Nox4 is a protective reactive oxygen species generating vascular NADPH oxidase.

RATIONALE: The function of Nox4, a source of vascular H(2)O(2), is unknown. Other Nox proteins were identified as mediators of endothelial dysfunction. OBJECTIVE: We determined the function of Nox4 in situations of increased stress induced by ischemia or angiotensin II with global and tamoxifen-inducible Nox4(-/-) mice. METHODS AND RESULTS: Nox4 was highly expressed in the endothelium and contributed to H(2)O(2) formation. Nox4(-/-) mice exhibited attenuated angiogenesis (femoral artery ligation) and PEG-catalase treatment in control mice had a similar effect. Tube formation in cultured Nox4(-/-) lung endothelial cells (LECs) was attenuated and restored by low concentrations of H(2)O(2,) whereas PEG-catalase attenuated tube formation in control LECs. Angiotensin II infusion was used as a model of oxidative stress. Compared to wild-type, aortas from inducible Nox4-deficient animals had development of increased inflammation, media hypertrophy, and endothelial dysfunction. Mechanistically, loss of Nox4 resulted in reduction of endothelial nitric oxide synthase expression, nitric oxide production, and heme oxygenase-1 (HO-1) expression, which was associated with apoptosis and inflammatory activation. HO-1 expression is controlled by Nrf-2. Accordingly, Nox4-deficient LECs exhibited reduced Nrf-2 protein level and deletion of Nox4 reduced Nrf-2 reporter gene activity. In vivo treatment with hemin, an inducer of HO-1, blocked the vascular hypertrophy induced by Nox4 deletion in the angiotensin II infusion model and carbon monoxide, the product of HO-1, blocked the Nox4-deletion-induced apoptosis in LECs. CONCLUSION: Endogenous Nox4 protects the vasculature during ischemic or inflammatory stress. Different from Nox1 and Nox2, this particular NADPH oxidase therefore may have a protective vascular function.

Amphiphilic, low molecular weight poly(ethylene imine) derivatives with enhanced stability for efficient pulmonary gene delivery.

BACKGROUND: Poly(ethylene imine) (PEI) is a widely used transfection reagent for mammalian cells, but in vivo application of PEI 25 kDa is restricted by its toxicity. Low molecular weight (LMW) PEI is less toxic, but also less efficient than its high molecular weight equivalent, and prone to aggregation. METHOD: A set of polymers was synthesized by coupling poly(ethylene glycol) (PEG) that contained either C(16/18) -chains (Cx-EO) or butyl-poly(propylene oxide)-co-poly(ethylene glycol) (ButPP). Critical micelle concentration (CMC) was determined for copolymers. Polyplexes were characterized by DNA binding ability, polyplex size and aggregation, hemolysis, and cytotoxicity. Transfection efficiency was tested in vitro and in vivo in mouse lungs. RESULTS: Copolymers formed stable complexes with DNA, and showed enhanced complex stability in isotonic solution for at least 1 h. CMC was determined for Cx-EO-PEI 4.7 and 8.3 at 0.0019 and 0.0037 mM, respectively; membrane activity in a haemolysis assay was demonstrated for ButPP-PEI: both factors possibly enhance endosomal escape effect after PEGylation. IC(50) values of all synthesized polymers were in the range 6-33 ng/ml. Transfection efficiency of unmodified LMW-PEIs was equivalent or better than that of PEI 25 as a result of aggregation in vitro. Cells treated with polyplexes of amphiphilic polymers showed reduced transfection compared to PEI 25. After instillation in mouse lungs, highest transfection efficiency was demonstrated with Cx-EO copolymer of lowest molecular weight PEI. CONCLUSIONS: A new set of polymers with low toxicity and high stability was synthesized, which contains promising candidates for pulmonary gene transfer, as documented by in vivo experiments in mice.

Enhanced gene expression and reduced toxicity in mice using polyplexes of low-molecular-weight poly(ethylene imine) for pulmonary gene delivery.

The aim of this study was to elicit improved gene expression and decreased cytotoxicity for pulmonary gene therapy by replacing the commonly used carrier 25 kDa branched poly(ethylene imine) (BPEI) by two PEI derivatives, low-molecular-weight PEI (LMWPEI) and polyethylene glycol-grafted PEI (PEGPEI). All polymers were shown to condense DNA to spherical particles of approximately 100 nm. Biocompatibility was investigated in vitro and in vivo. Although transfection was less efficient with LMWPEI-DNA in vitro, this polyplex caused the highest luciferase expression in the mouse lung after intratracheal instillation. While PEGPEI luciferase expression in vitro was approximately three times higher when compared to BPEI, a transfection rate at the level of naked DNA was observed in vivo. LMWPEI polyplexes were located in both the bronchial and alveolar cells, whereas BPEI polyplexes were mainly detected in bronchial cells. LMWPEI combines low cytotoxicity with high transfection efficiency in the mouse lung in vivo, rendering it a promising strategy for pulmonary gene delivery.