Receptor-mediated gene delivery using polyethylenimine (PEI) coupled with polypeptides targeting FGF receptors on cells surface (original) (raw)
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Coupling of cell-binding ligands to polyethylenimine for targeted gene delivery
Gene Therapy, 1997
Recently the high transfection potential of the cationic poly-fold increased transfection efficiency. This activity depends mer polyethylenimine (PEI) was described (Boussif O et al. on ligand-receptor interaction and was observed also at Proc Natl Acad Sci USA 1995; 92: 7297-7301). To com-low PEI cation:DNA anion ratios where ligand-free PEI bine the promising DNA delivering activity of PEI with the lacks efficiency. Depending on the cell-binding ligand, speconcept of receptor-mediated gene delivery, cell-binding cific targeting (CD3 antibody, Jurkat cells) can be achligands (transferrin or antiCD3 antibody) were incorporated ieved. Gene transfer can be augmented by the addition by covalent linkage to PEI. DNA complexes of PEI or of an endosome-destabilizing influenza peptide, but is not ligand-PEI conjugates were tested for transfection of cul-dependent on the presence of additional endosomolytic tured neuroblastoma Neuro 2A cells, melanoma B16 or agents. Application of transferrin-PEI for the production of H225 cells, erythroid leukemic K562 cells and T cell leuke-murine interleukin-2 in B16 cells resulted in exceptionally mia Jurkat E6.1 cells. Depending on the cell line, incorpor-high secretion rates of 19 g IL-2 protein per 10 6 cells per ation of the cell-binding ligand resulted in an up to 1000-24 h.
Bioconjugate Chemistry, 2001
With the aim of generating gene delivery systems for tumor targeting, we have synthesized a conjugate consisting of polyethylenimine (PEI) covalently modified with epidermal growth factor (EGF) peptides. Transfection efficiency of the conjugate was evaluated and compared to native PEI in three tumor cell lines: KB epidermoid carcinoma cells, CMT-93 rectum carcinoma cells, and Renca-EGFR renal carcinoma cells. Depending on the tumor cell line, incorporation of EGF resulted in an up to 300-fold increased transfection efficiency. This ligand-mediated enhancement and competition with free EGF strongly suggested uptake of the complexes through the EGF receptor-mediated endocytosis pathway. Shielded particles being crucial for systemic gene delivery, we studied the effect of covalent surface modification of EGF-PEI/DNA complexes with a poly(ethylene glycol) (PEG) derivative. An alternative way for the formation of PEGylated EGF-containing complexes was also evaluated where EGF was projected away from PEI/DNA core complexes through a PEG linker. Both strategies led to shielded particles still able to efficiently transfect tumor cells in a receptor-dependent fashion. These PEGylated EGF-containing complexes were 10-to 100-fold more efficient than PEGylated complexes without EGF.
Design and gene delivery activity of modified polyethylenimines
Advanced Drug Delivery Reviews, 2001
The polycation polyethylenimine (PEI) has recently been widely employed for the design of DNA delivery vehicles. Gene delivery using PEI involves condensation of DNA into compact particles, uptake into the cells, release from the endosomal compartment into the cytoplasm, and uptake of the DNA into the nucleus. Particularly for in vivo gene delivery, optimal coordination and timing between DNA complexation for protection of the DNA from nucleases and the disassembly of the complexes is essential. For in vivo application, DNA complexes have to pass a variety of anatomical and physiological barriers, and an environment of biological fluids and extracellular matrix before reaching their targets. Furthermore, targeted gene delivery is seriously hampered by non-specific interactions with non-target cells. Strategies have been developed to protect transfection complexes from non-specific interactions and to increase target specificity and gene expression.
Polyethylenimine-based nanocarriers in co-delivery of drug and gene: a developing horizon
Nano Reviews & Experiments
The meaning of gene therapy is the delivery of DNA or RNA to cells for the treatment or prevention of genetic disorders. The success rate of gene therapy depends on the progression and safe gene delivery system. The vectors available for gene therapy are divided into viral and non-viral systems. Viral vectors cause higher transmission efficiency and long gene expression, but they have major problems, such as immunogenicity, carcinogenicity, the inability to transfer large size genes and high costs. Non-viral gene transfer vectors have attracted more attention because they exhibit less toxicity and the ability to transfer large size genes. However, the clinical application of non-viral methods still faces some limitations, including low transmission efficiency and poor gene expression. In recent years, numerous methods and gene-carriers have been developed to improve gene transfer efficiency. The use of Polyethylenimine (PEI) based transfer of collaboration may create a new way of treating diseases and the combination of chemotherapy and gene therapy. The purpose of this paper is to introduce the PEI as an appropriate vector for the effective gene delivery.
Polymer-based non-viral gene delivery as a concept for the treatment of cancer
Pharmacological Reports, 2009
Gene therapy has become a promising technique for the treatment of cancer. Nevertheless, the success of gene therapy depends on the effectiveness of the vector. The challenge of a gene carrier is to deliver exogenous DNA from the site of administration into the nucleus of the appropriate target cell. Polymer-based vectors are biologically safe, have low production costs and are efficient tools for gene therapy. Although non-degradable polyplexes exhibit high gene expression levels, their application potential is limited due to their inability to be effectively eliminated, which results in cytotoxicity. The development of biodegradable polymers has allowed for high levels of transfection without cytotoxicity. For site-specific targeting of polyplexes, further modifications, such as incorporation of ligands, can be performed. Most expectations have been addressed to polyplexes architecture according it dynamic response with the microenvironment.
