A pH-sensitive polymer that enhances cationic lipid-mediated gene transfer.

The efficient release of nonviral gene carriers from endosomes is an important step for the successful delivery of DNA into the cell nucleus. A synthetic pH-sensitive anionic polymer, poly(propylacrylic acid) (PPAA), was designed to aid in endosomal escape of nonviral vectors and improve the transfection efficiencies with these vectors. Transfection of NIH3T3 fibroblasts with ternary physical mixtures of the cationic lipid DOTAP, pCMVbeta plasmid DNA, and PPAA showed marked enhancement of both gene expression levels and fraction of cells transfected compared to binary control mixtures of DOTAP and DNA. PPAA also significantly improved the serum-stability of DOTAP/DNA vectors. The DOTAP/DNA/PPAA vectors maintained high levels of transfection in media containing up to 50% serum. The striking enhancement of transfection efficiency with cationic lipid/DNA/PPAA mixtures, along with the enhanced serum-stability, suggests that PPAA may provide significant improvements for the in vivo intracellular delivery of drugs such as DNA, oligonucleotides, proteins, and peptides.     

Nonviral vector loaded collagen sponges for sustained gene delivery in vitro and in vivo

Background

Naked DNA and standard vectors have previously been used for gene delivery from implantable carrier matrices with great potential for gene therapeutic assistance of wound healing or tissue engineering. We have previously developed copolymer‐protected gene vectors which are inert towards opsonization. Here we examine their potency in carrier‐mediated gene delivery in comparison to standard vectors using a vector‐loaded collagen sponge model.

Methods

Equine collagen type I sponges were loaded by a lyophilization method with naked DNA, polyethylenimine (PEI)‐DNA, DOTAP/cholesterol‐DNA and copolymer‐protected PEI‐DNA. These preparations were characterized in terms of vector‐release, cell growth on the matrices and reporter gene expression by cells colonizing the sponges in vitro and in vivo. Subcutaneous implantation of sponges in rats served as an in vivo model.

Results

At the chosen low vector dose, the loading efficiency was at least 86%. Naked DNA‐loaded collagen matrices lost 77% of the DNA dose in an initial burst in aqueous buffer in vitro. The other preparations examined displayed a sustained vector release. There was no difference in cell growth and invasion of the sponges between vector‐loaded and untreated collagen grafts. Reporter gene expression from cells colonizing the sponges in vitro was observed for not more than 7 days with naked DNA, whereas the lipoplex and polyplex preparations yielded long‐term expression throughout the experimental period of up to 56 days. The highest expression levels were achieved with the PEI‐DNA‐PROCOP (protective copolymer) formulation. Upon subcutaneous implantation in rats, no luciferase expression was detected with naked DNA preparations. DOTAP/cholesterol‐DNA and PEI‐DNA‐loaded implants lead to reporter gene expression for at least 3 days, but with poor reproducibility. PEI‐DNA‐PROCOP collagen matrices yielded consistently the highest reporter gene expression levels for at least 7 days with good reproducibility.

Conclusions

With the preparation method chosen, lipoplex‐ and polyplex‐loaded collagen sponges are superior in mediating sustained gene delivery in vitro and local transfection in vivo as compared to naked DNA‐loaded sponges. Protective copolymers are particularly advantageous in promoting the tranfection capacity of polyplex‐loaded sponges upon subcutaneous implantation, likely due to their stabilizing and opsonization‐inhibiting properties. Copyright © 2002 John Wiley & Sons, Ltd.

     

Evaluation by fluorescence resonance energy transfer of the stability of nonviral gene delivery vectors under physiological conditions

