Barbara Stevenson

Liposome-mediated CFTR gene transfer to the nasal epithelium of patients with cystic fibrosis

We report the results of a double-blind, placebo-controlled trial in nine cystic fibrosis (CF) subjects receiving cationic liposome complexed with a complementary DNA encoding the CF transmembrane conductance regulator (CFTR), and six CF subjects receiving only liposome to the nasal epithelium. No adverse clinical effects were seen and nasal biopsies showed no histological or immuno-histological changes. A partial restoration of the deficit between CF and non-CF subjects of 20% was seen for the response to low Cl− perfusion following CFTR cDNA administration. This was maximal around day three and had reverted to pretreatment values by day seven. In some cases the response to low Cl− was within the range for non-CF subjects. Plasmid DNA and transgene-derived RNA were detected in the majority of treated subjects. Although these data are encouraging, it is likely that transfection efficiency and the duration of expression will need to be increased for therapeutic benefit.

Evidence for safety and efficacy of DOTAP cationic liposome mediated CFTR gene transfer to the nasal epithelium of patients with cystic fibrosis

In cystic fibrosis (CF), mutation of the cystic fibrosis transmembrane conductance regulator (CFTR) gene results in defective transepithelial ion transport, leading to life shortening inflammatory lung disease. Before lung studies, we tested the safety and efficacy of gene delivery to the nasal epithelium of CF patients using pCMV-CFTR–DOTAP cationic liposome complex. A single dose of 400 μg pCMV-CFTR:2.4 mg DOTAP was administered in a randomised, double-blinded fashion to the nasal epithelium of eight CF patients, with a further eight receiving buffer only. Patients were monitored for signs and symptoms for 2 weeks before treatment and 4 weeks after treatment. Inflammatory cells were quantified in a nasal biopsy taken 3 days after treatment. There was no evidence for excess nasal inflammation, circulating inflammatory markers or other adverse events ascribable to active treatment. Gene transfer and expression were assayed by the polymerase chain reaction. Transgene DNA was detected in seven of the eight treated patients up to 28 days after treatment and vector derived CFTR mRNA in two of the seven patients at +3 and +7 days. Transepithelial ion transport was assayed before and after treatment by nasal potential difference during drug perfusion and by SPQ fluorescence halide ion conductance. Partial, sustained correction of CFTR-related functional changes toward normal values were detected in two treated patients. The level of gene transfer and functional correction were comparable to those reported previously using adenoviral vectors or another DNA–liposome complex, but here were sustained and uncompromised by false positives. These results justify further studies with pCMV-CFTR–DOTAP aimed at treating CF lung disease.

Inclusion of cholesterol in DOTAP transfection complexes increases the delivery of DNA to cells in vitro in the presence of serum

The contrast between the relative efficiency of transfection by cationic lipid reagents in vitro and that in vivo is well recognised. One suggested reason for this is the presence of competing polyanionic surfaces in blood and other biological fluids, and even in vitro transfections have to be performed in low-serum medium. In this study we have shown that by preparing cationic lipid reagents based on DOTAP with cholesterol as a second constituent of the bilayer we can achieve significant levels of in vitro transfection in serum concentrations of up to 80% (DOTAP alone did not transfect at all in these conditions). In an effort to explain the behaviour of DOTAP/cholesterol mixes under these conditions, we examined the effect of serum on the transfection complex. We could detect protein bound to each type of cationic lipid complex, but there was no difference in the amount nor in the type of protein bound. DNA within either type of complex which were incubated with increasing amounts of serum remained resistant to digestion with DNase I, and there was no reduction in the condensation of the DNA as measured by ethidium bromide fluorescence. Finally, we measured the attachment and uptake into cells by the different complexes in the presence of serum and showed that more DOTAP–cholesterol than DOTAP complexes attach to and are taken up by cells in the presence of serum. We suggest that improved cell binding and uptake may be the main mechanism by which cholesterol acts to maintain transfection in the presence of serum.

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.

