Qianyu Zhang

Tumor microenvironment sensitive doxorubicin delivery and release to glioma using angiopep-2 decorated gold nanoparticles

Glioma is still hard to be treated due to their complex microenvironment. In this study, a gold nanoparticle-based delivery system was developed. The system, An-PEG-DOX-AuNPs, was loaded with doxorubicin (DOX) through hydrazone, an acid-responsive linker, and was functionalized with angiopep-2, a specific ligand of low density lipoprotein receptor-related protein-1 (LRP1), which could mediate the system to penetrate blood brain barrier and target to glioma cells. The particle size of An-PEG-DOX-AuNPs was 39.9 nm with a zeta potential of -19.3 mV, while the DOX loading capacity was 9.7%. In vitro, the release of DOX from DOX-AuNPs was pH-dependent. At lower pH values, especially 5.0 and 6.0, release of DOX was much quicker than that at pH 6.8 and 7.4. After coating with PEG, the acid-responsive release of DOX from PEG-DOX-AuNPs was almost the same as that from DOX-AuNPs. Cellular uptake study showed obviously higher intensity of intracellular An-PEG-DOX-AuNPs compared with PEG-DOX-AuNPs. In vivo, An-PEG-DOX-AuNPs could distribute into glioma at a higher intensity than that of PEG-DOX-AuNPs and free DOX. Correspondingly, glioma-bearing mice treated with An-PEG-DOX-AuNPs displayed the longest median survival time, which was 2.89-fold longer than that of saline. In conclusion, An-PEG-DOX-AuNPs could specifically deliver and release DOX in glioma and significantly expand the median survival time of glioma-bearing mice.

Comparison of four different peptides to enhance accumulation of liposomes into the brain

The cell penetrating peptide TAT, which appears to enter cells with alacrity, can pass through the BBB efficiently. It has been indentified to enhance the brain delivery of the liposome. However, little was known about its mechanism. TAT contains a basic region consisting of six arginine and two lysine residues. These eight basic amino acids seem to be the key to its highly efficient membrane translocation and brain delivery. In this study, four selected peptides are synthesized. (1) TAT peptide with terminal Cysteine (Cys-AYGRKKRRQRRR). (2) TAT peptide with disordered sequence (Cys-RKARYRGRKRQR). (3) Glycine and glutamic acid substituted TAT peptide (Cys-AYGGQQGGQGGG). (4) R8 (Cys-RRRRRRRR). Liposomes were chosen as the delivery vehicle. The peptide was covalently bonded with the liposome. We compare four peptides for their brain targeting potential, and investigate their ability to target liposomes to the brain in vitro and in vivo. The cellular uptake of these four liposomes by brain capillary endothelial cells (BCECs) of rats and C6s and the mechanism of the pathway of endocytosis were explored. Biodistribution in vivo was also investigated qualitatively and quantitatively. The results showed that the charge of the peptide played an important role in enhancing its brain delivery. The sequence had little to do with its membrane translocation and brain delivery indicated there might be no specific receptor or transporter for the Tat peptide.

A pH-responsive α-helical cell penetrating peptide-mediated liposomal delivery system

Tumor-oriented nanocarrier drug delivery approaches with pH-sensitivity have been drawing considerable attentions over the years. Here we described a liposomal delivery system modified with pH-responsive cell penetrating peptide TH (TH-Lip). Conventional cell penetrating peptide (CPP)-related drug delivery tactics sometimes seemed limited due to the extensive in vivo penetration and the lack of proper selectivity of conventional CPPs. In this study, TH (AGYLLGHINLHHLAHL(Aib)HHIL-NH₂), an engineered α-helical cell penetrating peptide originated from peptide TK (AGYLLGKINLKKLAKL(Aib)LLIL-NH₂), was endowed pH-responsiveness after complete replacement of all lysines in the sequence of TK into histidines, and was introduced onto the surface of liposomes. Accordingly, TH-Lip could benefit from the unique property of TH, as the cell penetrating capacity of TH was concealed during the blood circulation and in normal tissues because of the neutral pH under those conditions. However, when TH-Lip reached the tumor, and as pH declined, histidines in TH peptide protonated and the surface charge of TH-Lip converted from negative to positive, initiating activated cell penetrating capacity and leading to enhanced cellular and tumor spheroid uptake. The endocytosis inhibition assay demonstrated that the endocytosis of TH-Lip was influenced by the positively charged surface of the liposomes in acidic environment and was mediated by clathrin, and the intracellular trafficking study suggested that the liposomes were mainly accumulated in endoplasmic reticulum and Golgi apparatus. After systemic administration in mice, TH-Lip could be internalized into tumor cells efficaciously. When it comes to the delivery of paclitaxel (PTX), the pH-responsiveness of TH-Lip led to strong inhibition against tumor cell growth which occurred both in vitro (under pH 6.3) and in vivo, and the tumor inhibition rate reached 86.3% on C26 tumor-bearing mice for PTX-loaded TH-Lip. Therefore, TH-Lip proved itself to be a promising pH-responsive strategy for drug delivery within acidified tumor microenvironment.

