Abstract
The cystic fibrosis transmembrane conductance regulator (CFTR) gene was cloned over two decades ago and a vast number of pre-clinical and clinical studies have been performed since that time. Despite this progress, a true "cure" for the disease has not been achieved, partly because the lung is a major barrier for intruders, making it exceedingly difficult for new pharmaceutical formulations to penetrate target cells. Safety-engineered viral vectors, such as adeno-associated viral vectors (AAVs) or integrase-defective lentiviruses, have been used with moderate success in temporarily supplementing the expression of critical proteins. However, stability and safety concerns often dampen the effects of these approaches. With emerging technologies, such as modified messenger (mRNA) and new genome editing strategies, scientists are now exploring the possibility of not only supplementing defective proteins, but instead, correcting the genetic defects at their source. This chapter will highlight the theoretical possibilities and primary data in pre-clinical models supporting the efforts toward in vivo gene correction of cystic fibrosis (CF).
Keywords
- Cystic fibrosis (CF)
- gene correction
- messenger RNA (mRNA)
- zinc finger nuclease (ZFN)
- transcription activator-like effector nuclease (TALEN)
- clustered regularly interspaced short palindromic repeats (CRISPR)
- CRISPR/Cas9
- dimeric CRISPR RNA-guided FokI
1. Introduction
Cystic fibrosis (CF) is the most prevalent life-shortening autosomal recessive disorder in Caucasian populations [1]. Occurring in 1 out of every 3,500 newborns in the United States, and 1 out of every 2,000–3,000 in the European Union, CF affects more than 70,000 individuals worldwide [2]. Chronic lung disease is the major factor contributing to morbidity and mortality among CF patients, as abnormal airway secretions and chronic endobronchial infection lead to progressive airway obstruction. In addition to the respiratory tract, the disease may also affect the pancreas, liver, kidneys, intestine, and reproductive system [3].
Disease severity varies greatly among those with CF, depending largely upon the degree to which the lungs are affected. However, eventual deterioration of the lungs leading to airway obstruction and death is inevitable, and for many years the average CF patient was not expected to reach adulthood [2]. Over the course of the past three decades, advancements in modern medicine have allowed physicians to postpone debilitating changes to the lungs, slowing the progression of disease and allowing many individuals with CF to live well into their 50s or 60s. Despite these advances in current therapy, the median age of survival remains only 33.4 years [2], emphasizing the need for novel therapeutic approaches to further improve patient outcomes in CF.
2. The pathophysiology of cystic fibrosis
Cystic fibrosis is the direct result of a mutation in both alleles of
Over 1500 different mutations have been described in the CFTR gene, each leading to different defects in the CFTR protein itself [7]. In the most common mutation, the deletion of phenylalanine (F) from position 508 (∆F508), improper protein folding results in the degradation of CFTR by the cell, which limits the amount of CFTR that reaches the epithelial cell surface. ∆F508-CFTR accounts for approximately 70% of CF cases worldwide and 90% of those occurring in the United States [7].
Alternative mutations in CFTR may result in truncation of the protein via premature stop codons, prevention of proper processing, folding, or trafficking to the plasma membrane, or interference with the chloride channel’s ion transport ability, leading to poor gating or conductance [8]. A patient’s specific CFTR gene mutation often dictates the severity of his or her disease, as well as the availability of drugs designed to target their particular protein defect.
In addition to mutations within
Traditional management strategies for CF typically involve the use of antibiotics to treat infection as well as agents or mechanical devices to improve mucus clearance and prevent damage to the lungs. Non-CFTR ion channel agents, for instance, are small molecules designed to normalize the transport of sodium and chloride by targeting non-CFTR ion channels expressed by epithelial cells. Osmotic agents, or inhaled hypertonic solutions, have also been employed to restore airway surface liquid by drawing liquid out of the airway epithelium and into the mucus [12].
In more recent years, the characterization of
3. Targeting functional defects in CFTR Protein: Small molecule CFTR modulators
A number of small molecules have been designed to overcome the functional defects in CFTR protein caused by upstream gene mutations (Figure 1). These CFTR modulators can be classified into three families according to the specific functional defect that they target: premature stop codon suppressors, correctors, and potentiators [13].
