Affibody-displaying bionanocapsules for specific drug delivery to HER2-expressing cancer cells

A novel HER2-targeted carrier was developed using bionanocapsules (BNCs). Bionanocapsules (BNCs) are 100-nm hollow nanoparticles composed of the l-protein of hepatitis B virus surface antigen. An affibody of HER2 was genetically displayed on the BNC surface (Z_HER2-BNC). For the investigation of binding affinity, Z_HER2-BNC was incubated with the cancer cell lines SK-BR-3 (HER2 positive), and MDA-MB-231 (HER2 negative). For analysis of HER2 targeting specificity, Z_HER2-BNC or Z_WT-BNC (without affibody) was incubated with both SK-BR-3 and MDA-MB-231 cells by time lapse and concentration. For the delivery of encapsulated molecules (calcein), fluorescence of Z_HER2-BNC mixed with liposomes was also compared with that of Z_WT-BNC and nude liposomes by incubation with SK-BR-3 cells. As a result, Z_HER2-BNC-liposome complex demonstrated the delivery to HER2-expressing cells (SK-BR-3) with a high degree of specificity. This indicates that genetically engineered BNCs are promising carrier for cancer treatment.     

Evidence for targeted gene delivery to Hep G2 hepatoma cells in vitro

We have developed a system for targeting foreign DNA to hepatocytes in vitro using a soluble DNA carrier that takes advantage of receptor-mediated endocytosis to achieve internalization. The idea is based on the fact that hepatocytes possess a unique receptor that binds and internalizes galactose-terminal (asialo)glycoproteins. To create a targetable carrier system that could bind DNA in a nondeforming manner, we used poly(L-lysine) to bind DNA in a strong but noncovalent interaction. An asialoglycoprotein, asialoorosomucoid (AsOR), was chemically coupled to poly(L-lysine) to form an asialoorosomucoid-poly(L-lysine) conjugate. Various proportions of conjugate to DNA were tested to determine conditions that maximized DNA content in a soluble complex and that limited solubility of complexes. To test the targetable gene delivery system, AsOR-poly(L-lysine) conjugate was complexed to the plasmid pSV2 CAT containing the gene for chloramphenicol acetyltransferase (CAT) driven by an SV-40 promoter. We tested this complex using a model system consisting of human hepatoma cell line Hep G2 [asialoglycoprotein receptor (+)], hepatoma SK-Hep 1, IMR-90 fibroblasts, and uterine smooth muscle [receptor (-)] cells. Each cell line was incubated with 0.2 micron filtered AsOR-poly(L-lysine)-DNA complex or controls consisting of DNA plus AsOR, DNA plus poly(L-lysine), or DNA alone. Cells were assayed for the presence of CAT activity as a measure of gene transformation. SK-Hep 1, IMR-90, and smooth muscle [receptor (-)] cells produced no detectable acetylated chloramphenicol derivatives under any of these conditions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synthesis of galactosyl compounds for targeted gene delivery

Cell-specific DNA delivery offers a great potential for targeted gene therapy. Toward this end, we have synthesized a series of compounds carrying galactose residues as a targeting ligand for asialoglycoprotein receptors of hepatocytes and primary amine groups as a functional domain for DNA binding. Biological activity of these galactosyl compounds in DNA delivery was evaluated in HepG2 and BL-6 cells and compared with respect to the number of galactose residues as well as primary amine groups in each molecule. Transfection experiments using a firefly luciferase gene as a reporter revealed that compounds with multivalent binding properties were more active in DNA delivery. An optimal transfection activity in HepG2 cells requires seven primary amine groups and a minimum of two galactose residues in each molecule. The transfection activity of compounds carrying multi-galactose residues can be inhibited by asialofetuin, a natural substrate for asialoglycoprotein receptors of hepatocytes, suggesting that gene transfer by these galactosyl compounds is asialoglycoprotein receptor-mediated. These results provide direct evidence in support of our new strategy for the use of small and synthetic compounds for cell specific and targeted gene delivery.     

Synthesis of cholesterol-carborane conjugate for targeted drug delivery

The cholesterol-carborane conjugate has been designed and synthesized to selectively deliver boron to tumor cells by means of reconstituted low-density lipoprotein. The chemical stability and cytotoxicity of the new compound have been examined. Several methods have been evaluated for incorporation of the compound into LDL.     

