Methodological optimization of polyethylenimine (PEI)-based gene delivery to the lungs of mice via aerosol application

BACKGROUND: Polyethylenimine (PEI) has been successfully used for gene delivery to the lungs of mice via aerosol application using a whole body nebulization device. In this report we optimized the design of such an aerosol device. METHODS: Aerosol devices were constructed as either serial inhalation apparatus or as a whole body nebulization chamber connected to an aerosol spacer placed in a horizontal or vertical position. PEI-based gene vectors were nebulized using a standard jet nebulizer and luciferase gene expression of various tissues was examined. RESULTS: Using a whole body aerosol device resulted in luciferase gene expression in the lungs of mice at the same level as compared with a serial inhalation apparatus. Whereas gene expression was enhanced in the presence of 5% CO(2)-in-air, anesthesia of mice strongly decreased gene expression even when mice were intubated with an intravascular cannula. Reduction of the median mass aerodynamic diameter (MMAD) of the aerosol from 3.4 to 0.27 microm by interposition of an aerosol spacer increased gene expression significantly 3-fold. Drying of the aerosol by silica gel additionally increased gene delivery significantly 3-fold. Reporter gene expression mediated by branched PEI 25 kDa was 9- and 15-fold higher as compared with linear PEIs of 22 and 25 kDa, respectively, and was dependent on the DNA concentration. Gene expression was detectable as soon as 6 h after gene vector application and reached a maximum after 72 h but was still detectable after 14 days. The presence of Zn(2+) did not increase gene expression. CONCLUSION: We propose aerosol drying as a novel and simple method of optimizing PEI-based gene delivery to the lungs.     

Use of lipoplex-induced nuclear factor-kappaB activation to enhance transgene expression by lipoplex in mouse lung

BACKGROUND: Although lipofection-induced TNF-alpha can activate nuclear factor kappaB (NF-kappaB), which, in turn, increases the transgene expression from plasmid DNA in which any NF-kappaB responsive element is incorporated, no attempts have been made to use such biological responses as NF-kappaB activation against a vector to enhance vector-mediated gene transfer. METHODS: A lipoplex composed of N-[1-(2,3-dioleyloxy)propyl]-N,N,N-trimethylammonium and cholesterol liposome and plasmid DNA encoding firefly luciferase under the control of the cytomegalovirus immediate early promoter (pCMV-Luc) was intravenously injected into mice. Luciferase activity as well as NF-kappaB activation in the lung were evaluated. Then, a novel plasmid DNA, pCMV-kappaB-Luc, was constructed by inserting 5 repeats of NF-kappaB-binding sequences into the pCMV-Luc. RESULTS: NF-kappaB in the lung was activated by injection of the lipoplex and its nuclear localization was observed. An injection of lipopolysaccharide 30 min prior to the lipofection further activated NF-kappaB. At the same time, the treatment significantly increased the transgene expression by lipoplex, suggesting a positive correlation between expression and NF-kappaB activity. Based on these findings, we tried to enhance the lipoplex-based transgene expression by using NF-kappaB activation. The lipoplex consisting of pCMV-kappaB-Luc showed a 4.7-fold increase in transgene expression in the lung compared with that with pCMV-Luc. CONCLUSIONS: We demonstrated that NF-kappaB activation by lipoplex can be used to enhance lipoplex-mediated transgene expression by inserting NF-kappaB-binding sequences into plasmid DNA. These findings offer a novel method for designing a vector for gene transfer in conjunction with biological responses to it.     

Lipoplex size determines lipofection efficiency with or without serum

In order to identify factors affecting cationic liposome-mediated gene transfer, the relationships were examined among cationic liposome/DNA complex (lipoplex)-cell interactions, lipoplex size and lipoplex-mediated transfection (lipofection) efficiency. It was found that lipofection efficiency was determined mainly by lipoplex size, but not by the extent of lipoplex-cell interactions including binding, uptake or fusion. In addition, it was found that serum affected mainly lipoplex size, but not lipoplex-cell interactions, which effect was the major reason behind the inhibitory effect of serum on lipofection efficiency. It was concluded that, in the presence or absence of serum, lipoplex size is a major factor determining lipofection efficiency. Moreover, in the presence or absence of serum, lipoplex size was found to affect lipofection efficiency by controlling the size of the intracellular vesicles containing lipoplexes after internalization, but not by affecting lipoplex-cell interactions. In addition, large lipoplex particles showed, in general, higher lipofection efficiency than small particles. These results imply that, by controlling lipoplex size, an efficient lipid delivery system may be achieved for in vitro and in vivo gene therapy.     