Lumacaftor (VX-809, Vertex Pharmaceuticals), for instance, is a CFTR corrector that increases trafficking of ∆F508-CFTR to the epithelial cell surface [14]. Lumacaftor has also been used in combination with ivacaftor (VX-770, Vertex Pharmaceuticals, trade name Kalydeco), a CFTR potentiator that improves the transport of chloride through CFTR channels rendered dysfunctional by G551D or R560T missense mutations. By binding to the channels and inducing a non-conventional mode of gating, ivacaftor increases the probability that the chloride channel is open [14]. Another small molecule CFTR modulator, ataluren (PTC124, PTC Therapeutics, trade name Translarna in the EU), is a production corrector that makes ribosomes less sensitive to G542X or W1282X nonsense mutations [15]. Overcoming these premature stop codons allows the synthesis of full-length, functional CFTR. Together, these small molecule modulators focus on addressing the functional defects in a patient’s own CFTR protein.
Gene therapy: Gene supplementation and transcript supplementation therapy
Instead of addressing the functional deficit in a patient’s endogenous CFTR, another approach involves supplementing the cell with an exogenous, functional copy of the protein (Figure 2). This can occur in one of several ways: through gene, transcript, or protein replacement therapy. By delivering a functional copy of the
4.1. Gene supplementation therapy
The two main forms of gene supplementation therapy are defined by the vehicle used to deliver functional cDNA to the cell: this consists of either viral or non-viral vectors (Figure 2A).
4.2. Transcript supplementation therapy
In recent years, transcript supplementation therapy has been introduced as an alternative to gene replacement therapy (Figure 2B). As mRNA transcripts are not capable of integrating into the chromosome, the threat of insertional mutagenesis is completely void. Following uptake via receptor-mediated endocytosis and lysosomal trafficking, mRNA also completely avoids the rate-limiting step of nuclear entry, being translated rapidly and efficiently directly in the cytoplasm [26]. With its naturally short half-life, mRNA transcripts are particularly useful for applications where short bursts of protein expression are desired. However, the addition of chemical modifications mimicking endogenous mRNA modification schemes has increased expression and stability, while decreasing immune responses. One major benefit to the use of chemically modified mRNA is the ability to readminister the vector as necessary.
The use of mRNA itself has long been appealing as an alternative to gene-based delivery vehicles. Unfortunately, for many years researchers were unable to use
In one recent study, transcript therapy with chemically modified
5. Repairing the CFTR mutation: Gene correction with genome-editing nucleases
With residual limitations in optimizing gene and transcript supplementation therapies for CF lung disease, a new field has begun to emerge: aiming to correct, rather than supplement, the defective gene. Compared to gene or transcript replacement approaches, “gene correction” aims to replace the defective portion of the CFTR gene with a normal allele at its natural chromosomal location (Figure 3). The repair of a mutant gene directly at its original locus has two major advantages. Most importantly, the corrected gene remains under control of its endogenous promoter, hence assuring life-long expression and native regulation in the cell. Moreover, depending on the delivery vehicle(s) used, gene correction has the potential to avoid the involvement of foreign DNA, thus reducing the risk of insertional mutagenesis.
Several lines of investigation into viable gene correction approaches have been pursued. These involve the use of genome-editing nucleases, such as ZFNs, TALENs, or CRISPR-based systems, to take advantage of the cell’s natural damage repair pathways. In this strategy, delivery of a site-specific-endonuclease (SSE) or SSE pair elicits a double-strand break (DSB) in the defective gene near the site of an unwanted mutation or sequence, initiating cellular repair mechanisms including homologous recombination (HR) and non-homologous end-joining (NHEJ).
NHEJ, an error-prone process, can be utilized to initiate mutations that essentially disrupt or knock out an undesirable gene. As NHEJ repairs the DSB by ligating the broken strands together, this process commonly results in small insertions or deletions of base pairs, known as indels. The generation of indels at the repair site can cause frame-shift mutations that prevent the protein from being properly transcribed and translated. This concept was demonstrated in 2008, when investigators utilized ZFNs and NHEJ to disrupt the HIV co-receptor,
Alternatively, a donor template can be delivered to the cell in addition to the nuclease(s), and used as a guide for directing HR, in a process referred to as homology-directed repair (HDR). In HDR, an extra-chromosomal donor fragment or “repair template” contains regions of significant homology up- and downstream of the DSB site. In between the homology arms, the repair template houses the desired, corrected sequence. Once the nuclease has cleaved, the regions of homology will be used as a template for rebuilding the site. As a result, the mutation-free sequence housed between homology arms is incorporated into the chromosome (Figure 3).