Journal of biomedical nanotechnology, 2018
Convenient methods for the preparation of gene delivery platforms based on branched low molecular weight polyethylenimine (PEI) were described. Firstly, PEI lipids, with a low molecular weight PEI headgroup and hexadecyl chain tail group, were prepared through a highly efficient ring-opening reaction of glycidyl hexadecyl ether (EpoxyC16) by amine from PEI. Then, the PEI lipids were used as a component of cationic liposomes and as a surfactant for the preparation of poly(D,L-lactide-co-glycolide) (PLGA) nanoparticle (NP) via solvent extraction/evaporation method. As potential effective gene delivery platforms, their preparation, size, size distribution, toxicities, plasmid DNA loading, in vitro transfection and intracellular trafficking were studied. Both facile platforms showed less toxicity and higher transfection efficacy when compared to high molecular weight PEI in vitro, and may have further versatile applications in the gene delivery field.
2014
Recently, polyethylenimines (PEIs) have emerged as efficient vectors for nucleic acids delivery. However, inherent cytotoxicity has limited their in vivo applications. To address this concern as well as to incorporate hydrophobic domains for improving interactions with the lipid bilayers in the cell membranes, we have tethered varying amounts of amphiphilic pyridoxyl moieties onto bPEI to generate a small series of pyridoxyl-PEI (PyP) polymers. Spectroscopic characterization confirms the formation of PyP polymers, which subsequently form stable complexes with pDNA in nanometric range with positive surface charge. The projected modification not only accounts for a decrease in the density of 1 • amines but also allows formation of relatively loose complexes with pDNA (cf. bPEI). Alleviation of the cytotoxicity, efficient interaction with cell membranes and easy disassembly of the pDNA complexes have led to the remarkable enhancement in the transfection efficiency of PyP/pDNA complexes in mammalian cells with one of the formulations, PyP-3/pDNA complex, showing transfection in ∼68% cells compared to ∼16% cells by Lipofectamine/pDNA complex. Further, the efficacy of PyP-3 vector has been established by delivering GFP-specific siRNA resulting in ∼88% suppression of the target gene expression. These results demonstrate the efficacy of the projected carriers that can be used in future gene therapy applications.
BioMed Research International, 2014
Previously, we demonstrated that 6-(N,N,N ,N -tetramethylguanidinium chloride)-hexanoyl-polyethylenimine (THP) polymers exhibited significantly enhanced transfection efficiency and cell viability. Here, in the present study, we have synthesized a series of N,N,N ,N -tetramethylguanidinium-polyethylenimine (TP1-TP5) polymers via a single-step reaction involving peripheral primary amines of bPEI and varying amounts of 2-(1H-benzotriazol-1-yl)-1,1,3,3-tetramethyluronium hexafluorophosphate (HBTU). These polymers were found to interact efficiently with negatively charged pDNA and formed stable complexes in the size range of ∼240-450 nm. Acid-base titration profiles revealed improved buffering capacity of TP polymers as compared to bPEI. Transfection and cytotoxicity assays performed with TP/pDNA complexes on HEK293, CHO, and HeLa cells showed significantly higher transfection efficiency and cell viability with one of the complexes, TP2/pDNA complex, exhibited the highest transfection efficiency (∼1.4-2.3fold) outcompeting native bPEI and the commercially available transfection reagent, Lipofectamine 2000. Compared to previously reported THP polymers, the transfection efficiency of TP/pDNA complexes was found to be lower, as examined by flow cytometry. These results highlight the importance of the hydrophobic C-6 linker in THP polymers in forming compact nanostructures with pDNA, which might lead to efficient uptake and internalization of the complexes; however, the projected TP polymers offer an advantage of their rapid and economical one-step synthesis.
Ovarian carcinoma cells are effectively transfected by polyethylenimine (PEI) derivatives
Cancer Gene Therapy, 2000
As a prerequisite to nonviral gene therapy approaches of ovarian carcinoma, we evaluated the possibility of transfecting established tumor cell lines (SKOV3, IGROV1) as well as primary mesothelial and tumor cells by various polyethylenimine (PEI) derivatives. Several PEI-based vectors were able to effectively transfect these cells, as shown by high luciferase expression levels (10 8 to 10 9 relative light units per milligram of cell protein) that corresponded with 25-50% of green fluorescent protein-positive cells after 24 hours. However, unpredictable differences were observed among the vectors and cell types that a posteriori justified the screening procedure. We also showed that cells that were not transfected after the first experiment remained transfectable in a subsequent transfection experiment to a level similar to that of the initial population. This experiment does not support the emergence of a transfection-resistant cell population and opens the door to multiple therapeutic gene deliveries. Although efficacy and cell targeting still remain to be improved, PEI derivatives appear to be promising molecules for the development of nonviral gene therapy of ovarian carcinoma. Cancer Gene Therapy (2000) 7, 644 -652
Synthesis and application of a non-viral gene delivery system for immunogene therapy of cancer
Journal of Controlled Release, 2005
The synthesis and gene delivery application of a novel lipopolymer, PEG-PEI-CHOL (PPC), is described. PPC is composed of a low molecular weight branched polyethylenimine (PEI) covalently linked with functional groups methoxypolyethyleneglycol (PEG) and cholesterol (CHOL). The potential utility of PPC as a gene delivery polymer was evaluated by showing its ability to form stable nanocomplexes with DNA, protect DNA from degradation by DNase and mediate gene transfer in vitro and in vivo in solid tumors. The ratio of PEG/PEI/CHOL and nitrogen to phosphate (Polymer/DNA) was optimized for physico-chemical properties and gene delivery efficiency of PPC/DNA complexes. The gene therapy application of the polymer was shown following administration of a murine IL-12 plasmid (pmIL-12) formulated with PPC into tumors in mice which resulted in significant inhibition of tumor growth. The inhibitory effects of pmIL-12/PPC were enhanced when combined with specific chemotherapeutic agents, demonstrating the potential usefulness of pIL-12/PPC as an adjuvant therapy for cancer treatment.