimibe was combined with chemo-immunotherapy. Paclitaxel and immunoadjuvant αGC were co-encapsulated in liposomes modified with pH sensitive TH peptide (PTX/αGC-TH-Lip). After intravenous injections, the combination of avasimibe significantly elevated the free cholesterol level and relieved the inhibition of CD8+ T cells caused by PTX/αGC-TH-Lip, leading to enhanced CTL responses and anti-tumor effects of PTX/αGC-TH-Lip in B16F10 melanoma xenograft and lung metastasis models. The adoptive immunotherapy further confirmed the enhanced anti-tumor immune responses of the combined strategy. The combination of avasimibe and PTX/αGC-TH-Lip was proven as a feasible approach to enhance the antitumor effects of chemo-immunotherapy by relieving the inhibition of CD8+ T cells.

A size-shrinkable nanoparticle-based combined anti-tumor and anti-inflammatory strategy for enhanced cancer therapy.

Cancer-related inflammation can promote tumorigenesis, tumor growth and tumor metastasis in many types of cancers. Therefore, inhibiting cancer-related inflammation significantly improves cancer therapy. It has been reported that metformin (MET) inhibits the nuclear translocation of nuclear factor-κB (NF-κB), a key factor in cancer-related inflammation. However, the short half-life and the lack of tumor targeting limit the anti-inflammatory efficacy of MET in vivo. Herein, using pH-sensitive imine bonds, MET and the chemotherapy drug doxorubicin (DOX) were loaded onto size-shrinkable RGD-DGL-GNP nanoparticles (RDG NPs) for combination therapy. The RGD-MET-DGL-GNP nanoparticles (RMDG NPs) penetrated deep into the tumor to deliver MET and inhibit the NF-κB activity in tumor cells, which further decreased tumor necrosis factor-α (TNF-α) and interleukin-6 (IL-6) expressions in tumor tissues and suppressed tumor cell proliferation. As a result, the co-administration of RGD-DOX-DGL-GNP (RDDG NPs) and RMDG NPs induced an improved therapeutic effect in a xenograft tumor model and a lipopolysaccharide (LPS)-induced pulmonary metastasis model with murine 4T1 breast cancer and CT26 colon cancer cells. Combining RDDG and RMDG NPs to simultaneously target tumors and cancer-related inflammation is a very effective anti-cancer strategy.

A size switchable nanoplatform for targeting the tumor microenvironment and deep tumor penetration.

The complex tumor microenvironment (TME) in solid tumors forms physiological barriers to the efficient delivery of nanomedicine, leading to limited therapeutic efficacy. Herein, to overcome these physiological barriers and improve the therapeutic effect, we constructed a novel size-adjustable nanoplatform for efficient drug delivery into solid tumors. The smart size-switchable nanoplatform (DGL/DOX@PP) was prepared by conjugating small dendrigraft poly-l-lysine (DGL) to poly(ethylene glycol)-poly(caprolactone) micelles via a matrix metalloproteinase 2 (MMP-2)-sensitive peptide. DGL/DOX@PP had an initial size of 100 nm and a nearly neutral charge, rendering the system able to take advantage of the enhanced permeability and retention effect. After extravasation from the tumor vessels, small DGL/DOX nanoparticles (∼30 nm) were rapidly released from DGL/DOX@PP in response to MMP-2 in the TME. This process of particle size alteration greatly enhanced the nanoparticle penetration into both multicellular spheroids (MCSs) and solid tumors. In vivo results demonstrated that compared with small and non-switchable nanoparticles, particles from the size-switchable nanoplatform achieved excellent antitumor efficacy in 4T1 tumor-bearing mice. This size-adjustable nanoplatform provides a multifunctional strategy for TME modulation and tumor penetration.

Dual Receptor Targeting Cell Penetrating Peptide Modified Liposome for Glioma and Breast Cancer Postoperative Recurrence Therapy.

PURPOSE: Cell penetrating peptides (CPPs) were widely used as motifs for drug delivery to tumor. In former study, an RGD reverse sequence dGR was used to develop active-targeting liposome R8dGR-Lip, which showed well penetrating ability and treatment efficiency on glioma model. However, recurrence after tumor resection caused by post-operative residual cancer cells was a huge obstacle in tumor treatment. In consideration of the effective anti-cancer effect of PTX-R8dGR-Lip when treating glioma in former study, we decide to evaluate its pharmacodynamics on tumor resection models, which were more invasive and resistant. METHOD: In vitro, the effectiveness of PTX-R8dGR-Lip in reducing tumor initiating cell (TIC) was investigated using mammosphere formation. In vivo, the inhibition efficiency of PTX-R8dGR-Lip on C6 glioma recurrence and 4 T1 breast cancer recurrence model were evaluated, including tumor bioluminescence imaging, survival rate and immumohistochemical staining, etc.. RESULTS: C6 mammosphere formation rate of PTX-R8dGR-Lip group was 48.06 ± 2.72%, and 4 T1 mammosphere formation rate of PTX-R8dGR-Lip group was 39.51 ± 4.02% when PBS group was set as 100%. C6 and 4 T1 bioluminescent tumor resected model were established, then effectiveness of different PTX-loaded preparations were evaluated on these two models. PTX-R8dGR-Lip could obviously inhibit tumor recurrence, prolong survival rate and reduce tumor tissue invasion. CONCLUSION: PTX-R8dGR-Lip could reduce post-operative recurrence rate, prolong survival time, and decrease the proliferation of residual cancer cells through regulating the expression of recurrence-related cytokines.

Tandem Peptide Based on Structural Modification of Poly-Arginine for Enhancing Tumor Targeting Efficiency and Therapeutic Effect.

The nonselectivity of cell penetrating peptides had greatly limited the application in systemic administration. By conjugating a dGR motif to the C-terminal of octa-arginine, the formed tandem peptide R8-dGR had been proved to specifically recognize both integrin αvß3 and neuropilin-1 receptors. However, the positive charge of poly-arginine would still inevitably lead to rapid clearance in the circulation system. Therefore, in this study, we tried to reduce the positive charge of poly-arginine by decreasing the number of arginine, to thus achieve improved tumor targeting efficiency. We had designed several different Rx-dGR peptides (x = 4, 6, and 8) modified liposomes and investigated their tumor targeting and penetrating properties both in vitro and in vivo. Among all the liposomes, R6-dGR modified liposomes exhibited a long circulation time similar to that of PEGylated liposomes while they retained strong penetrating ability into both tumor cells and tumor tissues, and thus had displayed the most superior tumor targeting efficiency. Then, paclitaxel and indocyanine green coloaded liposomes were prepared, and R6-dGR modified coloaded liposomes also exhibited enhanced antitumor effect on C6 xenograft tumor bearing mice. Therefore, we suggest R6-dGR as a potential tumor targeting ligand with both strong penetrating ability and improved pharmacokinetic behavior, which could be further used for efficient antitumor therapy.