Nonionic amphiphilic block copolymers promote gene transfer to the lung.

Various pulmonary disorders, including cystic fibrosis, are potentially amenable to a treatment modality in which a therapeutic gene is directly delivered to the lung. Current gene delivery systems, either viral or nonviral, need further improvement in terms of efficiency and safety. We reported that nonionic amphiphilic block copolymers hold promise as nonviral gene delivery systems for transfection of muscular tissues. To evaluate the efficiency of these vectors in the lung, intratracheal instillation or aerosolization of reporter genes complexed with Lutrol or PE6400 was performed. Lutrol-DNA and, to a lesser extent, PE6400-DNA complexes promoted efficient gene transfection into mouse airways in a dose-dependent manner. This improvement over naked DNA was observed irrespective of the reporter gene. Lutrol enabled us to deliver significantly higher DNA amounts than current nonviral vectors, with even greater increases in gene expression and without the formation of colloidally unstable complexes. Time course studies showed that Lutrol-DNA complexes permitted prolonged gene expression for up to 5 days whereas with poly(ethylenimine) (PEI)-DNA polyplexes, expression peaked on days 1-2 postinstillation, was strongly reduced by day 5, and reached background levels on day 7. Aerosolized delivery of Lutrol-DNA complexes, a less invasive approach to deliver genes to the lung, gave 5- to 15-fold higher reporter gene expression compared with PEI-DNA polyplexes administered via the same delivery route. After intratracheal instillation of Lutrol-DNA complexes, histochemical staining for beta-galactosidase expression showed the presence of large blue areas. Histopathological analysis showed that Lutrol alone did not elicit inflammation, and that the inflammatory response after intratracheal instillation of Lutrol-DNA complexes was reversible and was observed only with the highest amounts of DNA. We also found that Lutrol can efficiently deliver genes to the airways of cystic fibrosis mice. Thus, we conclude that Lutrol is a highly promising vector for gene delivery to the lung.

Inducible production of erythropoietin using intramuscular injection of block copolymer/DNA formulation.

BACKGROUND: We have previously shown that intramuscular injection of plasmid DNA formulated with a non-ionic amphiphile synthetic vector [poly(ethylene oxide)(13)-poly(propylene oxide)(30)-poly(ethylene oxide)(13) block copolymer; PE6400] increases reporter gene expression compared with naked DNA. We have now investigated this simple non-viral formulation for production of secreted proteins from the mouse skeletal muscle. METHODS: Plasmids encoding either constitutive human secreted alkaline phosphatase or murine erythropoietin inducible via a Tet-on system were formulated with PE6400 and intramuscularly injected into the mouse tibial anterior muscle. RESULTS: PE6400/DNA formulation led to an increased amount of recombinant alkaline phosphatase secreted from skeletal muscle as compared with naked DNA. In the presence of doxycycline, a single injection of 10 microg plasmid encoding inducible murine erythropoietin formulated with PE6400 significantly increased the hematocrit, whereas the same amount of DNA in the absence of PE6400 had no effect. The increase in the hematocrit was stable for 42 days. The tetracycline-inducible promoter permitted pharmacological control of hematocrit level after DNA intramuscular injection. However, 4 months post-injection the hematocrit returned to its pre-injection value, even in the presence of doxycycline. This phenomenon was likely caused by an immune response against the tetracycline-activated transcription factor. CONCLUSIONS: Intramuscular injection of plasmid DNA formulated with PE6400 provides an efficient and simple method for secretion and production of non-muscle proteins.

Negatively charged self-assembling DNA/poloxamine nanospheres for in vivo gene transfer.

Over the past decade, numerous nonviral cationic vectors have been synthesized. They share a high density of positive charges and efficiency for gene transfer in vitro. However, their positively charged surface causes instability in body fluids and cytotoxicity, thereby limiting their efficacy in vivo. Therefore, there is a need for developing alternative molecular structures. We have examined tetrabranched amphiphilic block copolymers consisting of four polyethyleneoxide/polypropyleneoxide blocks centered on an ethylenediamine moiety. Cryo-electron microscopy, ethidium bromide fluorescence and light and X-ray scattering experiments performed on vector-DNA complexes showed that the dense core of the nanosphere consisted of condensed DNA interacting with poloxamine molecules through electrostatic, hydrogen bonding and hydrophobic interactions, with DNA molecules also being exposed at the surface. The supramolecular organization of block copolymer/DNA nanospheres induced the formation of negatively charged particles. These particles were stable in a solution that had a physiological ionic composition and were resistant to decomplexation by heparin. The new nanostructured material, the structure of which clearly contrasted with that of lipoplexes and polyplexes, efficiently transferred reporter and therapeutic genes in skeletal and heart muscle in vivo. Negatively charged supramolecular assemblies hold promise as therapeutic gene carriers for skeletal and heart muscle-related diseases and expression of therapeutic proteins for local or systemic uses.

A nonionic amphiphile agent promotes gene delivery in vivo to skeletal and cardiac muscles.

Direct injection of naked DNA into skeletal or cardiac muscle induces detectable gene expression. Although this provides a practical system for transgene expression, the reported efficacy is too low to confer a therapeutic benefit. By following a rational strategy based on the supramolecular structures adopted by active complexes, we have discovered a novel nonionic amphiphile synthetic agent [poly(ethyleneoxide)(13)-poly(propyleneoxide)(30)-poly(ethyleneoxide)(13) block copolymer; PE6400] that enables gene expression in up to 35% of muscle fibers from mouse tibial cranial muscle. PE6400 abolishes the ceiling effect on transgene expression of increasing amounts of naked DNA and permits long-term expression of the beta-galactosidase reporter gene in immunologically tolerant transgenic rats. This improvement in gene expression over naked DNA was observed irrespective of the reporter gene, ranging from 0.7 to 3.4 kb, and of the animal model used. In skeletal muscle, the PE6400 formulation led to a level of transfection efficiency similar to that obtained by electrotransfer. PE6400 also promotes high transgene expression in cardiac muscle. In contrast, PE6400-DNA formulations were inefficient in vitro in established cell lines and in isolated cardiomyocytes. When microinjected into the cell cytoplasm, PE6400 promotes DNA trafficking into the nucleus and induces gene expression. PE6400 provides a simple gene delivery system for skeletal and myocardial gene transfer. We propose that the PE6400 formulation could serve for the treatment of diseases primarily affecting muscle or for the expression of therapeutic proteins for local or systemic benefit.

Hyperstructures, genome analysis and I-cells.

New concepts may prove necessary to profit from the avalanche of sequence data on the genome, transcriptome, proteome and interactome and to relate this information to cell physiology. Here, we focus on the concept of large activity-based structures, or hyperstructures, in which a variety of types of molecules are brought together to perform a function. We review the evidence for the existence of hyperstructures responsible for the initiation of DNA replication, the sequestration of newly replicated origins of replication, cell division and for metabolism. The processes responsible for hyperstructure formation include changes in enzyme affinities due to metabolite-induction, lipid-protein affinities, elevated local concentrations of proteins and their binding sites on DNA and RNA, and transertion. Experimental techniques exist that can be used to study hyperstructures and we review some of the ones less familiar to biologists. Finally, we speculate on how a variety of in silico approaches involving cellular automata and multi-agent systems could be combined to develop new concepts in the form of an Integrated cell (I-cell) which would undergo selection for growth and survival in a world of artificial microbiology.