The stability in physiological medium of polyplex- and lipoplex-type nonviral gene vectors was evaluated by detecting the conformational change of complexed plasmid DNA (pDNA) labeled simultaneously with fluorescein (energy donor) and X-rhodamine (energy acceptor) through fluorescence resonance energy transfer (FRET). Upon mixing with cationic components, such as LipofectAMINE, poly(L-lysine), and poly(ethylene glycol)-poly(L-lysine) block copolymer (PEG-PLys), the fluorescence spectrum of doubly labeled pDNA underwent a drastic change due to the occurrence of FRET between the donor-acceptor pair on pDNA taking a globular conformation (condensed state) through complexation. The measurement was carried out also in the presence of 20% serum, under which conditions FRET from condensed pDNA was clearly monitored without interference from coexisting components in the medium, allowing evaluation of the condensed state of pDNA in nonviral gene vectors under physiological conditions. Serum addition immediately induced a sharp decrease in FRET for the LipofectAMINE/pDNA (lipoplex) system, which was consistent with the sharp decrease in the transfection efficiency of the lipoplex system in serum-containing medium. In contrast, the PEG-PLys/pDNA polyplex (polyion complex micelle) system maintained appreciable transfection efficiency even in serum-containing medium, and FRET efficiency remained constant for up to 12 h, indicating the high stability of the polyion complex micelle under physiological conditions.     

Targeting of polyplex to human hepatic cells by bio-nanocapsules, hepatitis B virus surface antigen L protein particles

We have previously demonstrated that lipoplex, a complex of cationic liposomes and DNA, could be targeted to human hepatic cells in vitro and in vivo by conjugation with bio-nanocapsules (BNCs) comprising hepatitis B virus (HBV) surface antigen L protein particles. Because the BNC-lipoplex complexes were endowed with the human hepatic cell-specific infection machinery from HBV, the complexes showed excellent specific transfection efficiency in human hepatic cells. In this study, we have found that polyplex (a complex of polyethyleneimine (PEI) and DNA) could form stable complexes with BNCs spontaneously. The diameter and ζ-potential of BNC-polyplex complexes are about 240 nm and +3.54 mV, respectively, which make them more suitable for in vivo use than polyplex alone. BNC-polyplex complexes with an N/P ratio (the molar ratio of the amine group of PEI to the phosphate group of DNA) of 40 showed excellent transfection efficiency in human hepatic cells. When acidification of endosomes was inhibited by bafilomycin A1, the complexes showed higher transfection efficiency than polyplex itself, strongly suggesting that the complexes escaped from endosomes by both fusogenic activity of BNCs and proton sponge activity of polyplex. Furthermore, the cytotoxicity is comparable to that of polyplex of the same N/P value. Thus, BNC-polyplex complexes would be a promising gene delivery carrier for human liver-specific gene therapy.     

Acinus

Fusion with lysosomes is the common last step of endocytic trafficking and autophagy. Accordingly, several proteins are required in both pathways for cargoes to reach their destinations. Among these proteins, Drosophila Acinus stands out, as it exerts opposite effects on these two pathways, and thus establishes a new paradigm. Loss of Acinus function destabilizes early endosomes, thereby promoting the delivery of their cargo to lysosomes. By contrast, the maturation of autophagosomes to autolysosomes is inhibited in acn mutant cells. The increase in autophagy upon Acinus overexpression and its location to the nucleus are consistent with Acinus being a novel regulator of autophagy.     

Chitosan enhanced gene delivery of cationic liposome via non-covalent conjugation

Two new types of stable ternary complexes were formed by mixing chitosan with DOTAP/pDNA lipoplex and DOTAP with chitosan/pDNA polyplex via non-covalent conjugation for the efficient delivery of plasmid DNA. They were characterized by atomic force microscopy, gel retarding, and dynamic light scattering. The DOTAP/CTS/pDNA complexes were in compacted spheroids and irregular lump of larger aggregates in structure, while the short rod- and toroid-like and donut shapes were found in CTS/DOTAP/pDNA complexes. The transfection efficiency of the lipopolyplexes showed higher GFP gene expression than DOTAP/pDNA and CTS/pDNA controls in Hep-2 and Hela cells, and luciferase gene expression 2–3-fold than DOTAP/pDNA control and 70–120-fold than CTS/pDNA control in Hep-2 cells. The intracellular trafficking was examined by confocal laser scanning microscopy. Rapid pDNA delivery to the nucleus enchanced by chitosan was achieved after 4 h transfection.     

