Lee A. Davies

CpG-free plasmids confer reduced inflammation and sustained pulmonary gene expression

Pulmonary delivery of plasmid DNA (pDNA)/cationic liposome complexes is associated with an acute unmethylated CG dinucleotide (CpG)-mediated inflammatory response and brief duration of transgene expression. We demonstrate that retention of even a single CpG in pDNA is sufficient to elicit an inflammatory response, whereas CpG-free pDNA vectors do not. Using a CpG-free pDNA expression vector, we achieved sustained (≥56 d) in vivo transgene expression in the absence of lung inflammation.

Enhanced lung gene expression after aerosol delivery of concentrated pDNA/PEI complexes.

A major limitation of many self-assembling nonviral gene transfer formulations is that they are commonly prepared at relatively low component concentrations. While this typically has little impact on their use in cell culture, it can severely limit the progress of in vivo studies. In order to overcome this, we have developed a simple, scalable, pharmaceutically acceptable concentration method that has allowed us to increase the concentration of a commonly used pDNA/PEI formulation from 0.2 to >8 mg/ml plasmid DNA (pDNA). Crucially, the concentration method was found to have only minimal impact on the electrostatic properties or size of the pDNA/PEI particles. When delivered as an aerosol to the mouse lung, the concentrated pDNA/PEI formulations resulted in a 15-fold increase in lung reporter gene expression, with minimal impact in terms of inflammation or toxicity. Importantly, this performance advantage was replicated after aerosol administration to sheep lungs, with reporter gene expression being similarly approximately 15-fold higher than with the conventional pDNA/PEI formulation, and lung inflammation falling to background levels. These findings demonstrate that concentrated pDNA/PEI formulations offer increased aerosol gene transfer with decreased inflammatory sequelae, and represent a promising advance in the field of nonviral lung gene transfer. It seems likely that similar benefits might be achievable with alternative delivery routes and with other nonviral formulations.

Pre-clinical evaluation of three non-viral gene transfer agents for cystic fibrosis after aerosol delivery to the ovine lung

We use both large and small animal models in our pre-clinical evaluation of gene transfer agents (GTAs) for cystic fibrosis (CF) gene therapy. Here, we report the use of a large animal model to assess three non-viral GTAs: 25 kDa-branched polyethyleneimine (PEI), the cationic liposome (GL67A) and compacted DNA nanoparticle formulated with polyethylene glycol-substituted lysine 30-mer. GTAs complexed with plasmids expressing human cystic fibrosis transmembrane conductance regulator (CFTR) complementary DNA were administered to the sheep lung (n=8 per group) by aerosol. All GTAs gave evidence of gene transfer and expression 1 day after treatment. Vector-derived mRNA was expressed in lung tissues, including epithelial cell-enriched bronchial brushing samples, with median group values reaching 1–10% of endogenous CFTR mRNA levels. GL67A gave the highest levels of expression. Human CFTR protein was detected in small airway epithelial cells in some animals treated with GL67A (two out of eight) and PEI (one out of eight). Bronchoalveolar lavage neutrophilia, lung histology and elevated serum haptoglobin levels indicated that gene delivery was associated with mild local and systemic inflammation. Our conclusion was that GL67A was the best non-viral GTA currently available for aerosol delivery to the sheep lung, led to the selection of GL67A as our lead GTA for clinical trials in CF patients.

The development of gene therapy for diseases of the lung

The development of a successful gene therapy has many stages, including preclinical testing in animal models and proof of principle clinical studies. A variety of diseases affect the lung, which are candidates for gene therapy; this review will mainly focus on the diseases that have attracted the most attention and have therefore yielded the most progress, namely lung cancer and the monogenic disorder cystic fibrosis. Knowledge gained from clinical studies could eventually be applied to more complex lung conditions such as acute respiratory distress syndrome and asthma. In addition, increased gene transfer efficiencies could be obtained by appropriate selection of the gene transfer vector and mode of delivery.

Electroporation enhances reporter gene expression following delivery of naked plasmid DNA to the lung

Existing methods of non‐viral airway gene transfer suffer from low levels of efficiency. Electroporation has been used to enhance gene transfer in a range of tissues. Here we assess the usefulness of electroporation for enhancing gene transfer in the lungs of mice and sheep.

Optimising non-viral gene delivery in a tumour spheroid model.

Our current understanding of how the unique tumour microenvironment influences the efficacy of gene delivery is limited. The current investigation systematically examines the efficiency of several non‐viral gene transfer agents to transfect multicellular tumour spheroids (MCTS), an in vitro model that displays a faithful three‐dimensional (3D) representation of solid tumour tissue.

Long-term persistence of gene expression from adeno-associated virus serotype 5 in the mouse airways.

