Alpha-1 antitrypsin limits neutrophil extracellular trap disruption of airway epithelial barrier function.

Neutrophil extracellular traps contribute to lung injury in cystic fibrosis and asthma, but the mechanisms are poorly understood. We sought to understand the impact of human NETs on barrier function in primary human bronchial epithelial and a human airway epithelial cell line. We demonstrate that NETs disrupt airway epithelial barrier function by decreasing transepithelial electrical resistance and increasing paracellular flux, partially by NET-induced airway cell apoptosis. NETs selectively impact the expression of tight junction genes claudins 4, 8 and 11. Bronchial epithelia exposed to NETs demonstrate visible gaps in E-cadherin staining, a decrease in full-length E-cadherin protein and the appearance of cleaved E-cadherin peptides. Pretreatment of NETs with alpha-1 antitrypsin (A1AT) inhibits NET serine protease activity, limits E-cadherin cleavage, decreases bronchial cell apoptosis and preserves epithelial integrity. In conclusion, NETs disrupt human airway epithelial barrier function through bronchial cell death and degradation of E-cadherin, which are limited by exogenous A1AT.

Defining strategies to extend duration of gene expression from targeted compacted DNA vectors.

Gene transfer complexes containing poly-L-lysine (poly-K) and DNA with ligands directed at the serpin enzyme complex receptor (sec-R) deliver reporter genes to receptor-bearing cells in vivo. Expression lasts for about 30 days, when complexes containing long-chain poly-K are used. Extending the duration of expression would be desirable if correction of genetic defects is the goal. To test whether the mechanism by which expression is extinguished was due to an immune response to the transgene, or the loss of the transgene, we conducted two experiments. In the first, we injected sec-R-targeted lacZ complexes intravenously (i.v.) into mice genetically engineered to express this gene briefly during development. These mice, who should recognize the protein as 'self', also extinguished lacZ expression after 30 days. In a second experiment, we injected immunodeficient animals with sec-R-targeted human factor IX complexes. A similar temporal pattern of expression was observed in Rag-1 -/- mice, in whom expression also extinguished by 40 days. Moreover, factor IX plasmid DNA was detected in the lung and spleen 50 days after injection of complexes, suggesting that not all cells which had taken up the transgene had been destroyed. Thus, the host's immune response to the transgene may not account for the loss of reporter gene expression from these molecular conjugates. We further tested whether repeat administration of sec-R-targeted complexes will be limited by host immune responses. Mice were pre-dosed twice with sec-R-targeted complexes containing lacZ over a 40-day period. We then injected the animals i.v. with sec-R-targeted human factor IX complexes and measured gene expression and antibody production. Although 14 of 36 animals displayed low-titer antibodies to the ligand in targeted complex, expression levels were unaffected compared with virgin dosing. When the complexes were administered three times intranasally (n=10), no antibodies against the complex were detected in blood. Plasma from mice dosed with saline, nontargeted complex or naked DNA did not react with the ligand, ligand-poly K conjugate or targeted complex. All animals exhibiting human factor IX expression developed antibodies to that transgene by 21 days. Thus, at least three repeat administrations of sec-R-directed molecular conjugates are possible, provided that immune responses to the transgene itself are not limiting.

Chain length of the polylysine in receptor-targeted gene transfer complexes affects duration of reporter gene expression both in vitro and in vivo.

Complexes composed of peptide ligand for the serpin enzyme complex receptor covalently coupled to poly-L-lysine condensed by charge interaction with plasmid DNA direct gene transfer into receptor bearing cells. We compared intensity and duration of reporter gene expression in vitro and in vivo from serpin-enzyme receptor-directed gene transfer complexes prepared with poly-L-lysine of different chain lengths. When substituted with linker and ligand to comparable extents, DNA complexes containing short chain poly-L-lysine were larger and gave higher peak expression but significantly shorter duration of expression than those containing long chain poly-L-lysine. Both peak expression and duration of expression exceeded that observed with Lipofectin. Neither naked DNA nor DNA complexed with unsubstituted polylysine was effective in gene transfer. For in vivo experiments, complexes containing optimal ligand and degree of substitution (based on in vitro data, peptide C105Y, 11 ligands/plasmid DNA molecule) were prepared with either short chain or long chain polylysine and a beta-galactosidase expression plasmid. Following injection into the tail veins of mice, longer chain complexes gave significantly higher expression of reporter gene in lung and spleen that lasted for a significantly longer period of time than the shorter chain complexes. The short chain poly-L-lysine-DNA complexes were larger in diameter, as assessed by electron microscopy or atomic force microscopy, and gave less protection against DNase digestion in vitro than longer chain complexes. Thus, for gene transfer complexes directed at the serpin enzyme complex receptor, longer chain poly-L-lysine gave a much longer duration of expression both in vitro and in vivo. We speculate that this may be due to protection against degradation afforded the plasmid DNA by the tighter compaction produced by long chain poly-L-lysine.