Liposome formulated with TAT-modified cholesterol for improving brain delivery and therapeutic efficacy on brain glioma in animals

The treatment of central nervous system diseases such as brain glioma is a major challenge due to the presence of the blood-brain barrier (BBB). A cell-penetrating peptide TAT (AYGRKKRRQRRR), which appears to enter cells with alacrity, was employed to enhance the delivery efficiency of normal drug formulation to the brain. Targeting liposomal formulations often apply modified phospholipids as anchors. However, cholesterol, another liposomal component more stable and cheaper, has not been fully investigated as an alternative anchor. In our study, TAT was covalently conjugated with cholesterol for preparing doxorubicin-loaded liposome for brain glioma therapy. Cellular uptake by brain capillary endothelial cells (BCECs) and C6 glioma cells was explored. The anti-proliferative activity against C6s confirmed strong inhibitory effect of the liposomes modified with doxorubicin-loaded TAT. The bio-distribution findings in brains and hearts were evident of higher efficiency of brain delivery and lower cardiotoxic risk. The results on survival of the brain glioma-bearing animals indicate that survival time of the glioma-bearing rats treated with TAT-modified liposome was much longer than in the other groups. In conclusion, the potency of the TAT-modified liposome to enter the BBB appears to be related with the TAT on the liposomes surface. The TAT-modified liposome may improve the therapeutic efficacy on brain glioma in vitro and in vivo.

Liposome formulated with TAT-modified cholesterol for enhancing the brain delivery.

Delivery of drugs to the brain is a major challenge due to the presence of the blood-brain barrier (BBB). The cell penetrating peptide TAT, which appears to enter cells with alacrity, can pass through the BBB efficiently. With this in mind, a novel TAT-modified liposome (TAT-LIP) was developed for overcoming the ineffective delivery of normal drug formulation to the brain. Targeting liposomal formulations are always composed of modified phospholipids as an anchor. However, cholesterol, another liposomal component, which was more stable and cheaper, has not been fully investigated as an alternative anchor. In this study, TAT was covalently conjugated with the cholesterol to prepare the liposome. The cellular uptake by brain capillary endothelial cells (BCECs) of rats and the mechanism of TAT-LIP pathway of endocytosis was explored. The blood brain barrier model in vitro was established to evaluate the transendothelial ability crossing the BBB and its transport mechanism. The biodistribution of each formulation was further identified. The results showed that the positive charge of the TAT-LIP played an important role in enhancing its brain delivery. The absorptive endocytosis might be one of the mechanisms of TAT-LIP crossing the BBB. In conclusion, the experimental data in vitro and in vivo indicated that the TAT-LIP was a promising brain drug delivery system due to its high delivery efficiency across the BBB.

Cell-penetrating peptide-based intelligent liposomal systems for enhanced drug delivery.

Liposomes are widely used as drug delivery systems and several liposome-based nanomedicines have been approved for clinical use. Cell penetrating peptides (CPPs) have been decorated onto nanoparticulated vesicle such as liposomes to further improve the intracellular delivery efficiency. However, the poor selectivity of CPPs hindered their application, especially in the in vivo application. To resolve this issue, several strategies have been developed, including shielding and environment-triggered deshielding of CPPs as well as designing of environment-responsive CPPs and specific- targeting CPPs and last but not least, combination strategy. In this review, the abovementioned strategies were discussed.