Recombinant adeno-associated virus vectors based on serotype 2 (rAAV2) have been used to deliver transgenes to the airways in a variety of pre-clinical and clinical studies. Gene transfer in these studies has been severely restricted by the basolateral localization of rAAV2 receptors. Here, we studied vectors constructed from the AAV5 genome and capsid, which utilize N-linked sialic acid-containing receptors found on the apical surface of airway epithelial cells. We investigated gene transfer efficacy and duration of transgene expression following delivery of rAAV5/5 vectors to the mouse respiratory tract. Robust, dose-dependent transgene expression was observed in the epithelium lining the nose for at least 32 weeks, and for at least 52 weeks in the lung. Importantly, in the lung, transgene expression mediated by rAAV5/5 was 40-fold greater than by rAAV2/2 vectors. A distinct cellular preference for rAAV5/5-mediated transduction was observed, with transgene expression being predominantly restricted to sustentacular cells of the olfactory epithelium in the nose and alveolar type II cells in the lung. Administration of rAAV5/5 vectors to both the nose and lungs led to the rapid development of rAAV5/5-neutralizing antibodies, suggesting that repeated administration may be severely hampered by host immune responses.

Pharmacological Characterization of a Novel ENaCα siRNA (GSK2225745) With Potential for the Treatment of Cystic Fibrosis

Lung pathology in cystic fibrosis is linked to dehydration of the airways epithelial surface which in part results from inappropriately raised sodium reabsorption through the epithelial sodium channel (ENaC). To identify a small-interfering RNA (siRNA) which selectively inhibits ENaC expression, chemically modified 21-mer siRNAs targeting human ENaCα were designed and screened. GSK2225745, was identified as a potent inhibitor of ENaCα mRNA (EC50 (half maximal effective concentration) = 0.4 nmol/l, maximum knockdown = 85%) and protein levels in A549 cells. Engagement of the RNA interference (RNAi) pathway was confirmed using 5′ RACE. Further profiling was carried out in therapeutically relevant human primary cells. In bronchial epithelial cells, GSK2225745 elicited potent suppression of ENaCα mRNA (EC50 = 1.6 nmol/l, maximum knockdown = 82%). In human nasal epithelial cells, GSK2225745 also produced potent and long-lasting (≥72 hours) suppression of ENaCα mRNA levels which was associated with significant inhibition of ENaC function (69% inhibition of amiloride-sensitive current in cells treated with GSK2225745 at 10 nmol/l). GSK2225745 showed no evidence for potential to stimulate toll-like receptor (TLR)3, 7 or 8. In vivo, topical delivery of GSK2225745 in a lipid nanoparticle formulation to the airways of mice resulted in significant inhibition of the expression of ENaCα in the lungs. In conclusion, GSK2225745 is a potent inhibitor of ENaCα expression and warrants further evaluation as a potential novel inhaled therapeutic for cystic fibrosis.

Aerosol delivery of DNA/liposomes to the lung for cystic fibrosis gene therapy

Abstract Lung gene therapy is being evaluated for a range of acute and chronic diseases, including cystic fibrosis (CF). As these therapies approach clinical realization, it is becoming increasingly clear that the ability to efficiently deliver gene transfer agents (GTAs) to target cell populations within the lung may prove just as critical as the gene therapy formulation itself in terms of generating positive clinical outcomes. Key to the success of any aerosol gene therapy is the interaction between the GTA and nebulization device. We evaluated the effects of aerosolization on our preferred formulation, plasmid DNA (pDNA) complexed with the cationic liposome GL67A (pDNA/GL67A) using commercially available nebulizer devices. The relatively high viscosity (6.3±0.1 cP) and particulate nature of pDNA/GL67A formulations hindered stable aerosol generation in ultrasonic and vibrating mesh nebulizers but was not problematic in the jet nebulizers tested. Aerosol size characteristics varied significantly between devices, but the AeroEclipse II nebulizer operating at 50 psi generated stable pDNA/GL67A aerosols suitable for delivery to the CF lung (mass median aerodynamic diameter 3.4±0.1 μm). Importantly, biological function of pDNA/GL67A formulations was retained after nebulization, and although aerosol delivery rate was lower than that of other devices (0.17±0.01 ml/min), the breath-actuated AeroEclipse II nebulizer generated aerosol only during the inspiratory phase and as such was more efficient than other devices with 83±3% of generated aerosol available for patient inhalation. On the basis of these results, we have selected the AeroEclipse II nebulizer for the delivery of pDNA/GL67A formulations to the lungs of CF patients as part of phase IIa/b clinical studies.

Adenovirus-mediated In Utero Expression of CFTR Does Not Improve Survival of CFTR Knockout Mice

Gene therapy is being investigated in the treatment of lung-related aspects of the genetic disease, Cystic fibrosis (CF). Clinical studies have demonstrated CF transmembrane conductance regulator (CFTR) expression in the airways of adults with CF using a variety of gene transfer agents. In utero gene therapy is an alternative approach that facilitates vector transduction of rapidly expanding populations of target cells while avoiding immune recognition of the vector. In CF, in utero gene transfer could potentially delay the onset of disease symptoms in childhood and compensate for the role, if any, that CFTR plays in the developing organs. Previously published studies have suggested that transient expression of CFTR in utero was sufficient to rescue the fatal intestinal defect in S489X Cftr(tm1Unc)/Cftr(tm1Unc) knockout mice. We replicated these studies using an identical CFTR-expressing adenoviral vector and CF mouse strain in sufficiently large numbers to provide robust Kaplan-Meier survival data. Although each step of the procedure was carefully controlled and vector-specific CFTR expression was confirmed in the fetal organs after treatment, there was statistically no significant improvement in the survival of mice treated in utero with AdCFTR, compared with contemporaneous control animals.