Mario Ariatti

Further Studies on Targeted DNA Transfer to Cells Using a Highly Efficient Delivery System of Biotinylated Transferrin and Biotinylated Polylysine Complexed to Streptavidin

Conjugates consisting of biotinylated transferrin and biotinylated poly-L-lysine attached to streptavidin have been prepared and found to transfer luciferase plasmid DNA very efficiently to HeLa cells in the presence of chloroquine. Transfection was dependent on (i) use of biotinylated short chain polylysine containing 70 lysine residues, (ii) biotinylated transferrin containing 1-2 biotin moieties, (iii) reaction of biotinylated transferrin with streptavidin followed by isolation of the resulting conjugate on Sephadex G-200 and (iv) interaction of streptavidin-biotinylated transferrin with biotinylated polylysine giving a complex suitable for DNA transfection. It was found that if the above sequence of steps resulting in the formation of streptavidin-biotinylated transferrin/biotinylated polylysine was followed without isolation of intermediate conjugates by Sephadex G-200 chromatography, pRSVL DNA transfer was still very efficient. Transfer of luciferase DNA by the streptavidin conjugates and subsequent expression of luciferase activity was almost completely inhibited by excess free transferrin, showing that gene transfer was through the transferrin receptor pathway via receptor-mediated endocytosis. The streptavidin (bio2-transferrin) bio10-pLys70 conjugate used in the present experiments was approximately one hundred times more efficient in pRSVL DNA transfection with the HeLa cells than the previously described avidin-pLys460 (bio-transferrin) complex.

Studies on the Transfer of DNA into Cells Through Use of Avidin-Polylysine Conjugates Complexed to Biotinylated Transferrin and DNA

A simple procedure has been developed for studying the transfer of DNA into cells using the process of receptor-mediated endocytosis. Poly-L-lysine 460 was covalently attached to the carbohydrate chains of avidin via periodate oxidation and NaBH4 reduction to give avidin-pLys460. Following purification through Sephacryl S-300, the conjugate was reacted with biotinylated transferrin. The resulting avidin-pLys460-[bio-transferrin] could be either fractionated by Superose 12 gel chromatography or used directly in experiments with DNA. Determination of the interaction between avidin-pLys460-]bio-transferrin] and DNA was carried out by nitro cellulose filter binding and agarose gel retardation assays. The conjugate was shown to bind DNA strongly, giving stable complexes soluble in 0.15-0.2 M salt solutions. Gene transfer using avidin-pLys460-[bio-transferrin] and the luciferase plasmid pRSVL was accomplished with Hela cells, alpha T3 pituitary cells and a human melanoma cell line used in the present study. Transfection was dependent on bio-transferrin and stimulated by the lysosomotropic agent chloroquine. The results are consistent with a receptor-mediated endocytosis mechanism of DNA delivery for Hela cells and a combination of receptor and adsorptive endocytosis for the alpha T3 pituitary and melanoma T-5 cell lines.

Low Concentrations of Chlorpromazine and Related Phenothiazines Stimulate Gene Transfer in HeLa Cells Via Receptor-Mediated Endocytosis

Chlorpromazine and related phenothiazine antipsychotic compounds at the low concentration of 10 -5 M stimulated luciferase pRSVL DNA uptake and expression in HeLa cells. On the other hand, chloroquine at a 10 -5 M was without effect at this low concentration. However, at the higher normally used concentration of 10 -4 M (100 μM), chloroquine strongly stimulated luciferase expression and activity. Unfortunately, at 10 -4 M, the phenothiazines were toxic to the cells and could not be tested at this concentration. Further experimental work was carried out to elucidate the mechanism of action of phenothiazines and chloroquine on DNA uptake and expression. Interaction of [3 H] pBR 322 DNA with chlorpromazine, perphenazine, and chloroquine was studied using these compounds as their free bases dissolved in chloroform, followed by their impregnation onto Whatman No. 1 filter paper discs. Both phenothiazines on filter paper discs bound [3 H] pBR 322 DNA to a far greater extent than chloroquine. The method of assay (free base) suggests that the major contribution to binding is through intercalation. A further possible assay for studying the interaction of phenothiazines and chloroquine made use of the ethidium bromide/calf thymus DNA intercalation method. Intercalated calf thymus (CT) DNA complexes with ethidium bromide (EB) were examined for possible dissociation into free DNA and EB on the addition of either chloroquine. SO 4 or chlorpromazine.HCl (soluble salts). Partial dissociation was observed with both compounds. Further experiments on the stability of pBR 322 DNA-polylysine complexes were also carried out using an alternative method of assay. Chloroquine (10 -2 - 10 -4 M) and chlorpromazine (10 -4 M) did not bring about a dissociation of [3 H] pBR 322 DNA-polylysine 200 complexes when reactions were studied by nitrocellulose filter assays to measure released double-stranded DNA. The results indicate that chlorpromazine and related phenothiazines stimulate luciferase DNA uptake expression at 10 -5 M. Chloroquine at this concentration had practically no effect on expression of luciferase activity. Further studies of chloroquine and chlorpromazine on their interaction with plasmid DNA as well as DNA-polylysine complexes are reported.