The role of organ vascularization and lipoplex-serum initial contact in intravenous murine lipofection

Following intravenous administration of cationic lipid-DNA complexes (lipoplexes) into mice, transfection (lipofection) occurs predominantly in the lungs. This was attributed to high entrapment of lipoplexes in the extended lung vascular tree. To determine whether lipofection in other organs could be enhanced by increasing the degree of vascularization, we used a transgenic mouse model with tissue-specific angiogenesis in liver. Tail vein injection of N-(1-(2,3-dioleoyloxy)propyl)-N,N,N-trimethylammonium chloride (DOTAP)/cholesterol lipoplexes resulted in increased lipoplex entrapment in hypervascularized liver but did not boost luciferase expression, suggesting that lipoplex delivery is not a sufficient condition for efficient organ lipofection. Because the intravenously injected lipoplexes migrated within seconds to lungs, we checked whether the effects of immediate contact with serum correlate with lung lipofection efficiency of different DOTAP-based formulations. Under conditions mimicking the injection environment, the lipoplex-serum interaction was strongly dependent on helper lipid and ionic strength: lipoplexes prepared in 150 mM NaCl or lipoplexes with high (>33 mol%) cholesterol were found to aggregate immediately. This aggregation process was irreversible and was inversely correlated with the percentage of lung cells that took up lipoplexes and with the efficiency of lipofection. No other structural changes in serum were observed for cholesterol-based lipoplexes. Dioleoyl phosphatidylethanolamine-based lipoplexes were found to give low expression, apparently because of an immediate loss of integrity in serum, without lipid-DNA dissociation. Our study suggests that efficient in vivo lipofection is the result of cross-talk between lipoplex composition, interaction with serum, hemodynamics, and target tissue "susceptibility" to transfection.     

Effective pulmonary delivery of an aerosolized plasmid DNA vaccine via surface acoustic wave nebulization

Background

Pulmonary-delivered gene therapy promises to mitigate vaccine safety issues and reduce the need for needles and skilled personnel to use them. While plasmid DNA (pDNA) offers a rapid route to vaccine production without side effects or reliance on cold chain storage, its delivery to the lung has proved challenging. Conventional methods, including jet and ultrasonic nebulizers, fail to deliver large biomolecules like pDNA intact due to the shear and cavitational stresses present during nebulization.

Methods

In vitro structural analysis followed by in vivo protein expression studies served in assessing the integrity of the pDNA subjected to surface acoustic wave (SAW) nebulisation. In vivo immunization trials were then carried out in rats using SAW nebulized pDNA (influenza A, human hemagglutinin H1N1) condensate delivered via intratracheal instillation. Finally, in vivo pulmonary vaccinations using pDNA for influenza was nebulized and delivered via a respirator to sheep.

Results

The SAW nebulizer was effective at generating pDNA aerosols with sizes optimal for deep lung delivery. Successful gene expression was observed in mouse lung epithelial cells, when SAW-nebulized pDNA was delivered to male Swiss mice via intratracheal instillation. Effective systemic and mucosal antibody responses were found in rats via post-nebulized, condensed fluid instillation. Significantly, we demonstrated the suitability of the SAW nebulizer to administer unprotected pDNA encoding an influenza A virus surface glycoprotein to respirated sheep via aerosolized inhalation.

Conclusion

Given the difficulty of inducing functional antibody responses for DNA vaccination in large animals, we report here the first instance of successful aerosolized inhalation delivery of a pDNA vaccine in a large animal model relevant to human lung development, structure, physiology, and disease, using a novel, low-power (<1 W) surface acoustic wave (SAW) hand-held nebulizer to produce droplets of pDNA with a size range suitable for delivery to the lower respiratory airways.     

