Yue Qiu

A pH-responsive cell-penetrating peptide-modified liposomes with active recognizing of integrin αvβ3 for the treatment of melanoma.

The use of pH-responsive cell-penetrating peptides (CPPs) is an attractive strategy for drug delivery in vivo, however, they still could not actively target to the desired sites. Here, we designed a pH-responsive CPP (TR) with the ability of active targeting to integrin αvβ3, which was a tandem peptide consisted of active targeting ligand peptide (c(RGDfK)) and pH-responsive CPP (TH). The targeting efficiency of TR with integrin was evaluated by molecular simulation and docking studies. The affinity assays of TR peptide modified liposomes (TR-Lip) at pH7.4 and pH6.5 demonstrated adequately the pH-responsive binding efficacy of TR-Lip with integrin αvβ3. The cellular uptake of CFPE-labeled TR-Lip on integrin αvβ3-overexpressing B16F10 cells was 41.67-, 30.67-, and 11.90-fold higher than that of CFPE-labeled PEG-, RGD-, and TH-modified liposomes at pH6.5, respectively, suggesting that TR-Lip could not only actively target to αvβ3-overexpressing cells compared to TH-Lip, but also significantly increased cellular uptake compared to RGD-Lip. At the concentration of 20μg/mL paclitaxel (PTX), the killing activity of PTX-loaded TR-Lip (PTX-TR-Lip) against B16F10 cells was 1.80-, 1.45-, 1.30-, 1.15-time higher than that of PTX-loaded PEG-, RGD-, TH-modified liposomes and free PTX at pH6.5, respectively. In vivo imaging displayed the maximum accumulation of DiD-labeled TR-Lip at tumor sites compared to the other groups. Tumor inhibition rate of B16F10 tumor-bearing mice treated with PTX-TR-Lip was 85.04%, relative to that of PBS. In B16F10 tumor-bearing mice, PTX-TR-Lip showed significantly higher survival rate compared with the other groups. Collectively, all the results in vitro and in vivo suggested that TR-Lip would be a potential delivery system for PTX to treat integrin αvβ3-overexpressing tumor-bearing mice.

High Tumor Penetration of Paclitaxel Loaded pH Sensitive Cleavable Liposomes by Depletion of Tumor Collagen I in Breast Cancer.

The network of collagen I in tumors could prevent the penetration of drugs loaded in nanoparticles, and this would lead to impaired antitumor efficacy. In this study, free losartan (an angiotensin inhibitor) was injected before treatment to reduce the level of collagen I, which could facilitate the penetration of nanoparticles. Then the pH-sensitive cleavable liposomes (Cl-Lip) were injected subsequently to exert the antitumor effect. The Cl-Lip was constituted by PEG(5K)-Hydrazone-PE and DSPE-PEG(2K)-R8. When the Cl-Lip reached to the tumor site by the enhanced permeability and retention (EPR) effect, PEG(5K)-Hydrazone-PE was hydrolyzed from the Cl-Lip under the low extra-cellular pH conditions of tumors, then the R8 peptide was exposed, and finally liposomes could be internalized into tumor cells by the mediation of R8 peptide. In vitro experiments showed both the cellular uptake of Cl-Lip by 4T1 cells and cytotoxicity of paclitaxel loaded Cl-Lip (PTX-Cl-Lip) were pH sensitive. In vivo experiments showed the Cl-Lip had a good tumor targeting ability. After depletion of collagen I, Cl-Lip could penetrate into the deep place of tumors, the tumor accumulation of Cl-Lip was further increased by 22.0%, and the oxygen distributed in tumor tissues was also enhanced. The antitumor study indicated free losartan in combination with PTX-Cl-Lip (59.8%) was more effective than injection with PTX-Cl-Lip only (37.8%) in 4T1 tumor bearing mice. All results suggested that depletion of collagen I by losartan dramatically increased the penetration of PTX-Cl-Lip and combination of free losartan and PTX-CL-Lip could lead to better antitumor efficacy of chemical drugs. Thus, the combination strategy might be a promising tactic for better treatment of solid tumors with a high level of collagen I.

Multifunctional Tandem Peptide Modified Paclitaxel-Loaded Liposomes for the Treatment of Vasculogenic Mimicry and Cancer Stem Cells in Malignant Glioma

The chemotherapy of aggressive glioma is usually accompanied by a poor prognosis because of the formation of vasculogenic mimicry (VM) and brain cancer stem cells (BCSCs). VM provided a transporting pathway for nutrients and blood to the extravascular regions of the tumor, and BCSCs were always related to drug resistance and the relapse of glioma. Thus, it is important to evaluate the inhibition effect of antiglioma drug delivery systems on both VM and BCSCs. In this study, paclitaxel-loaded liposomes modified with a multifunctional tandem peptide R8-c(RGD) (R8-c(RGD)-Lip) were used for the treatment of glioma. An in vitro cellular uptake study proved the strongest targeting ability to be that of R8-c(RGD)-Lip to glioma stem cells. Drug loaded R8-c(RGD)-Lip exhibited an efficient antiproliferation effect on BCSCs and could induce the destruction of VM channels in vitro. The following pharmacodynamics study demonstrated that R8-c(RGD)-modified drug-loaded liposomes achieved both anti-VM and anti-BCSC effects in vivo. Finally, no significant cytotoxicity of the blood system or major organs of the drug-loaded liposomes was observed under treatment dosage in the safety evaluation. In conclusion, all of the results proved that R8-c(RGD)-Lip was a safe and efficient antiglioma drug delivery system.