Efficacy of immobilized polyplexes and lipoplexes for substrate‐mediated gene delivery

Non‐viral gene delivery by immobilization of complexes to cell‐adhesive biomaterials, a process termed substrate‐mediated delivery, has many in vitro research applications such as transfected cell arrays or models of tissue growth. In this report, we quantitatively investigate the efficiency of gene delivery by surface immobilization, and compare this efficiency to the more typical bolus delivery. The ability to immobilize vectors while allowing cellular internalization is impacted by the biomaterial and vector properties. Thus, to compare this efficiency between vector types and delivery methods, transfection conditions were initially identified that maximized transgene expression. For surface delivery from tissue culture polystyrene, DNA complexes were immobilized to pre‐adsorbed serum proteins prior to cell seeding, while for bolus delivery, complexes were added to the media above adherent cells. Mathematical modeling of vector binding, release, and cell association using a two‐site model indicated that the kinetics of polyplex binding to cells was faster than for lipoplexes, yet both vectors have a half‐life on the surface of approximately 17 min. For bolus and surface delivery, the majority of the DNA in the system remained in solution or on the surface, respectively. For polyplexes, the efficiency of trafficking of cell‐associated polyplexes to the nucleus for surface delivery is similar or less than bolus delivery, suggesting that surface immobilization may decrease the activity of the complex. The efficiency of nuclear association for cell‐associated lipoplexes is similar or greater for surface delivery relative to bolus. These studies suggest that strategies to enhance surface delivery for polyplexes should target the vector design to enhance its potency, whereas enhancing lipoplex delivery should target the material design to increase internalization. Biotechnol. Bioeng. 2009;102: 1679–1691. © 2008 Wiley Periodicals, Inc.     

Low-volume jet injection for efficient nonviral in vivo gene transfer

The transfer of naked deoxyribonucleic acid (DNA) represents an alternative to viral and liposomal gene transfer technologies for gene therapy applications. Various procedures are employed to deliver naked DNA into the desired cells or tissues in vitro and in vivo, such as by simple needle injection, particle bombardment, in vivo electroporation or jet injection. Among the various nonviral gene delivery technologies jet injection is gaining increasing acceptance because it allows gene transfer into different tissues with deeper penetration of the applied naked DNA. The versatile hand-held Swiss jet injector uses pressurized air to force small volumes of 3 to 10 μL of naked DNA into targeted tissues. The β-galactosidase (LacZ) reporter gene construct and tumor necrosis factor α gene-expressing vectors were successfully jet injected at a pressure of 3.0 bar into xenotransplanted human tumor models of colon carcinoma. Qualitative and quantitative expression analysis of jet injected tumor tissues revealed the efficient expression of these genes in the tumors. Using this Swiss jet-injector prototype repeated jet injections of low volumes (3–10 μL) into one target tissue can easily be performed. The key parameters of in vivo jet injection such as jet injection volume, pressure, jet penetration into the tumor tissue, DNA stability have been defined for optimized nonviral gene therapy. These studies demonstrate the applicability of the jet injection technology for the efficient and simultaneous in vivo gene transfer of two different plasmid DNAs into tumors. It can be employed for nonviral gene therapy of cancer using minimal amounts of naked DNA.     

Polymer‐coated viral vectors: hybrid nanosystems for gene therapy

The advantages and critical aspects of nanodimensional polymer‐coated viral vector systems potentially applicable for gene delivery are reviewed. Various viral and nonviral vectors have been explored for gene therapy. Viral gene transfer methods, although highly efficient, are limited by their immunogenicity. Nonviral vectors have a lower transfection efficiency as a result of their inability to escape from the endosome. To overcome these drawbacks, novel nanotechnology‐mediated interventions that involve the coating or modification of virus using polymers have emerged as a new paradigm in gene therapy. These alterations not only modify the tropism of the virus, but also reduce their undesirable interactions with the biological system. Also, co‐encapsulation of other therapeutic agents in the polymeric coating may serve to augment the treatment efficacy. The viral particles can aid endosomal escape, as well as nuclear targeting, thereby enhancing the transfection efficiency. The integration of the desirable properties of both viral and nonviral vectors has been found beneficial for gene therapy by enhancing the transduction efficiency and minimizing the immune response. However, it is essential to ensure that these attempts should not compromise on the inherent ability of viruses to target and internalize into the cells and escape the endosomes.     