Bacterial DNA is implicated in the inflammatory response to delivery of DNA/DOTAP to mouse lungs

Phase 1 clinical trials of liposome-mediated gene therapy for cystic fibrosis have been completed and in all cases the expression level achieved has been low and transient. Clearly, improvements in the efficiency of gene transfer are required. It is now being recognised that delivery of high doses of DNA/liposomes to the mouse airway epithelium can achieve reproducible evidence of transgene, but is often associated with an unacceptable level of inflammation/ toxicity. It has recently been shown that instillation of bacterial DNA causes inflammation in the lower respiratory tract of rodents. The increased number and unmethylated status of CpG motifs, particularly when present in a particular base context, was identified as an important factor in this response. It was suggested that the immune system recognises this molecular pattern as ‘foreign’ thus activating appropriate immune responses. We have found that methylation of DNA decreases the level of several inflammatory cytokines in lavage fluid and surprisingly has a differential effect on expression of the plasmids pCMV CFTR-int6ab and pCMV CAT which only differ in the actual transcription cassette. The severe lung pathology observed did not show a corresponding decrease with methylation suggesting that these cytokines are not the only contributors to the toxicity/inflammation observed.

Functional correction of episomal mutations withshort DNA fragments and RNA–DNA oligonucleotides

Gene correction is an alternative approach to replacement gene therapy. By correcting mutations within the genome, some of the barriers to effective gene therapy are avoided. Homologous nucleic acid sequences can correct mutations by inducing recombination or mismatch repair. Recently, encouraging data have been presented using both short DNAfragments (SDFs) and RNA–DNA oligonucleotides (RDOs) in experimental strategies to realize clinical gene correction.

Optimising gene repair strategies in cell culture.

Gene repair, the precise modification of the genome, offers a number of advantages over replacement gene therapy. In practice, gene targeting strategies are limited by the inefficiency of homologous recombination in mammalian cells. A number of strategies, including RNA-DNA oligonucleotides (RDOs) and short DNA fragments (SDFs), show promise in improving the efficiency of gene correction. We are using GFP as a reporter for gene repair in living cells. A single base substitution was introduced into GFP to create a nonsense mutation (STOP codon, W399X). RDOs and SDFs are used to repair this mutation episomally in transient transfections and restore green fluorescence. The correction efficiency is determined by FACS analysis. SDFs appear to correct GFP W399X in a number of different cell lines (COS7, A549, HT1080, HuH-7), although all at a similar low frequency (∼0.6% of transfected cells). RDOs correct only one of our cell lines significantly (HT1080-RAD51), these cells overexpress the human RAD51 gene; the bacterial RecA homologue. The GFP W399X reporter is a fusion gene with hygromycin (at the 5′ end), this has allowed us to make stable cell lines (A549, HT1080) to study genomic correction. Initial studies using our correction molecules show only low efficiencies of genomic repair (∽10−4). Polyethylenimine (PEI) is used to deliver RDOs and SDFs into mammalian cells in culture for our study. We have used fluorescently labelled RDOs and SDFs to study the effectiveness of this process. FACS analysis of transfected nuclei implied efficient delivery (>90%) both with SDFs and RDOs. However, confocal fluorescence microscopy suggests that a large proportion of the complexed RDO/SDF appears to remain outside the nucleus (or attached to the nuclear membrane). On the basis of these data we are assessing new delivery methods and factors that may alter recombination status to optimise gene repair.

Differential global gene expression in cystic fibrosis nasal and bronchial epithelium

Respiratory epithelium is the target of therapies, such as gene therapy, for cystic fibrosis (CF) lung disease. To determine the usefulness of the nasal epithelium as a pre-screen for lung-directed therapies, we profiled gene expression in CF and non-CF nasal and bronchial epithelium samples using Illumina HumanRef-8 Expression BeadChips. 863 genes were differentially expressed between CF and non-CF bronchial epithelium but only 15 were differentially expressed between CF and non-CF nasal epithelium (≥1.5-fold, P≤0.05). The most enriched pathway in CF bronchial epithelium was inflammatory response, whereas in CF nasal epithelium it was amino acid metabolism. We also compared nasal and bronchial epithelium in each group and identified differential expression of cellular movement genes in CF patients and cellular growth genes in non-CF subjects. We conclude that CF and non-CF nasal and bronchial epithelium are transcriptionally distinct and CF nasal epithelium is not a good surrogate for the lung respiratory epithelium.