Lipoplex size determines lipofection efficiency with or without serum

In order to identify factors affecting cationic Iiposome-mediated gene transfer, the relationships were examined among cationic liposome/DNA complex (lipoplex)-cell interactions, lipoplex size and lipoplex-mediated transfection (lipofection) efficiency. It was found that lipofection efficiency was determined mainly by lipoplex size, but not by the extent of lipoplex-cell interactions including binding, uptake or fusion. In addition, it was found that serum affected mainly lipoplex size, but not lipoplex-cell interactions, which effect was the major reason behind the inhibitory effect of serum on lipofection efficiency. It was concluded that, in the presence or absence of serum, lipoplex size is a major factor determining Iipofection efficiency. Moreover, in the presence or absence of serum, lipoplex size was found to affect lipofection efficiency by controlling the size of the intracellular vesicles containing lipoplexes after internalization, but not by affecting lipoplex-cell interactions. In addition, large lipoplex particles showed, in general, higher lipofection efficiency than small particles. These results imply that, by controlling lipoplex size, an efficient lipid delivery system may be achieved for in vitro and in vivo gene therapy.     

Systemic administration of cationic phosphonolipids/DNA complexes and the relationship between formulation and lung transfection efficiency

Performances of cationic lipid formulations for intravenous gene delivery to mouse lungs have been previously reported. We report in this study that cationic phosphonolipids, when appropriately formulated, can be good synthetic vectors for gene delivery to lung after intravenous administration. One of our reagents, GLB43, was capable of mediating a 500-fold higher expression in the lungs of mice than could be obtained with free pDNA alone (P=0.018). We demonstrate that the most important parameters for cationic phosphonolipid transfection activity after systemic administration are the chemical structure of the cationic phosphonolipid, the lipid to DNA charge ratio and the inclusion of co-lipid in the formulation. We report using a luciferase reporter gene that transfection activity in vivo 24 h after cationic phosphonolipid systemic administration could not be predicted from in vitro analysis. In contrast to in vitro studies, cationic phosphonolipids including the oleyl acyl chains (GLB43) were more effective than its analogue with the myristyl acyl chains (GLB73). Using pathological analysis of animal livers, we demonstrate that the toxicity level was correlated with the lipoplex formulation and the lipid to DNA ratio.     

Haloperidol-associated stealth liposomes: a potent carrier for delivering genes to human breast cancer cells

Sigma receptors are membrane-bound proteins that are overexpressed in certain human malignancies including breast cancer. These receptors show very high affinity for various sigma ligands including neuroleptics like haloperidol. We hypothesized that in associating haloperidol-linked lipid into the cationic lipid-DNA complex, we can specifically target and deliver genes to breast cancer cells that overexpress sigma receptors. In the present study, haloperidol was chemically modified to conjugate at the distal end of the polyethylene glycollinked phospholipid, which was then incorporated into the cationic liposome known to condense and deliver genes inside cells. The resulting haloperidol-conjugated targeted lipoplex showed at least 10-fold higher (p < 0.001) reporter gene expression in MCF-7 cells than control lipoplex. The reporter gene expression of the targeted lipoplex was significantly blocked by haloperidol (p < 0.001) and by another sigma ligand, 1,3-ditolylguanidine (p < 0.001) in the majority of cationic lipid to DNA charge ratios (+/-). Spironolactone-mediated sigma receptor down-regulation enabled MCF-7 to show 10-fold lower transgene expression with targeted lipoplex compared with that obtained in spironolactone-untreated cells. The targeted lipoplex generated nonspecific gene expression in sigma receptor-nonexpressing human cancer cells such as Hela, KB, HepG2, and Chinese hamster ovary cells. Moreover, the transgene expression remained unabated in physiologically relevant serum concentrations. This is the first study to demonstrate that haloperidol-targeted gene delivery systems can mediate efficient targeting of genes to sigma receptor-overexpressing breast cancer cells, thereby becoming a novel class of therapeutics for the treatment of human cancers.     