Nucleofection-based gene targeting in human pre-B cells

Electroporation is a powerful and convenient means for transfection of nonviral vectors into mammalian cells, providing an essential tool for numerous applications including gene targeting via homologous recombination. Recent evidence clearly suggests that high-efficiency gene transfer can be achieved in most cell lines by nucleofection, an electroporation-based transfection method that allows transfected vectors to directly enter the nucleus. In this paper, we analyze the effectiveness of nucleofection for gene targeting using human pre-B cells. For this, we tested 93 different transfection conditions, and found several conditions that gave high (~ 80%) transfection efficiency with low cytotoxicity (~ 70% survival rate). Remarkably, under the optimal nucleofection conditions, the gene-targeting efficiency was ~ 2-5-fold higher than that achieved with conventional electroporation methods. We also found that nucleofection conditions with high transfection efficiency and low cytotoxicity tend to provide high gene-targeting efficiency. Our results provide significant implications for gene targeting, and suggest that nucleofection-based nonviral gene transfer is useful for systematic generation of human gene-knockout cell lines.     

Comparison of nonviral transfection and adeno-associated viral transduction on cardiomyocytes

Cardiomyocytes are terminally differentiated cells that to date have been characterized as poor targets for nonviral gene transfer. This study was therefore designed to determine the optimal nonviral gene transfer parameters in cell cultures of neonatal rat cardiomyocytes and to compare them with the efficiency of gene transfer using adeno-associated viral vectors (AAV). Transfection efficiency was measured by quantitative chloramphenicol acetyltransferase type I (CAT)-enzyme-linked immunosorbent assay and β-galactosidase staining, based on overexpression of reporter genes (CAT and LacZ). The efficiency of CAT/LacZ overexpression was assessed using the following techniques: (1) liposomal reagents, such as: FuGENE 6, LipofectAMINE 2000, LipofectAMINE PLUS, GenePORTER, Metafectene, and LipoGen; (2) electroporation and nucleofector techniques; and (3) an AAV2 vector harboring a lacZ reporter gene. Toxicity was monitored by total protein measurement and by analyzing cell metabolism. On average, Lipofectamine 2000 was the most effective nonviral method examined yielding consistently high transfection rates (8.1% β-galactosidase-positive cells) combined with low toxicity. Electroporation also resulted in high transfection values (7.5%); however, cellular toxicity was higher than that of Lipofectamine 2000. Finally, transduction with AAV2 vectors provided the highest levels of transduction (88.1%) with no cellular toxicity. We conclude that although transduction with AAV is more efficient (88.1%), transfections with nonviral techniques, when optimized, may provide a useful alternative for overexpression of therapeutic genes in neonatal cardiomyocytes.     

The role of surface chemistry-induced cell characteristics on nonviral gene delivery to mouse fibroblasts

ABSTRACT: BACKGROUND: Gene delivery approaches serve as a platform to modify gene expression of a cell population with applications including functional genomics, tissue engineering, and gene therapy. The delivery of exogenous genetic material via nonviral vectors has proven to be less toxic and to cause less of an immune response in comparison to viral vectors, but with decreased efficiency of gene transfer. Attempts have been made to improve nonviral gene transfer efficiency by modifying physicochemical properties of gene delivery vectors as well as developing new delivery techniques. In order to further improve and understand nonviral gene delivery, our approach focuses on the cell-material interface, since materials are known to modulate cell behavior, potentially rendering cells more responsive to nonviral gene transfer. In this study, self-assembled monolayers of alkanethiols on gold were employed as model biomaterial interfaces with varying surface chemistries. NIH/3T3 mouse fibroblasts were seeded on the modified surfaces and transfected using either lipid- or polymer- based complexing agents. RESULTS: Transfection was increased in cells on charged hydrophilic surfaces presenting carboxylic acid terminal functional groups, while cells on uncharged hydrophobic surfaces presenting methyl terminations demonstrated reduced transfection for both complexing agents. Surface--induced cellular characteristics that were hypothesized to affect nonviral gene transfer were subsequently investigated. Cells on charged hydrophilic surfaces presented higher cell densities, more cell spreading, more cells with ellipsoid morphologies, and increased quantities of focal adhesions and cytoskeleton features within cells, in contrast to cell on uncharged hydrophobic surfaces, and these cell behaviors were subsequently correlated to transfection characteristics. CONCLUSIONS: Extracellular influences on nonviral gene delivery were investigated by evaluating the upregulation and downregulation of transgene expression as a function of the cell behaviors induced by changes in the cells' microenvronments. This study demonstrates that simple surface modifications can lead to changes in the efficiency of nonviral gene delivery. In addition, statistically significant differences in various surface-induced cell characteristics were statistically correlated to transfection trends in fibroblasts using both lipid and polymer mediated DNA delivery approaches. The correlations between the evaluated complexing agents and cell behaviors (cell density, spreading, shape, cytoskeleton, focal adhesions, and viability) suggest that polymer-mediated transfection is correlated to cell morphological traits while lipid-mediated transfection correlates to proliferative characteristics.     