Dendrimer-based targeted delivery of an apoptotic sensor in cancer cells

Our previous studies have demonstrated the applicability of poly(amidoamine) (PAMAM) dendrimers as a platform for the targeted delivery of chemotherapeutic drugs both in vitro and in vivo. To monitor the rate and extent of cell-killing caused by the delivered chemotherapeutic drug, we wished to analyze the degree of apoptosis in targeted cells on a real-time basis. As the apoptosis-regulating caspases are activated during the apoptotic process, several caspase-hydrolyzable, fluorescence resonance energy transfer (FRET)-based substrates have been marketed for the detection of apoptosis. However, the applicability of these agents is limited because of their nonspecificity and the consequent high background fluorescence in tissues. Here we show the synthesis, characterization, and in vitro targeting of an engineered PAMAM nanodevice in which folic acid (FA) is conjugated as the targeting molecule and a caspase-specific FRET-based agent (PhiPhiLux G1D2) is conjugated as the apoptosis-detecting agent. This conjugate specifically targets FA-receptor-positive, KB cells. In these cells, the apoptosis-inducing agent staurosporine caused a 5-fold increase in the cellular fluorescence. These results show, for the first time, the potential applicability of a targeted apoptosis-measuring nanodevice, which could be used for simultaneously monitoring the apoptotic potential of a delivered drug.     

Bio-encapsulation of microbial cells for targeted agricultural delivery

Biofertilizers, namely Rhizobium and biocontrol agents such as Pseudomonas and Trichoderma have been well established in the field of agricultural practices for many decades. Nevertheless, research is still going on in the field of inoculant production to find methods to improve advanced formulation and application in fields. Conventionally used solid and liquid formulations encompass several problems with respect to the low viability of microorganisms during storage and field application. There is also lack of knowledge regarding the best carrier in conventional formulations. Immobilization of microorganisms however improves their shelf-life and field efficacy. In this context, microencapsulation is an advanced technology which has the possibility to overcome the drawbacks of other formulations, results in extended shelf-life, and controlled microbial release from formulations enhancing their application efficacy. This review discusses different microencapsulation technologies including the production strategies and application thereof in agricultural practices.     

Bio-encapsulation of microbial cells for targeted agricultural delivery

Biofertilizers, namely Rhizobium and biocontrol agents such as Pseudomonas and Trichoderma have been well established in the field of agricultural practices for many decades. Nevertheless, research is still going on in the field of inoculant production to find methods to improve advanced formulation and application in fields. Conventionally used solid and liquid formulations encompass several problems with respect to the low viability of microorganisms during storage and field application. There is also lack of knowledge regarding the best carrier in conventional formulations. Immobilization of microorganisms however improves their shelf-life and field efficacy. In this context, microencapsulation is an advanced technology which has the possibility to overcome the drawbacks of other formulations, results in extended shelf-life, and controlled microbial release from formulations enhancing their application efficacy. This review discusses different microencapsulation technologies including the production strategies and application thereof in agricultural practices.     

Synthesis of folate-functionalized RAFT polymers for targeted siRNA delivery

Receptor-mediated, cell-specific delivery of siRNA enables silencing of target genes in specific tissues, opening the door to powerful therapeutic options for a multitude of diseases. However, the development of delivery systems capable of targeted and effective siRNA delivery typically requires multiple steps and the use of sophisticated, orthogonal chemistries. Previously, we developed diblock copolymers consisting of dimethaminoethyl methacrylate-b-dimethylaminoethyl methacrylate-co-butyl methacrylate-co-propylacrylic acid as potent siRNA delivery systems that protect siRNA from enzymatic degradation and enable its cytosolic delivery through pH-responsive, endosomolytic behavior. (1, 2) These architectures were polymerized using a living radical polymerization method, specifically reversible addition-fragmentation chain transfer (RAFT) polymerization, which employs a chain transfer agent (CTA) to modulate the rate of reaction, resulting in polymers with low polydispersity and telechelic chain ends reflecting the chemistry of the CTA. Here we describe the straightforward, facile synthesis of a folate receptor-targeted diblock copolymer siRNA delivery system because the folate receptor is an attractive target for tumor-selective therapies as a result of its overexpression in a number of cancers. Specifically, we detail the de novo synthesis of a folate-functionalized CTA, use the folate-CTA for controlled polymerizations of diblock copolymers, and demonstrate efficient, specific cellular folate receptor interaction and in vitro gene knockdown using the folate-functionalized polymer.     

LyP-1-fMWNTs enhanced targeted delivery of MBD1siRNA to pancreatic cancer cells

Functionalized multi-walled carbon nanotubes have been extensively gained popularity in pancreatic cancer gene therapy. LyP-1, a peptide, has been proved to specifically bind pancreatic cancer cells. The potential therapeutic effect of LyP-1–conjugated functionalized multi-walled carbon nanotubes in treating pancreatic cancer is still unknown. In this study, LyP-1–conjugated functionalized multi-walled carbon nanotubes were successfully synthesized, characterized and showed satisfactory size distribution and zeta potential. Compared with functionalized multi-walled carbon nanotubes, cellular uptake of LyP-1–functionalized multi-walled carbon nanotubes was shown to be increased. Compound of LyP-1–functionalized multi-walled carbon nanotubes and MBD1siRNA showed superior gene transfection efficiency. Moreover, LyP-1-fMWNTs/MBD1siRNA complex could significantly decrease the viability and proliferation and promoted apoptosis of pancreatic cancer cells in vitro. Further xenograft assays revealed that the tumour burden in the nude mice injected with LyP-1–functionalized multi-walled carbon nanotubes/MBD1siRNA was significantly relieved. The study demonstrated that LyP-1–functionalized multi-walled carbon nanotubes/MBD1siRNA could be a promising candidate for tumour active targeting therapy in pancreatic cancer.     