Herpes simplex virus-enhanced cationic lipid/DNA-mediated transfection

Liposome plasmid DNA complexes (lipoplexes) are often inefficient in mediating gene transfer and expression because of DNA degradation in lysosomal vesicles. Because herpes simplex virus (HSV) enters cells by fusion of the virus envelope with the plasma membranes, thereby overriding the endosomal pathway, HSV/lipoplex mixtures could be useful for improving gene transfer particularly when the mixture uses highly defective HSV particles that fail to express cytotoxic viral gene products. To evaluate this possibility, lipoplexes composed of cationic liposomes and lacZ reporter plasmids were compared for their ability to transduce cells in culture in the presence and absence of infectious HSV particles. The results showed that HSV increased the efficiency of cell transduction by approximately 4-100-fold compared with lipoplex vector alone, depending on the cell type targeted for gene delivery. The increased efficiency of transduction was virus dose dependent and required virus entry.     

Development and characterization of a synthetic promoter for selective expression in proliferating endothelial cells

BACKGROUND: Systemic administration of non-viral gene therapy provides better access to tumors than local administration. Development of a promoter that restricts expression of cytotoxic proteins to the tumor vasculature will increase the safety of the system by minimizing expression in the non-dividing endothelial cells of the vasculature of non-target tissues. METHODS: Cell cycle promoters were tested for selective expression in dividing cells vs. non-dividing cells in vitro and promoter strength was compared to the cytomegalovirus (CMV) promoter. Successful promoter candidates were tested in vivo using two proliferating endothelium mouse models. Ovarectomized mice were injected with estradiol prior to lipoplex administration and expression levels were measured in the lungs and uterus 4 days after administration. The second model was a subcutaneous tumor model and expression levels were measured in the lungs and tumors. For both animal models, expression levels from the proliferating endothelium promoter were compared to that obtained from a CMV promoter. RESULTS: The results showed that the Cdc6 promoter yielded higher expression in proliferating vs. non-proliferating cells. Secondly, promoter strength could be selectively increased in endothelial cells by the addition of a multimerized endothelin enhancer (ET) to the Cdc6 promoter. Thirdly, comparison of expression levels in the lungs vs. uterus in the ovarectomized mouse model and lungs vs. tumor in the mouse tumor model showed expression was much higher in the uterus and the tumor than in the lungs for the ET/Cdc6 promoter, and expression levels were comparable to that of the CMV promoter in the hypervascularized tissues. CONCLUSIONS: These results demonstrate that the combination of the endothelin enhancer with the Cdc6 promoter yields selective expression in proliferating endothelium and can be used to express cytotoxic proteins to treat vascularized tumors.     

Hepatocyte-targeting gene delivery using a lipoplex composed of galactose-modified aromatic lipid synthesized with click chemistry

Highly efficient drug carriers targeting hepatocyte is needed for treatment for liver diseases such as liver cirrhosis and virus infections. Galactose or N-acetylgalactosamine is known to be recognized and incorporated into the cells through asialoglycoprotein receptor (ASGPR) that is exclusively expressed on hepatocyte and hepatoma. In this study, we synthesized a galactose-modified lipid with aromatic ring with click chemistry. To make a complex with DNA, termed ‘lipoplex’, we prepared a binary micelle composed of cationic lipid; dioleoyltrimethylammoniumpropane (DOTAP) and galactose-modified lipid (D/Gal). We prepared lipoplex from plasmid DNA (pDNA) and D/Gal and examined the cell specificity and transfection efficiency. The lipoplex was able to interact with ASGPR immobilized on gold substrate in the quartz-crystal microbalance (QCM) sensor cell. The lipoplex induced high gene expression to HepG2 cells, a human hepatocellular carcinoma cell line, but not to A549 cells, a human alveolar adenocarcinoma cell line. The treatment with asialofetuin, which is a ligand for ASGPR and would work as a competitive inhibitor, before addition of the lipoplexes decreased the expression to HepG2 cells. These results indicate that D/Gal lipoplex was incorporated into HepG2 cells preferentially through ASGPR and the uptake was caused by galactose specific receptor. This delivery system to hepatocytes may overcome the problems for gene therapy and be used for treatment of hepatitis and hepatic cirrhosis.     