Nucleofection as an efficient nonviral transfection method for human monocytic cells

Despite some progress in the field of gene transfer into hard-to-transfect cells, so far an efficient nonviral method for monocytes has not been available. A comparison of plasmid DNA with capped and polyadenylated mRNA for enhanced green fluorescent protein gene delivery into the commonly used monocytic cell lines U937 and THP-1 suggested that limited DNA trafficking may be the underlying cause of poor transfection results. As Nucleofector technology delivers DNA (or mRNA) straight into the nucleus, we obtained nucleofection efficiencies of up to 80% without significant cell toxicity. Moreover, as the DNA quickly reaches the nucleus, nucleofected cells were ready for analysis after only 2–6 h. The technique is suitable not only for monocytes but also for other hard-to-transfect cells.     

Quantifying the intracellular transport of viral and nonviral gene vectors in primary neurons

Real-time confocal particle tracking (CPT) was used to compare the transport and trafficking of polyethylenimine (PEI)/DNA nanocomplexes to that of efficient adenoviruses in live primary neurons. Surprisingly, the quantitative intracellular transport properties of PEI/DNA nonviral gene vectors are similar to that of adenoviral vectors. For example, the values of individual particle/virus transport rates and the distributions of particle/virus transport modes (i.e., the percentage undergoing active, diffusive, or subdiffusive transport) largely overlapped. In addition, both PEI/DNA vectors and adenoviruses rapidly accumulated near the cell nucleus in primary neurons despite our finding that PEI/DNA move slower in neurites than in the cell body, whereas adenoviruses move with equal rates in either location. The intracellular trafficking pathways of PEI/DNA and adenoviruses, however, were substantially different. The majority of PEI/DNA trafficked through the endolysosomal pathway so as to end up in late endosomes/lysosomes (LE/Lys), whereas adenoviruses efficiently escaped endosomes. This result suggests that the sequestration of nonviral gene vectors within acidic vesicles may be a critical barrier to gene delivery to primary neurons in the central nervous system (CNS).     

pH-responsive three-layered PEGylated polyplex micelle based on a lactosylated ABC triblock copolymer as a targetable and endosome-disruptive nonviral gene vector