Effect of Polyethylene Glycol Conjugated to DNA-Transfecting Complexes Targeted at the Transferrin Receptor of HeLa Cells

AbstractModification of streptavidin (biotinylated transferrin)-biotinylated polylysine conjugates for DNA delivery by covalent addition of polyethylene glycol chains was investigated. It was found that addition of two to four monomethoxy-polyethylene glycol chains to bio20-polylysine100, a component of the transfecting conjugate, increased luciferase activity approximately four- to five-fold in a HeLa cell system. The increase occurred only in the presence of the lysosomotropic agent chloroquine and was inhibited by free transferrin. The latter result indicating that DNA uptake was via transferrin receptor-mediated endocytosis. Titration of cell cultures with transfecting complexes, with and without attached polyethylene glycol, showed luciferase activity to decrease at higher concentrations of the complexes. This was more marked with complexes containing polyethylene glycol. Complexes containing higher concentrations of attached polyethylene glycol inhibited luciferase expression strongly. Free polyethy...

Novel serum-tolerant lipoplexes target the folate receptor efficiently

Gene transfer using non-viral vectors is a promising approach for the safe delivery of nucleic acid therapeutics. In this study, we investigate a lipid-based system for targeted gene delivery to malignant cells overexpressing the folate receptor (FR). Cationic liposomes were formulated with and without the targeting ligand folate conjugated to distearoylphosphatidyl ethanolamine polyethylene glycol 2000 (DSPE-PEG2000), the novel cytofectin 3β[N(N(1),N(1)-dimethlaminopropylsuccinamidoethane)-carbamoyl]cholesterol (SGO4), which contains a 13atom, 15Å spacer element, and the helper lipid, dioleoylphosphatidylethanolamine (DOPE). Physicochemical parameters of the liposomes and lipoplexes were obtained by zeta sizing, zeta potential measurement and cryo-TEM. DNA-binding and protection capabilities of liposomes were confirmed by gel retardation assays, EtBr intercalation and nuclease protection assays. The complexes were assessed in an in vitro system for their effect on cell viability using the MTT assay, and gene transfection activity using the luciferase assay in three cell lines; HEK293 (FR-negative), HeLa (FR(+)-positive), KB (FR(++)-positive). Low cytotoxicities were observed in all cell lines, while transgene activity promoted by folate-tagged lipoplexes in FR-positive lines was tenfold greater than that by untargeted constructs and cell entry by folate complexes was demonstrably by FR mediation. These liposome formulations have the design capacity for in vivo application and may therefore be promising candidates for further development.

Novel Targeted Liposomes Deliver siRNA to Hepatocellular Carcinoma Cells in vitro

Liposomes form a major class of non‐viral vectors for short interfering RNA delivery, however tissue and cell‐specific targeting are additional requirements in the design of short interfering RNA delivery systems with a therapeutic potential. Selective delivery of liposomes to hepatocytes may be achieved by directing complexes to the asialoglycoprotein receptor, which is expressed on hepatocytes, and which displays high affinity for the β‐d‐galactopyranosyl moiety. We aimed to show that the d‐galactopyranosyl ring in direct β‐glycosidic link to cholesterol, when formulated into liposomes with 3β[N‐(N′,N′‐dimethylaminopropane) carbamoyl] cholesterol (Chol‐T) or its quaternary trimethylammonium analogue (Chol‐Q), may promote targeted delivery of cytotoxic short interfering RNA to the human hepatoma cell line HepG2 via the asialoglycoprotein receptor. Liposome‐short interfering RNA interactions were characterized by electron microscopy, dye displacement, gel retardation and nuclease assays. Stable short interfering RNA‐protective lipoplexes were formed at N/P ratios in the range 5:1–7:1. Targeted lipoplex 4 achieved high transfection efficiencies at 50 nm short interfering RNA (70%) and <10% in a competition assay, whilst untargeted complexes reached low levels at the same concentration (<25%). Transfection efficiencies of all lipoplexes in the asialoglycoprotein receptor‐negative cell line HEK293 under the same conditions were low. Lipoplexes containing cholesteryl‐β‐d‐galactopyranoside may therefore form the basis for the development of useful hepatotropic short interfering RNA delivery vectors.