Engineering of Escherichia coli for targeted delivery of transgenes to HER2/neu-positive tumor cells

Targeting of non‐phagocytic tumor cells and prompt release of gene cargos upon entry into tumors are two limiting steps in the bacterial gene delivery path. To tackle these problems, the non‐pathogenic Escherichia coli strain BL21(DE3) was engineered to display the anti‐HER2/neu affibody on the surface. After co‐incubation with tumor cells for 3 h, the anti‐HER2/neu affibody‐presenting E. coli strain was selectively internalized into HER2/neu‐positive SKBR‐3 cells. The invasion efficiency reached as high as 30%. Furthermore, the bacteria were equipped with the phage ϕX174 lysin gene E‐mediated autolysis system. Carrying the transgene (e.g., eukaryotic green fluorescent protein, GFP), the tumor‐targeting bacteria were subjected to the thermal shock to trigger the autolysis system upon entry into HER2/neu‐positive cells. Flow cytometric analysis revealed that 3% of infected cells expressed GFP 24 h post thermal induction. Overall, the results show a promise of the proposed approach for developing bacteria as a delivery carrier. Biotechnol. Bioeng. 2011; 108:1662–1672. © 2011 Wiley Periodicals, Inc.     

Nanoparticle-mediated targeted drug delivery for breast cancer treatment

Breast cancer (BC) is the most common malignancy in women worldwide, and one of the deadliest after lung cancer. Currently, standard methods for cancer therapy including BC are surgery followed by chemotherapy or radiotherapy. However, both chemotherapy and radiotherapy often fail to treat BC due to the side effects that these therapies incur in normal tissues and organs. In recent years, various nanoparticles (NPs) have been discovered and synthesized to be able to selectively target tumor cells without causing any harm to the healthy cells or organs. Therefore, NPs-mediated targeted drug delivery systems (DDS) have become a promising technique to treat BC. In addition to their selectivity to target tumor cells and reduce side effects, NPs have other unique properties which make them desirable for cancer treatment such as low toxicity, good compatibility, ease of preparation, high photoluminescence (PL) for bioimaging in vivo, and high loadability of drugs due to their tunable surface functionalities. In this study, we summarize with a critical analysis of the most recent therapeutic studies involving various NPs-mediated DDS as alternatives for the traditional treatment approaches for BC. It will shed light on the significance of NPs-mediated DDS and serve as a guide to seeking for the ideal methodology for future targeted drug delivery for an efficient BC treatment.     

PEGylated trimethylchitosan emulsomes conjugated to octreotide for targeted delivery of sorafenib to hepatocellular carcinoma cells of HepG2

Abstract

The current study aimed to develop PEGylated trimethyl chitosan (TMC) coated emulsomes (EMs) conjugated with octreotide for targeted delivery of sorafenib to hepatocellular carcinoma cells (HCC) of HepG2. Sorafenib loaded TMC coated EMs were prepared by the emulsion evaporation method and characterized concerning particle size, zeta potential, drug encapsulation efficiency, and in vitro drug release. Synthesized EMs were then conjugated to octreotide. The cytotoxicity of the targeted and non-targeted EMs was determined by cellular uptake and MTT assay on HepG2 cell. Cell cycle assay was also studied using flow cytometry. The results showed the optimized EMs had the particle size of 127?nm, zeta potential of ?5.41?mV, loading efficiency of 95%, and drug release efficiency of 62% within 52?h. Octreotide was attached efficiently to the surface of EMs as much as 71%. MTT assay and cellular uptake studies showed that targeted EMs had more cytotoxicity than free sorafenib and non-targeted EMs. Cell cycle analyses revealed that there was a significant more accumulation of targeted EMs treated HepG2 cells in the G1 phase than free sorafenib and non-targeted EMs. The results indicate that designed EMs may be promising for the treatment of hepatocellular carcinoma.     

Synthesis and biological evaluation of novel taxoids designed for targeted delivery to tumors

The use of drug-antibody conjugates affords a method for the targeted delivery of anticancer drugs specifically to cancer cells. Monoclonal antibodies alone usually do not possess high therapeutic efficacy, however, they are capable of targeting tumor markers selectively. We have prepared taxoids with significantly higher cytotoxicity than paclitaxel and docetaxel. These taxoids now meet the high potency required for use in a targeted-delivery approach using monoclonal antibodies. The synthesis and biological evaluation of these taxoids are reported.     