Nonviral vectors for gene therapy have recently received an increased impetus because of the inherent safety problems of the viral vectors, while their transfection efficiency is generally low compared to the viral vectors. The lack of the ability to escape from the endosomal compartments is believed to be one of the critical barriers to the intracellular delivery of noviral gene vectors. This study was devoted to the design and preparation of a novel ABC triblock copolymer for constructing a pH-responsive and targetable nonviral gene vector. The copolymer, lactosylated poly(ethylene glycol)-block-poly(silamine)-block-poly[2-(N,N-dimethylamino)ethyl methacrylate] (Lac-PEG-PSAO-PAMA), consists of lactosylated poly(ethylene glycol) (A-segment), a pH-responsive polyamine segment (B-segment), and a DNA-condensing polyamine segment (C-segment). The Lac-PEG-PSAO-PAMA spontaneously associated with plasmid DNA (pDNA) to form three-layered polyplex micelles with a PAMA/pDNA polyion complex (PIC) core, an uncomplexed PSAO inner shell, and a lactosylated PEG outer shell, as confirmed by 1H NMR spectroscopy. Under physiological conditions, the Lac-PEG-PSAO-PAMA/pDNA polyplex micelles prepared at an N/P (number of amino groups in the copolymer/number of phosphate groups in pDNA) ratio above 3 were found to be able to condense pDNA, thus adopting a relatively small size (< 150 nm) and an almost neutral surface charge (zeta approximately +5 mV). The micelle underwent a pH-induced size variation (pH = 7.4, 132.6 nm --> pH = 4.0, 181.8 nm) presumably due to the conformational changes (globule-rod transition) of the uncomplexed PSAO chain in response to pH, leading to swelling of the free PSAO inner shell at lowered pH while retaining the condensed pDNA in the PAMA/pDNA PIC core. Furthermore, the micelles exhibited a specific cellular uptake into HuH-7 cells (hepatocytes) through asialoglycoprotein (ASGP) receptor-mediated endocytosis and achieved a far more efficient transfection ability of a reporter gene compared to the Lac-PEG-PSAO/pDNA and Lac-PEG-PAMA/pDNA polyplex micelles composed of the diblock copolymers and pDNA. The effect of hydroxychloroquine as an endosomolytic agent on the transfection efficiency was not observed for the Lac-PEG-PSAO-PAMA/pDNA polyplex micelles, whereas the nigericin treatment of the cell as an inhibitor for the endosomal acidification induced a substantial decrease in the transfection efficiency, suggesting that the protonation of the free PSAO inner shell in response to a pH decrease in the endosome might lead to the disruption of the endosome through buffering of the endosomal cavity. Therefore, the polyplex micelle composed of ABC (ligand-PEG/pH-responsive segment/DNA-condensing segment) triblock copolymer would be a promising approach to a targetable and endosome disruptive nonviral gene vector.     

Acinus: A nuclear regulator of autophagy and endocytic trafficking

Fusion with lysosomes is the common last step of endocytic trafficking and autophagy. Accordingly, several proteins are required in both pathways for cargoes to reach their destinations. Among these proteins, Drosophila Acinus stands out, as it exerts opposite effects on these two pathways, and thus establishes a new paradigm. Loss of Acinus function destabilizes early endosomes, thereby promoting the delivery of their cargo to lysosomes. By contrast, the maturation of autophagosomes to autolysosomes is inhibited in acn mutant cells. The increase in autophagy upon Acinus overexpression and its location to the nucleus are consistent with Acinus being a novel regulator of autophagy.Key words: fat body, endosomes, lysosomes, nuclear protein, Notch signaling, EGF ReceptorMuch of the core machinery that is required for the formation and maturation of autophagosomes and endosomes has been identified by genetic screens in yeast. But as both types of organelles are charged with more complex functions in multicellular organisms, it is not surprising to find additional layers of regulation imposed on them. One such regulatory element was revealed by a genetic screen we conducted in Drosophila.The screen''s original idea was to take advantage of the observation that many proteins acting in trafficking to lysosomes also function in the biogenesis of lysosome-related organelles. Among these, the pigment granules—responsible for the characteristic color of the fly eye—are easily scored for defects. Thus, we set up a primary screen for eye color mutants. Among the more than 500 original hits, a secondary screen identified those mutants that altered endocytic trafficking. Importantly, the genetic tool kit assembled by the fly community allowed us to screen homozygous mutant eyes in otherwise heterozygous flies. This schema made it possible to identify mutations that are homozygous lethal as one might expect for null alleles of genes required for lysosomal delivery.One of the unexpected genes identified by this screen was acinus (acn). The Acn protein lacks any domain signatures and is most similar to human Acinus, which had been implicated in the destruction of chromatin during apoptosis. It is not clear yet whether the Drosophila protein contributes to this function as well, but in acn null alleles chromatin condensation and fragmentation during apoptosis appear normal.There is, however, a profound effect on endocytic trafficking, as acn is required for stabilization of early endosomes. Staining for endocytosed ligands, such as Boss or Delta, is drastically reduced, concomitant with a reduction in early endosomes marked by Rab5 or the SNARE Avl. By contrast, late endosomes marked by Rab7 appear normal. These changes do not represent a block in the initial internalization of the ligands, as inhibition of lysosomal degradation reveals the same accumulation of internalized ligands in wild-type and acn mutant cells.Reduced stability of early endosomes also causes reduced signaling from EGF receptors and Notch, consistent with the emerging notion that signaling from these receptors may be linked to their uptake into early endosomes.Many mutants that disrupt endocytic trafficking also affect autophagy. We found that this theme extends to acn. The most accessible form of autophagy in Drosophila is found in fat bodies after a short period of starvation. Activation of the AKT1/TOR pathway triggers the formation of autophagosomes, which mature into autolysosomes by fusing with lysosomes. Loss of acn interferes with this maturation step, as shown by the reduction in LysoTracker staining and also by quantitative electron microscopy. Consistent with an effect on the maturation of autophagosomes, acn is required downstream of TOR signaling. For example, expression of dominant-negative TOR kinase is a powerful tool to induce autophagy in the fat body of wild-type, but not acn larvae.Interestingly, overexpression of Acn induces autophagy. This does not appear to be merely a side effect. Ubiquitous expression of Acn is lethal, but flies survive when autophagy is suppressed by knockdown of ATG5, a core element of the autophagy machinery. We find that this enhanced autophagy is also independent of the TOR pathway.Taken together, this analysis of the first null mutant of an acinus gene in any system reveals its function as a regulator of endosomal and autophagosomal dynamics, modulating developmental signaling and the cellular response to starvation. Our investigation of acn loss-of-function phenotypes reveals defects in membrane trafficking during endocytosis and autophagy. We were therefore surprised that Acn protein localized to the nucleus, and that we failed to detect any consistent localization to endocytic or autophagic structures. This unexpected finding was further tested with transgenes expressing Myc-tagged Acn in the context of a genomic rescue construct. This tagged protein, under control of its endogenous enhancer/promoter elements, rescued all aspects of Acn function, and, nevertheless, localized to the nucleus, rather than any endosomal compartment.These findings suggest that the mechanism by which Acinus proteins modify endocytosis and autophagy may be indirect. One model for such an indirect effect is suggested by the interaction of mammalian Acinus proteins with several RNA binding proteins. Modulation of the levels or structure of RNAs that encode specific elements of the endocytosis or autophagy pathways may constitute an exciting new element of their regulation. Testing this possibility and identifying potential targets regulated by this Acn-dependent mechanism are important challenges that we have just begun to address.     