Targeted delivery of transferrin and TAT co-modified liposomes encapsulating both paclitaxel and doxorubicin for melanoma

Abstract The purpose of this study was to develop an efficient dual-ligand based liposomal drug delivery system with targeting specificity as well as properties that would kill melanoma cells. Liposomes modified with transferrin (Tf) and cell-penetrating peptide TAT was prepared, which encapsulated two kinds of chemotherapy drugs, paclitaxel and doxorubicin (Tf/TAT-PTX/DOX-LP). The Tf ligands specifically bind to the overexpressed Tf receptors on the surface of melanoma cells, while the TAT ligands functioned as a classical cell penetrating peptide, helping dual-ligand liposomes be internalized by melanoma cells. The effect of dual-targeting system and “double-drug” combination therapy were evaluated both in vitro and in vivo. In vitro, cellular uptake, intracellular distribution and tumor spheroids penetration studies demonstrated that the system could not only be selectively and efficiently penetrate melanoma cells. Besides, apoptosis staining assay and cytotoxicity showed effective anti-tumor capability and obvious synergistic effect of combination therapy of PTX and DOX. In vivo imaging and fluorescent images of tumor section further demonstrated that Tf/TAT-PTX/DOX-LP had the highest tumor distribution. The results of these experiments demonstrated that double-drug liposomal drug delivery systems (DDS) had both enhanced targeting efficiency and increased therapeutic efficacy.

Liposomes Combined an Integrin αvβ3-Specific Vector with pH-Responsible Cell-Penetrating Property for Highly Effective Antiglioma Therapy through the Blood–Brain Barrier

Glioma, one of the most common aggressive malignancies, has the highest mortality in the present world. Delivery of nanocarriers from the systemic circulation to the glioma sites would encounter multiple physiological and biological barriers, such as blood-brain barrier (BBB) and the poor penetration of nanocarriers into the tumor. To circumvent these hurdles, the paclitaxel-loaded liposomes were developed by conjugating with a TR peptide (PTX-TR-Lip), integrin αvβ3-specific vector with pH-responsible cell-penetrating property, for transporting drug across the BBB and then delivering into glioma. Surface plasmon resonance (SPR) studies confirmed the very high affinity of TR-Lip and integrin αvβ3. In vitro results showed that TR-Lip exhibited strong transport ability across BBB, killed glioma cells and brain cancer stem cells (CSCs), and destroyed the vasculogenic mimicry (VM) channels. In vivo results demonstrated that TR-Lip could better target glioma, and eliminated brain CSCs and the VM channels in tumor tissues. The median survival time of tumor-bearing mice after administering PTX-TR-Lip (45 days) was significantly longer than that after giving free PTX (25.5 days, p < 0.001) or other controls. In conclusion, PTX-TR-Lip would improve the therapeutic efficacy of brain glioma in vitro and in vivo.

A New Concept of Enhancing Immuno-Chemotherapeutic Effects Against B16F10 Tumor via Systemic Administration by Taking Advantages of the Limitation of EPR Effect.

The enhanced permeability and retention (EPR) effect has been comfortably accepted, and extensively assumed as a keystone in the research on tumor-targeted drug delivery system. Due to the unsatisfied tumor-targeting efficiency of EPR effect being one conspicuous drawback, nanocarriers that merely relying on EPR effect are difficult to access the tumor tissue and consequently trigger efficient tumor therapy in clinic. In the present contribution, we break up the shackles of EPR effect on nanocarriers thanks to their universal distribution characteristic. We successfully design a paclitaxel (PTX) and alpha-galactosylceramide (αGC) co-loaded TH peptide (AGYLLGHINLHHLAHL(Aib)HHIL-Cys) -modified liposome (PTX/αGC-TH-Lip) and introduce a new concept of immuno-chemotherapy combination via accumulation of these liposomes at both spleen and tumor sites naturally and simultaneously. The PTX-initiated cytotoxicity attacks tumor cells at tumor sites, meanwhile, the αGC-triggered antitumor immune response emerges at spleen tissue. Different to the case that liposomes are loaded with sole drug, in this concept two therapeutic processes effectively reinforce each other, thereby elevating the tumor therapy efficiency significantly. The data demonstrates that the PTX/αGC-TH-Lip not only possess therapeutic effect against highly malignant B16F10 melanoma tumor, but also adjust the in vivo immune status and induce a more remarkable systemic antitumor immunity that could further suppress the growth of tumor at distant site. This work exhibits the capability of the PTX/αGC-TH-Lip in improving immune-chemotherapy against tumor after systemic administration.