Enhanced gene expression in lung by a stabilized lipoplex using sodium chloride for complex formation

BACKGROUND: In this study, we investigated the in vivo gene transfection efficacy of a 'surface charge regulated' (SCR) lipoplex, dispersed in the presence of an essential amount of NaCl during lipoplex formation. METHODS: SCR lipoplexes were prepared and their physicochemical properties were analyzed. After intravenous (i.v.) administration, transfection efficacy, distribution characteristics, and liver toxicity were evaluated in mice. RESULTS: At NaCl concentrations of 10 mM, the particle sizes of the SCR lipoplexes were about 120 nm and were compatible with a conventional lipoplex. However, fluorescent resonance energy transfer analysis revealed that cationic liposomes in the SCR lipoplexes increased fusion. After i.v. administration, the transfection activity in the lung of the SCR lipoplex (10 mM NaCl solution in the lipoplex) was approximately 10-fold higher than that of the conventional lipoplex. Pharmacokinetic studies demonstrated a higher distribution in lung by the SCR lipoplex. When the gene expression levels of the SCR lipoplex and conventional lipoplex were compared, the SCR lipoplex at a dose of 30 microg was compatible with that of the conventional lipoplex at a dose of 50 microg. A significantly higher serum alanine aminotransferase (ALT) activity and TNFalpha concentration was observed by the conventional lipoplex (pDNA dose; 50 microg), but this was not the case for the SCR lipoplex (pDNA dose; 30 microg). CONCLUSIONS: We demonstrated that the SCR lipoplex could enhance the transfection efficacy in the lung without increasing the liver toxicity. Hence, the information will be valuable for the future use, design, and development of lipoplexes for in vivo applications.     

Introduction of dinitrosyl iron complexes with thiol-containing ligands into animal organism by inhalation method

The possibility of water-soluble dinitrosyl iron complexes (DNIC) with thiol-containing ligands introduction into lungs and other tissues of mice by free inhalation of little drops (2–3 microns diameter) of the solutions of these complexes was investigated. Little drops of 2–20 mM solutions of the complexes were obtained by using an inhalation apparatus (compressor nebulizer). A cloud of these little drops was then inhaled by animals in a closed chamber. A maximal amount of protein-bound DNICs formed in mouse lungs was 0.6 micromoles per kilogram of tissue weight. The amount of DNIC in lungs, liver and blood decreased to the undetected level within 2–3 hours after inhalation. No cytotoxic effect of DNIC formed in lungs on Mycobacterium tuberculosis was found in mice infected with these mycobacteria.     

Role of tumor necrosis factor in oxygen toxicity.

mRNA from lungs of mice exposed to high-dose oxygen (greater than 95%) for 3 days demonstrated increased expression of the genes for tumor necrosis factor (TNF), interleukin-1, and interleukin-6 compared with mRNA from lungs of mice exposed to room air. Daily treatment of mice exposed to high-dose oxygen with an antibody to TNF improved survival compared with mice receiving a similar dose of control immunoglobulin G. Pretreatment of mice with repetitive sublethal intraperitoneal doses of recombinant human TNF for 3 days or a single intravenous dose followed by exposure to high-dose oxygen afforded a significant survival advantage compared with high-dose oxygen-exposed mice pretreated with vehicle or interleukin-1. The repetitive intraperitoneal TNF pretreatment reduced the development of interstitial pneumonitis, pulmonary edema, and lung weight gain associated with oxygen toxicity and enhanced expression of the gene for the free radical protective enzyme manganous superoxide dismutase in lung tissue, a gene that is augmented as mice are exposed to high-dose oxygen. Furthermore a single intravenous dose of TNF 24 h after oxygen exposure was still protective. The results suggest that the toxicity of oxygen therapy can be partially ameliorated by either treatment with anti-TNF antibody or pretreatment and early treatment with TNF. These findings are consistent with the hypothesis that oxygen exposure induces TNF, which causes part of the toxicity of high-dose oxygen, and that pretreatment or early treatment with TNF induces the gene for an enzyme that recently has been shown to be very effective in protecting mice from the toxicity of oxygen.     