Synthesis of novel cationic lipids having polyamidoamine dendrons and their transfection activity

We designed a novel type of cationic lipid, lipids with a cationic polar group in the polyamidoamine dendron, because these dendron-bearing lipids are expected to form complexes with plasmid DNA and achieve efficient transfection of cells by synergy of endosome buffering and membrane fusion with the endosome, both of which are useful for the promotion of the transfer of plasmid DNA from endosome to cytosol. Four kinds of lipids with polyamidoamine dendrons of first to fourth generations, DL-G1, DL-G2, DL-G3, and DL-G4, were synthesized. The lipid with a dendron of a higher generation exhibited greater ability to form lipoplexes with plasmid DNA, as estimated by agarose gel electrophoresis. While the DL-G1 lipoplex did not transfect CV1 cells, the lipoplexes containing the DL-G2, DL-G3, or DL-G4 could induce transfection of the cells, and their activity was elevated with increasing generation of the dendron. Addition of dioleoylphosphatidylethanolamine (DOPE), which is known to increase fusion ability of a lipid membrane, into the lipoplexes greatly enhanced their transfection activity. In addition, the comparison with DC-Chol-containing lipoplex, which is widely used as a nonviral vector, showed that the DL-G3-DOPE lipoplex exhibits more efficient transfections. These findings imply that these dendron-bearing lipids may form the basis for a novel family of cationic lipids for efficient gene delivery.     

Polyethyleneimine-based immunopolyplex for targeted gene transfer in human lymphoma cell lines

Background

Specific and efficient delivery of genes into targeted cells is a priority objective in non‐viral gene therapy. Polyethyleneimine‐based polyplexes have been reported to be good non‐viral transfection reagents. However, polyplex‐mediated DNA delivery occurs through a non‐specific mechanism. This article reports the construction of an immunopolyplex, a targeted non‐viral vector based on a polyplex backbone, and its application in gene transfer over human lymphoma cell lines.