Transfer of the human Alpha1-antitrypsin gene into pulmonary macrophages in vivo.

Several viral and nonviral methods have introduced functional genes into the lungs. An alternative strategy, receptor-mediated gene transfer, exploits the ability of receptors on the surface of cells to bind and internalize DNA complexes and could potentially be used to deliver genes to specific cells in the lung. The gene encoding human alpha1-antitrypsin (A1AT) was delivered to macrophages in vitro and in vivo by targeting the mannose receptor with mannose-terminal molecular conjugates. The human A1AT transcript was detected 2 d after transfection of macrophages in culture, but transgene expression was transient. Human A1AT protein was secreted into the culture medium, and Western blot hybridization revealed the mature human antiprotease. In addition, Sprague-Dawley rats underwent intravenous injections of increasing doses of plasmid DNA (0.2 mg, 1.0 mg, and 2.0 mg) complexed to the molecular conjugate. Four days after transfection, human A1AT mRNA was found in lungs from six of the 13 rats (46%) that received the higher doses of plasmid. Transgene expression was limited to cells in perivascular and alveolar regions, which conformed to the distribution of pulmonary macrophages. Human A1AT was measured in the epithelial lining fluid of rats treated with transfection complexes. Animals that received 1.0 mg of plasmid had human A1AT levels of 7.4 +/- 3.4 pM, which was significantly different from nontransfected and mock-transfected controls. Thus the mannose receptor permitted direct delivery of genes to pulmonary macrophages, though transgene expression was detected in the lung only at low levels.

Ligand substitution of receptor targeted DNA complexes affects gene transfer into hepatoma cells.

We have targeted the serpin enzyme complex receptor for gene transfer in human hepatoma cell lines using peptides < 30 amino acids in length which contain the five amino acid recognition sequence for this receptor, coupled to poly K of average chain length 100 K, using the heterobifunctional coupling reagent sulfo-LC SPDP. The number of sulfo-LC SPDP modified poly-L-lysine residues, as well as the degree of peptide substitution was assessed by nuclear magnetic resonance spectroscopy. Conjugates were prepared in which 3.5%, 7.8% or 26% of the lysine residues contained the sulfo-LC SPDP moiety. Each of these conjugates was then coupled with ligand peptides so that one in 370, one in 1039, or one in 5882 lysines were substituted with receptor ligand. Electron microscopy and atomic force microscopy were used to assess complex structure and size. HuH7 human hepatoma cells were transfected with complexes of these conjugates with the plasmid pGL3 and luciferase expression measured 2 to 16 days after treatment. All the protein conjugates in which 26% of the K residues were modified with sulfo-LC SPDP were poor gene transfer reagents. Complexes containing less substituted poly K, averaged 17 +/- 0.5 nm in diameter and gave peak transgene expression of 3-4 x 10(6) ILU/mg which persisted (> 7 x 10(5) ILU) at 16 days. Of these, more substituted polymers condensed DNA into complexes averaging 20 +/- 0.7 nm in diameter and gave five-fold less luciferase than complexes containing less substituted conjugates. As few as eight to 11 ligands per complex are optimal for DNA delivery via the SEC receptor. The extent of substitution of receptor-mediated gene transfer complexes affects the size of the complexes, as well as the intensity and duration of transgene expression. These observations may permit tailoring of complex construction for the usage required.

Gene transfer into hepatoma cell lines via the serpin enzyme complex receptor.

The serpin enzyme complex receptor (SECR) expressed on hepatocytes binds to a conserved sequence in alpha 1-antitrypain (alpha 1-AT) and other serpins. A molecular conjugate consisting of a synthetic peptide (C1315) based on the SECR binding motif of human alpha 1-AT covalently coupled to poly-L-lysine was used to introduce reporter genes into hepatoma cell lines in culture. This conjugate condensed DNA into spheroidal particles 18-25 nm in diameter. When transfected with the SECR-directed complex containing pGL3, Hep G2 cells that express the receptor, but not Hep G2 cells that do not, expressed a peak luciferase activity of 538,731 +/- 144,346 integrated light units/mg protein 4 days after transfection. Free peptide inhibited uptake and expression in a dose-dependent manner. Complexes of DNA condensed with polylysine or LC-sulfo-N-succinimidyl-3-(2-pyridyldithio)propionate-substituted polylysine were ineffective. Transfection with a plasmid encoding human factor IX produced expression in Hep G2 (high) and HuH7 cells that express SECR but not Hep G2 (low) cells that lack the receptor. Fluorescein-labeled C1315 peptide labeled 9-31% of Hep G2 (high), 10-14% of HuH7, and 0.6-3.4% of Hep G2 (low) cells, and when the lac Z gene was transfected, only these cells expressed beta-galactosidase. SECR-mediated gene transfer gives efficient, specific uptake and high-level expression of three reporter genes, and the system merits further study for gene therapy.