Lactoferrin modified doxorubicin-loaded procationic liposomes for the treatment of gliomas

In this study, a brain-targeted chemotherapeutical delivery system, doxorubicin-loaded lactoferrin-modified procationic liposome (DOX-Lf-PCL) was developed, and its therapeutic effect for glioma was evaluated. The uptake profile of various DOX formulations in vitro by primary brain capillary endothelial cells (BCECs) and glioma cell C6 were studied by laser scanning confocal microscope and flow cytometry. An intracranial tumor model of rats was employed to evaluate the therapeutic effect of DOX-Lf-PCLs for glioma. Five groups of glioma-bearing rats (total n=50) were subjected to three cycles of 2.5mg/kg body weight of doxorubicin in different formulations or normal saline (N.S.) and analyzed for survival (median survival time, Kaplan-Meier). The results indicated that compared with the DOX solution or DOX-loaded conventional liposomes (DOX-Lips), DOX-PCLs and DOX-Lf-PCLs showed an improved performance in the uptake efficiency in BCECs and C6 cells. The DOX-Lf-PCLs can inhibit the growth of C6 more efficiently in vitro than other DOX formulations. The endocytosis involved in the DOX-Lf-PCLs uptake of C6 was mediated by both receptor- and absorption-mediated transcytosis. DOX-Lf-PCLs could significantly extend the survival time compared with the N.S. control and other DOX formulations. This study showed that the therapy with DOX-Lf-PCLs offers an effective therapeutic potential for gliomas.

Increased tumor targeted delivery using a multistage liposome system functionalized with RGD, TAT and cleavable PEG

Though PEGylation has been widely used to enhance the accumulation of liposomes in tumor tissues through enhanced permeability and retention (EPR) effects, it still inhibits cellular uptake and affects intracellular trafficking of carriers. Active targeting molecules displayed better cell selectivity but were shadowed by the poor tumor penetration effect. Cell penetrating peptides could increase the uptake of the carriers but were limited by their non-specificity. Dual-ligand system may possess a synergistic effect and create a more ideal drug delivery effect. Based on the above factors, we designed a multistage liposome system co-modified with RGD, TAT and cleavable PEG, which combined the advantages of PEG, specific ligand and penetrating peptide. The cleavable PEG could increase the stability and circulation time of liposomes during circulation. After the passive extravasation to tumor tissues, the previously hidden dual ligands on the liposomes were exposed in a controlled manner at the tumor site through exogenous administration of a safe reducing agent L-cysteine. The RGD specifically recognized the integrins overexpressed on various malignant tumors and mediated efficient internalization in the synergistic effect of the RGD and TAT. Invitro cellular uptake and 3D tumor spheroids penetration studies demonstrated that the system could not only be selectively and efficiently taken up by cells overexpress ingintegrins but also penetrate the tumor cells to reach the depths of the avascular tumor spheroids. In vivo imaging and fluorescent images of tumor section further demonstrated that this system achieved profoundly improved distribution within tumor tissues, and the RGD and TAT ligands on C-R/T liposomes produced a strong synergistic effect that promoted the uptake of liposomes into cells after the systemic administration of L-cysteine. The results of this study demonstrated a tremendous potential of this multistage liposomes for efficient delivery to tumor tissue and selective internalization into tumor cells.

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.

Simultaneous delivery of therapeutic antagomirs with paclitaxel for the management of metastatic tumors by a pH-responsive anti-microbial peptide-mediated liposomal delivery system.

The roles of microRNAs (miRNAs) in the regulation of metastasis have been widely recognized in the recent years. Mir-10b antagomir (antagomir-10b) was shown to impede metastasis through the down-regulation of mir-10b; however, it could not stunt the growth of primary tumors. In this study we showed that the co-delivery of antagomir-10b with paclitaxel (PTX) by a novel liposomal delivery system modified with an anti-microbial peptide [D]-H6L9 (D-Lip) could significantly both hinder the migration of 4T1 cells and induce evident cellular apoptosis and cell death in the meantime. The histidines in the sequence of [D]-H6L9 allowed the peptide to get protonated under pH5.0 (mimicking the lysosome/endosome environment), and strong membrane lytic effect could thus be activated, leading to the escape of liposomes from the lysosomes and the decrease of of mir-10b expression. The in vivo and ex vivo fluorescence imaging showed that D-Lip could reach 4T1 tumors efficaciously. Incorporation of PTX did not influence the antagomir-10b delivery effect of D-Lip; for the in vivo tumor inhibition assay, compared with all the other groups, the combination of antagomir-10b and PTX delivered by D-Lip could prominently delay the growth of 4T1 tumors and reduce the lung metastases at the same time, and the expression of Hoxd10 in tumors was also significantly up-regulated. Taken together, these results demonstrated that D-Lip could act as a sufficient tool in co-delivering antagomir-10b and PTX.