The use of carboxymethylcellulose gel to increase non-viral gene transfer in mouse airways

We have assessed whether viscoelastic gels known to inhibit mucociliary clearance can increase lipid-mediated gene transfer. Methylcellulose or carboxymethylcellulose (0.25-1.5%) was mixed with complexes of the cationic lipid GL67A and plasmids encoding luciferase and perfused onto the nasal epithelium of mice. Survival after perfusion with 1% CMC or 1% MC was 90 and 100%, respectively. In contrast 1.5% CMC was uniformly lethal likely due to the viscous solution blocking the airways. Perfusion with 0.5% CMC containing lipid/DNA complexes reproducibly increased gene expression by approximately 3-fold (n=16, p<0.05). Given this benefit, likely related to increased duration of contact, we also assessed the effect of prolonging contact time of the liposome/DNA complexes by delivering our standard 80 microg DNA dose over either approximately 22 or 60 min of perfusion. This independently increased gene transfer by 6-fold (n=8, p<0.05) and could be further enhanced by the addition of 0.5% CMC, leading to an overall 25-fold enhancement (n=8, p<0.001) in gene expression. As a result of these interventions CFTR transgene mRNA transgene levels were increased several logs above background. Interestingly, this did not lead to correction of the ion transport defects in the nasal epithelium of cystic fibrosis mice nor for immunohistochemical quantification of CFTR expression. To assess if 0.5% CMC also increased gene transfer in the mouse lung, we used whole body nebulisation chambers. CMC was nebulised for 1h immediately before, or simultaneously with GL67A/pCIKLux. The former did not increase gene transfer, whereas co-administration significantly increased gene transfer by 4-fold (p<0.0001, n=18). This study suggests that contact time of non-viral gene transfer agents is a key factor for gene delivery, and suggests two methods which may be translatable for use in man.

Preparation for a first-in-man lentivirus trial in patients with cystic fibrosis.

We have recently shown that non-viral gene therapy can stabilise the decline of lung function in patients with cystic fibrosis (CF). However, the effect was modest, and more potent gene transfer agents are still required. Fuson protein (F)/Hemagglutinin/Neuraminidase protein (HN)-pseudotyped lentiviral vectors are more efficient for lung gene transfer than non-viral vectors in preclinical models. In preparation for a first-in-man CF trial using the lentiviral vector, we have undertaken key translational preclinical studies. Regulatory-compliant vectors carrying a range of promoter/enhancer elements were assessed in mice and human air–liquid interface (ALI) cultures to select the lead candidate; cystic fibrosis transmembrane conductance receptor (CFTR) expression and function were assessed in CF models using this lead candidate vector. Toxicity was assessed and ‘benchmarked’ against the leading non-viral formulation recently used in a Phase IIb clinical trial. Integration site profiles were mapped and transduction efficiency determined to inform clinical trial dose-ranging. The impact of pre-existing and acquired immunity against the vector and vector stability in several clinically relevant delivery devices was assessed. A hybrid promoter hybrid cytosine guanine dinucleotide (CpG)- free CMV enhancer/elongation factor 1 alpha promoter (hCEF) consisting of the elongation factor 1α promoter and the cytomegalovirus enhancer was most efficacious in both murine lungs and human ALI cultures (both at least 2-log orders above background). The efficacy (at least 14% of airway cells transduced), toxicity and integration site profile supports further progression towards clinical trial and pre-existing and acquired immune responses do not interfere with vector efficacy. The lead rSIV.F/HN candidate expresses functional CFTR and the vector retains 90–100% transduction efficiency in clinically relevant delivery devices. The data support the progression of the F/HN-pseudotyped lentiviral vector into a first-in-man CF trial in 2017.