Methods

Targeting elements (biotin‐labeled antibodies), which should recognize a specific element of the target cell membrane and promote nucleic acid entry into the cell, were attached to the polyplex backbone through a bridge protein (streptavidin). Immunopolyplex transfection activity was studied in several hematological cell lines [Jurkat (CD3+/CD19?), Granta 519 (CD3?/ CD19+), and J.RT3‐T3.5 (CD3?/CD19?)] using the EGFP gene as a reporter gene and anti‐CD3 and anti‐CD19 antibodies as targeting elements. Transfection activity was evaluated via green fluorescence per cell and the percentage of positive cells determined by flow cytometry.

Results

A significant selectivity of gene delivery was observed, since the anti‐CD3 immunopolyplex worked only in Jurkat cells while the anti‐CD19 immunopolyplex worked only in the Granta cell line. Moreover, transfection of a CD3+/CD3? cell mixture with anti‐CD3 immunopolyplexes showed up to 16‐fold more transfection in CD3+ than in CD3? cells. Several non‐specific transfection reagents showed poor or no transfection activity.

Conclusion

It is concluded that immunopolyplex is a good non‐viral vector for specific and selective nucleic acid delivery. Immunopolyplex design allows easy replacement of the targeting element (antibody) – the streptavidin–polyplex backbone remaining intact – thereby conferring high versatility. Copyright © 2002 John Wiley & Sons, Ltd.

     

Enhancement of gene delivery to human airway epithelial cells in vitro using a peptide from the polyoma virus protein VP1

BACKGROUND: Current liposome-based gene delivery methods for therapeutic benefit are limited by their low efficiency. One possible way to improve gene expression is to include a peptide with a nuclear localization signal (NLS) to enhance the movement of the transfection complex from the cytoplasm to the nuclei of target cells. We have tested a synthetic peptide based on the amino terminal region of the polyoma virus VP1 protein. This region has non-overlapping motifs for DNA binding and nuclear localization. METHODS: Luciferase gene transfer efficiency was evaluated using this peptide and a control peptide with a mutated NLS in subconfluent, confluent and polarized human bronchial epithelial (16HBE) cells compared to lipoplex alone. RESULTS: Gene transfer efficiency with a lipopolyplex containing the VP1 peptide enhanced gene delivery compared to lipoplex. Transfection with a lipopolyplex containing the control peptide failed to enhance gene delivery. The VP1 peptide increased the amount of plasmid associated with the nucleus while the mutant VP1 peptide did not. The order of lipopolyplex formation was important, with greatest enhancement when peptide was added to the plasmid before addition of the liposome. A bipartite peptide with the VP1 sequence and an integrin-binding motif (RGD) resulted in a reduction in gene transfer efficiency compared to lipoplex. Cell adhesion studies showed that the integrin binding associated with the RGD motif was lost when it was attached to the VP1 sequence. The combination of the two peptide sequences in cis may have compromised the function of both. CONCLUSIONS: Our results indicate that the VP1 peptide represents a strategy to enhance liposome-mediated gene delivery to airway epithelia in vitro. Comparison of transfection efficiencies between the VP1 and the mutant VP1 peptides and the direct measurement of plasmid associated with the nucleus suggests that this enhancement is caused by the NLS signal sequence in the peptide.     

Rab11 facilitates cross-talk between autophagy and endosomal pathway through regulation of Hook localization

During autophagy, double-membrane autophagosomes deliver sequestered cytoplasmic content to late endosomes and lysosomes for degradation. The molecular mechanism of autophagosome maturation is still poorly characterized. The small GTPase Rab11 regulates endosomal traffic and is thought to function at the level of recycling endosomes. We show that loss of Rab11 leads to accumulation of autophagosomes and late endosomes in Drosophila melanogaster. Rab11 translocates from recycling endosomes to autophagosomes in response to autophagy induction and physically interacts with Hook, a negative regulator of endosome maturation. Hook anchors endosomes to microtubules, and we show that Rab11 facilitates the fusion of endosomes and autophagosomes by removing Hook from mature late endosomes and inhibiting its homodimerization. Thus induction of autophagy appears to promote autophagic flux by increased convergence with the endosomal pathway.