Caecum: A Potential Site for Studying Gene Transfer in vivo

Abstract

Over the past years we have designed and synthesized a new class of synthetic vectors called phosphonolipids and then shown their ability to transfect lungs cells of mice with efficiency. One of them, GLB73, gave high levels of transfection. In the study reported here, we explored the potential of caecum as an alternative site for studying the feasibility of gene transfer in this site. Transfections were performed by using two reporter genes encoding for (igalactosidase and luciferase; transfection activity was assessed using two tests: chemiluminescent and cytofiuorimetric assays. The results obtained showed successful gene transfer into the caecum: up to 27% cells were LacZ+ with a mean of 11%; the maximum of efficiency was also observed 3 days after transfection which then decreased until day 7. Our lipoplex was 8-fold more efficient than the naked DNA (Mann Whitney test; p = 0.03). Moreover, we were able to visually follow the uptake of lipoplexes by enterocytes from 30 mn to 3 days post transfection.

So, this study constituted an encouraging first step in the assessment of the caecum as a potential model for gene transfer. In the near future, further electrophysiological studies using the gene of interest as CFTR gene should be performed in the caecum.     

Assembly and characterization of lipid-lipid binding protein particles

Lipid-protein complexes, lipoplexes, are currently of great interest because of their immunogenic, gene free, and low cost properties. For their applications as potential vaccines, it is critical to display a target protein on the surface of lipoplex particles to allow external interactions to take place. However, how to effectively assemble lipoplexes with target proteins externally accessible is a constant challenge. In this study, human liver fatty acid binding protein 1 (hl-FABP1) was used as a model protein in lipoplex assembly with a non-lipid binding protein, bovine serum albumin (BSA), serving as a comparison. The protein-lipid particles were assembled by four different processes and characterized by dynamic light scattering (DLS), transmission electron microscope (TEM), flow cytometry (FCM), and a modified ELISA. Results indicate that by incubating the target protein with pre-formed liposomes at a temperature higher than all transition temperatures (T_m) of the lipids used through an extended period of time, 1.48 × 10⁻⁶ nmol per lipoplex of incorporated proteins can be detected by ELISA and are externally accessible. Additional experiments showed that most of those externally accessible proteins are likely embedded in the lipid bilayer structure and are not subject to dissociation from the lipoplex particles at elevated salt concentrations.     

Improved aeroponic culture of inocula of arbuscular mycorrhizal fungi

We compared conventional atomizing disc aeroponic technology with the latest ultrasonic nebulizer technology for production of Glomus intraradices inocula. The piezo ceramic element technology used in the ultrasonic nebulizer employs high-frequency sound to nebulize nutrient solution into microdroplets 1 μm in diameter. Growth of pre-colonized arbuscular mycorrhizal (AM) roots of Sudan grass was achieved in both chambers used but both root growth and mycorrhization were significantly faster and more extensive in the ultrasonic nebulizer system than in the atomizing disc system. Shearing of the AM fungi (AMF) infected roots in both the systems did not reduce inoculum viability, as evident from the MPN data. However, sheared roots from the ultrasonic nebulizer system had significantly more infective propagules than those produced in the atomizing disc system. Thus, the latest ultra-sonic nebulizer aeroponic technology appears to be superior and an alternative to conventional atomizing disc or spray nozzle systems for the production of high-quality AMF inocula. These can be used in small doses to produce a large response, which is a prerequisite for commercialization of AMF technology. Accepted: 11 January 2000     

De novo ICAM-1 synthesis in the mouse lung: model of assessment of protein expression in lungs