PEG-PLA nanoparticles decorated with small-molecule PSMA ligand for targeted delivery of galbanic acid and docetaxel to prostate cancer cells

Prostate cancer (PCa) is one of the most prevalent non-drug delivery system cutaneous malignancies. Undoubtedly, introducing novel treatment options to achieve higher therapeutic index will be worthwhile. In this study, we report for the first time, a novel targeted self-assembled based on PEG-PLA nanoparticles (PEG-PLA NPs) containing galbanic acid (GBA) and docetaxel, which was targeted using ((S)-2-(3-((S)-5-amino-1-carboxypentyl) ureido) pentanedioic acid (ACUPA), a small molecule inhibitor targeting prostate-specific membrane antigen (PSMA), in prostate cancer cell line. The prepared NPs were characterized by different analytical methods. The MTT assay was used to compare the anti-proliferation of drugs-loaded PEG-PLA NPs and ACUPA-PEG-PLA against LNCaP (PSMA⁺) and PC3 (PSMA⁻) cells. PEG-PLA NPs with an average size of 130–140 nm had an enhanced release of GBA and docetaxel at pH 5.5 compared with pH 7.5. Spectrofluorometric analysis suggested that ACUPA-modified PEG-PLA could effectively enhance the drug uptake in PSMA⁺ prostate cancer cells. Cytotoxicity studies showed that the targeted NPs loaded with different concentrations of GBA and fixed concentration of docetaxel (4 nM) have shown higher toxicity (IC₅₀ 30 ± 3 µM) than both free GBA (80 ± 4.5 µM) and nontargeted NPs (IC₅₀ 40 ± 4.6 µM) in LNCaP cells. Collectively, these findings suggest that ACUPA-conjugated PEG-PLA nanosystem containing GBA and docetaxel is a viable delivery carrier for various cancer-targeting PSMA that suffer from short circulation half-life and limited therapeutic efficacy.     

Synthesis and characterization of a hemoglobin-ribavirin conjugate for targeted drug delivery

A novel conjugate of human hemoglobin (Hb) and the nucleoside analogue ribavirin (RBV) was synthesized to demonstrate the utility of Hb as a biocompatible drug carrier for improved drug delivery in the treatment of liver disease. RBV is used in combination with interferon for the treatment of hepatitis C, but its side effects can result in dose limitation or discontinuation of treatment. Targeted delivery of RBV may help to prevent or minimize its toxicity. The hemoglobin-ribavirin conjugate (Hb-RBV) was designed to release bioactive drug upon endocytosis by cells and tissues involved in extracellular Hb catabolism and clearance. Ribavirin-5'-monophosphate (RBV-P) was prepared from RBV and activated as the 5'-monophosphorimidazolide (RBV-P-Im) for reaction with carbonmonoxyhemoglobin to yield Hb-RBV consisting of multiple RBV drugs covalently attached as physiologically labile phosphoramidates via their 5'-hydroxyl groups. A molar drug ratio of six to eight RBV molecules per Hb tetramer was obtained with near complete haptoglobin (Hp) binding of the drug modified Hb maintained. The conjugate complex (Hp-Hb-RBV) was selectively taken up in vitro by cells that express the hemoglobin-haptoglobin receptor, CD163. Recovered ribavirin enzymatically cleaved from Hb-RBV showed equipotent antiproliferative activity compared to control unconjugated RBV against human HepG2 and mouse AML12 liver cell lines. Based upon the reported high level of Hb uptake in the liver, Hb-RBV may be useful in the treatment of certain liver diseases, as well as inflammatory disorders associated with CD163-positive macrophages.     

Synthesis of RGD analogs as potential vectors for targeted drug delivery

RGD analogs bind to integrin receptors with high affinity and therefore have the potential to be used as vectors for the targeted delivery of pharmaceutical agents to designated sites. Critical to this application is the ability to synthesize RGD analogs with different side chain functional groups that allow for the ready tethering of pharmaceutical agents without sacrificing their affinity for the target receptor significantly. A series of RGD analogs intended to be used as delivery vectors of pharmaceutical agents were prepared and evaluated for their ability to inhibit platelet aggregation by binding to glycoprotein IIb/IIIa. Among them, compound 11 showed the lowest IC50 against platelets activated by ADP. It was found that such RGD analogs could tolerate side chain modification fairly well with various functional groups attached such as amide, amine, ester, protected amine and poly(ethylene glycol). The fact that the compound with a side chain modification of poly(ethylene glycol) retained high affinity for glycoprotein IIb/IIIa (IC50 150 nM) suggests the feasibility of tethering fairly large pharmaceutical agents to such RGD analogs without significant sacrifice of their affinity to the intended receptor.