Novel Neo Glycolipid: Formulation into Pegylated Cationic Liposomes and Targeting of DNA Lipoplexes to the Hepatocyte-Derived Cell Line HepG2

Liver parenchymal cells are an important target for the treatment of several metabolic and viral disorders. Corrective gene delivery for this purpose is an avenue that is receiving increasing attention. In the present study, we report a novel neo glycolipid that may be formulated into cationic liposomes with or without poly(ethylene glycol) decoration. Lipoplexes formed with plasmid DNA are nuclease resistant and are targeted to the human hepatoblastoma cell line HepG2 by selective asialoglycoprotein receptor mediation. Transfection levels achieved by lipoplexes containing the targeting ligand cholesteryl-3β-N-(4-aminophenyl-β-D-galactopyranosyl) carbamate were sixfold greater than those obtained with similar but untargeted lipoplexes.

Effect of Nicotinic Acid Conjugated to DNA-Transfecting Complexes Targeted at the Transferrin Receptor of HeLa Cells

A conjugate consisting of streptavidin (biotinylated transferrin)-biotinylated polylysine for DNA delivery to cells was modified by partial nicotinylation of the polylysine component of the conjugate and used for transfection studies. A conjugate of biotin10-nicotinyl60-polylysine250 containing 60 weakly basic nicotinyl (pyridine-3-carboxyl) residues was prepared. The design of the modified polylysine was directed to the possible binding of H+ ions in the endosome-lysosomal vesicles (pH 5-6) by the nicotinyl groups, thus circumventing the use of chloroquine. The results obtained, however, while showing a 5- to 6-fold increase in luciferase transfection activity still necessitated an absolute requirement for chloroquine. A further polylysine conjugate containing a larger number of nicotinyl residues, biotin10-nicotinyl120-polylysine250, also was prepared and studied. This macromolecule stimulated luciferase activity to a small extent and was also dependent on chloroquine. Smaller biotinylated polylysine100 conjugates containing nicotinyl groups were also prepared. These were biotin10-nicotinyl30-polylysine100, and biotin10-nicotinyl60-polylysine100, respectively. Both substances, however, gave opaque, hazy aqueous solutions with precipitates on standing and could not be used for further experimental work. The results indicate that the introduction of weakly basic nicotinyl (pyridine-3-carboxyl) groups onto polylysine250 give conjugates that are unable to replace the lysosomotrophic agent chloroquine in the HeLa cell sysem studied. A 5- to 6-fold increase in luciferase activity, however, was found with biotin10-nicotinyl60-polylysine250.A conjugate consisting of streptavidin (biotinylated transferrin)-biotinylated polylysine for DNA delivery to cells was modified by partial nicotinylation of the polylysine component of the conjugate and used for transfection studies. A conjugate of biotin10- nicotinyl60-polylysine250 containing 60 weakly basic nicotinyl (pyridine-3-carboxyl) residues was prepared. The design of the modified polylysine was directed to the possible binding of H+ ions in the endosome-lysosomal vesicles (pH 5-6) by the nicotinyl groups, thus circumventing the use of chloroquine. The results obtained, however, while showing a 5- to 6-fold increase in luciferase transfection activity still necessitated an absolute requirement for chloroquine. A further polylysine conjugate containing a larger number of nicotinyl residues, biotin10-nicotinyl120-polylysine250, also was prepared and studied. This macromolecule stimulated luciferase activity to a small extent and was also dependent on chloroquine. Smaller biotinylated polylysine100 conjugates containing nicotinyl groups were also prepared. These were biotin10-nicotinyl30-polylysine, and biotin10-nicotinyl60-polylysine100, respectively. Both substances, however, gave opaque, hazy aqueous solutions with precipitates on standing and could not be used for further experimental work. The results indicate that the introduction of weakly basic nicotinyl (pyridine-3-carboxyl) groups onto polylysine250 give conjugates that are unable to replace the lysosomotrophic agent chloroquine in the HeLa cell sysem studied. A 5- to 6-fold increase in luciferase activity, however, was found with biotin10-nicotinyl60- polylysine250.

A note on poly-L-lysine-mediated gene transfer in HeLa cells.

Poly-L-lysines of chain lengths varying from 70 to 300 residues are shown to bring about luciferase pRSVL DNA uptake and expression in HeLa cells. Transfection was approximately 50% that of the cationic liposome DOTAB. Expression was higher in the presence of chloroquine. Of interest was the fact that luciferase activity depended on the polysine/DNA charge ratio (+/−). Maximum activity occurred at a charge ratio (+/−) of 3, while at a charge ratio of 1 (conjugate electrically neutral) activity was much lower. At the higher charge ratios (+/−) of 4 and 5, luciferase activity decreased. The results obtained are discussed.

Lipoplex-mediated stable gene transfer into HeLa cells.

Unilamellar cationic liposomes containing phosphatidylcholine, L-α-phosphat-idyl-DL-glycerol, cholesterol and N,N-dimethylaminopropylaminyl succinyl cholesterol in lipoplexes with plasmid ptkNEO transfected HeLa cells efficiently in the presence of G418.