Because most studies addressing the regulatory mechanisms of intercellular adhesion molecule (ICAM)-1 expression have used cultured endothelial cells, we set out to develop an isolated mouse lung preparation to study gene and protein expression in its proper cellular context in the organ. Lungs from CD1 mice were isolated and perfused (2 ml/min, 37 degrees C) with a recirculating volume of RPMI 1640 solution supplemented with 3 g/100 ml albumin. Lungs maintained their isogravimetric state for 4 h. Tumor necrosis factor (TNF-alpha; 2,000 U/ml) was added to the perfusate for 0.5, 1, 2, or 3.5 h to induce ICAM-1 expression or lungs received no treatment (control). After quick-freezing the lungs using liquid nitrogen at different time points, the prepared tissue homogenates were analyzed for ICAM-1 protein expression by Western blotting and NF-kappaB activation by electrophoretic mobility shift assay. TNF-alpha caused a progressive increase in NF-kappaB activity after 0.5 h and ICAM-1 protein expression two- to threefold of basal after 2 h. Untreated lungs expressed a low and constant level of ICAM-1 between 0 and 3.5 h. TNF-alpha failed to induce NF-kappaB activation and ICAM-1 expression in lungs of NADPH oxidase-deficient mice lacking p47(phox). We disaggregated mouse lungs using collagenase and stained the cells for ICAM-1 and VE-cadherin (used as an endothelial marker) to assess the in situ endothelial-specific expression of ICAM-1. We observed that TNF-alpha challenge resulted in increased ICAM-1 expression in endothelial cells freshly isolated from lungs. These data show the role of NADPH oxidase-derived oxidant signaling in the mechanism of NF-kappaB activation and ICAM-1 expression in mouse lung endothelial cells. Moreover, the general method presented herein has potential value in assessing mechanisms of gene and protein expression in the isolated-perfused mouse lung model.     

Characterization and Deposition of Respirable Large- and Small-Particle Bioaerosols

The deposition patterns of large-particle microbiological aerosols within the respiratory tract are not well characterized. A novel system (the flow-focusing aerosol generator [FFAG]) which enables the generation of large (>10-μm) aerosol particles containing microorganisms under laboratory conditions was characterized to permit determination of deposition profiles within the murine respiratory tract. Unlike other systems for generating large aerosol particles, the FFAG is compatible with microbiological containment and the inhalational challenge of animals. By use of entrapped Escherichia coli cells, Bacillus atrophaeus spores, or FluoSphere beads, the properties of aerosols generated by the FFAG were compared with the properties of aerosols generated using the commonly available Collison nebulizer, which preferentially generates small (1- to 3-μm) aerosol particles. More entrapped particulates (15.9- to 19.2-fold) were incorporated into 9- to 17-μm particles generated by the FFAG than by the Collison nebulizer. The 1- to 3-μm particles generated by the Collison nebulizer were more likely to contain a particulate than those generated by the FFAG. E. coli cells aerosolized using the FFAG survived better than those aerosolized using the Collison nebulizer. Aerosols generated by the Collison nebulizer and the FFAG preferentially deposited in the lungs and nasal passages of the murine respiratory tract, respectively. However, significant deposition of material also occurred in the gastrointestinal tract after inhalation of both the small (89.7%)- and large (61.5%)-particle aerosols. The aerosols generated by the Collison nebulizer and the FFAG differ with respect to mass distribution, distribution of the entrapped particulates, bacterial survival, and deposition within the murine respiratory tract.     

Global expression profiles from C57BL/6J and DBA/2J mouse lungs to determine aging-related genes.

This study identified gene expression profiles that provided evidence for genomic mechanisms underlying the pathophysiology of aging lung. Aging lungs from C57BL/6 (B6) and DBA/2 (D2) mouse strains differ in physiology and morphometry. Lungs were harvested from B6 mice at 2, 18, and 26 mo and from D2 mice at 2 and 18 mo of age. Purified RNA was subjected to oligonucleotide microarray analyses, and differential expression analyses were performed for comparison of various data sets. A significant majority of differentially expressed genes were upregulated with aging in both strains. Aging D2 lungs uniquely exhibited upregulation in stress-response genes including xenobiotic detoxification cascades. In contrast, aging B6 lungs showed downregulation of heat shock-response genes. Age-dependent downregulation of genes common to both B6 and D2 strains included several collagen genes (e.g., Col1a1 and Col3a1). There was a greater elastin gene (Eln) expression in D2 mice at 2 mo, and Eln was uniquely downregulated with age in this strain. The matrix metalloproteinase 14 gene (Mmp14), critical to alveolar structural integrity, was also downregulated with aging in D2 mice only. Several polymorphisms in the regulatory and untranslated regions of Mmp14 were identified between strains, suggesting that variation in Mmp14 gene regulation contributes to accelerated aging of lungs in D2 mice. In summary, lungs of B6 and D2 mice age with variable rates at the gene expression level, and these quantifiable genomic differences provide a template for understanding the variability in age-dependent changes in lung structure and function.