Enhanced glioma therapy by synergistic inhibition of autophagy and tyrosine kinase activity

Autophagy is a lysosomal degradation pathway that acts as a cytoprotective mechanism causing treatment resistance in various cancer cells. Recent studies showed that hydroxychloroquine can inhibit the latter step of autophagy and therefore enhance the anti-glioma efficiency of ZD6474, a tyrosine kinase inhibitor. However, the nonselective distribution of ZD6474 in vivo and the low penetrating ability of hydroxychloroquine when crossing the blood-brain barrier restrict their clinical use in glioma therapy. Here we coencapsulated ZD6474 and hydroxychloroquine into R6dGR peptide-modified liposomes (R6dGR-Lip) which can specifically recognize both integrin αvβ3 and neuropilin-1 receptors that are highly expressed on the endothelial cells and glioma cells. R6dGR significantly enhanced the brain targeting and overcame the blood-brain barrier. Our results confirmed that loading hydroxychloroquine into R6dGR-Lip blocked autophagic flux more efficiently than free hydroxychloroquine in glioma cells and significantly sensitized glioma cells to ZD6474-induced cell death in vitro and in vivo. The coencapsulated R6dGR-modified liposomes (ZD6474/HCQ-R6dGR-Lip) prolonged the medium survival time of intracranial C6 glioma bearing mice by 1.2-fold compared with ZD6474-R6dGR-Lip, 1.5-fold compared with free ZD6474/HCQ, and 1.8-fold compared with free ZD6474, exhibiting a synergistic therapeutic effect. Therefore, ZD6474/HCQ-R6dGR-Lip is presented as a potential strategy which could be further used for efficient anti-glioma therapy.

Cell-penetrating peptides induce apoptosis and necrosis through specific mechanism and cause impairment of Na + –K + -ATPase and mitochondria

Cell-penetrating peptides (CPPs) are widely used in the development of various drug delivery systems because of their ability of penetrating plasma membrane. However, the safety of their application remains largely unknown. In this study, we found that the incubation of two main kinds of CPPs with human normal liver cells could cause the occurrence of apoptosis and necrosis, then the detailed apoptosis-related protein were detected out. To discover the specific way which leads to these results, several methods were used in this study. Several cytokines, such as Caspase3 and Bcl-2, were detected to prove that the damage happened after treated with different CPPs. Then shielding the positive charge of TAT and R8, depletion of Na+ in culturing medium and addition of several inhibitors of specific ATPase site were used to investigate whether the cytotoxicity were charge-dependent and ATPase-related. Furthermore, the membrane potential of mitochondria and the leakage of mitochondrial cytochrome c were detected after treated with CPPs to investigate the damage on mitochondria. In general, our results assess the cytotoxicity caused by two main kinds of CPPs and reveal the clear mechanism of how it occurs. This study reveals the essence of cytotoxicity caused by CPPs, and the methods we followed can be used to evaluate the biocompatibility of new-designed CPPs, which makes the application of CPPs better and safer.

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.

Efficient siRNA transfer to knockdown a placenta specific lncRNA using RGD-modified nano-liposome: A new preeclampsia-like mouse model

Graphical abstract Figure. No Caption available. &NA; Preeclampsia is one of the most serious pregnancy complications. Many animal models have already been developed by researchers to study the pathogenesis and treatment of preeclampsia. However, most of these animal models were established by systemic administration or by surgery in the uterine cavity, which could lead to unwanted systemic toxicity or operative wounds and affect the accuracy of the results. Because of the high expression level of integrin &agr;v&bgr;3 on the placenta, arginine‐glycine‐aspartic acid peptide (RGD) modified PEGylated cationic liposome (RGD‐Lip) was designed as a novel gene delivery system to target the placenta safely and efficiently, and a new animal model of preeclampsia was established through targeting of long noncoding RNA (lncRNA). The results of cellular uptake and endosomal localization showed that RGD‐Lip enhanced cellular uptake and endosomal escape of small interfering RNA (siRNA) on HTR‐8/SVneo. In vivo imaging revealed that RGD‐Lip was selectively delivered to the placenta. Additionally, H19x siRNA was efficiently transferred into the placenta of C57BL/6 mice via the injection of H19x siRNA‐loaded RGD‐Lip, which could result in the occurrence of preeclampsia‐like symptoms. In summary, RGD‐Lip provided a platform to efficiently deliver siRNA to the placenta, and a new preeclampsia‐like mouse model was developed targeting placenta enriched/specific genes, including noncoding RNAs.