In cases where the patient is homozygous for the target allele, the uncleaved copy of the allele may be favored as a template for HR, decreasing efficiency. As such, it is important to provide the repair template in excess, to ensure that the target cell favors the repair template over the sister chromatid. It is also important to note that even when a repair template is provided in excess for HR, SSE binding and cleavage can also occur at off-target sites, which may initiate NHEJ. In the case of an off-target cutting event, NHEJ can cause unexpected mutations that may be harmful to the cell. As a result, potential off-target binding sites of the SSE should be predicted
Each of the available nuclease technologies utilizes a different method for recognizing specific sites and initiating DSB cleavage. In the following section, we will discuss the various mechanisms of action, as well as the pros and cons of each technology. It is important to note that in order to be safe for use in a clinical setting, nuclease technology must meet the following criteria:
Minimal off-target activity:
High binding specificity
Transient nuclease expression
High cleavage efficiency
Delivery to the cell using vectors that minimize insertional mutagenesis risk
5.1. Zinc finger nucleases
Zinc fingers are a common DNA-binding protein that can be found in nearly half of all transcription factors in the human genome [38]. These naturally abundant proteins can be re-engineered to recognize and bind specific target sequences. ZFN technology takes advantage of this by attaching a DNA-cleaving nuclease to the zinc finger-binding domain. The result is a site-specific binding protein that can cleave a strand of DNA at a precise location.
ZFNs utilize the non-specific DNA cleavage domain from the
Numerous evidence has supported the use of ZFNs for targeted gene editing in multiple species, including mice, rats, rabbits, pigs, plants, and zebrafish [38]. The use of this platform has also extended to the manipulation of stem cell populations
Despite this, ZFNs are not without their limitations. First, they are relatively difficult to engineer and expensive to purchase commercially, leaving them inaccessible to the majority of investigators. Secondly, not all sequences can be targeted by ZFNs, restricting their use in certain applications. And lastly, the specificity of ZFN pairs is not 100%, resulting in the potential for off-target cleavage events and related damage to occur. In the event of low specificity, off-target DSB induction may overwhelm cellular repair machinery leading to chromosomal rearrangements and/or cell death. These instances may also support random integration of donor DNA into undesirable locations, which has the potential to interfere with tumor suppressors, proto-oncogenes, or other actively transcribed genes [24,25].
5.2. Transcription activator-like effector nucleases
Transcription activator-like effector (TAL effector, or TALE) proteins are secreted by
TALENs utilize the same non-specific DNA cleavage domain from the
Compared with ZFNs, TALENs can cleave a broader, more comprehensive range of DNA sequences. In addition, they tend to be more accurate, reducing the potential for off-target cleavage events. Furthermore, as a result of the fast ligation-based automatable solid-phase high-throughput (FLASH) system reported in 2012, large-scale assembly of TALENs has also become a more efficient and cost-effective alternative [50].
5.3. CRISPR/Cas9
In 2012, the use of a novel genome-editing tool was described in human cell culture [51]. In bacteria and archaea, clustered regularly interspaced short palindromic repeats (CRISPR) work together with Cas genes to form a prokaryotic adaptive immune system that protects against foreign genetic elements such as plasmids or phages. Upon detecting viral DNA, for instance, this system converts segments of the foreign DNA into CRISPR RNAs (crRNA); the crRNA then combines with a trans-activating crRNA (tracrRNA). The crRNA–tracrRNA combination then guides a Cas9 DNA nuclease to a specific location within the viral DNA, called the protospacer, where a DSB is induced.
Investigators discovered that by designing a new crRNA and combining it with the tracrRNA, a “single-guide RNA” (sgRNA) could be produced that would direct the Cas9 nuclease activity to any desired location. Studies have shown that delivery of two components, the Cas9 nuclease and a corresponding sgRNA (containing both the crRNA and tracrRNA), were sufficient to elicit cleavage in a desired gene [52–55]. Hence, by retargeting the crRNA portion of the sgRNA, a site-specific genome-editing tool could be developed (Figure 4C).
Unlike ZFN and TALEN strategies, the nuclease cleavage domain in the CRISPR/Cas9 system is not fused to the DNA binding domain: instead, these are delivered to the cell in two separate components (Figure 4C). As a result of this design, only a single DNA binding domain has to be created. As this single protein-binding domain is significantly shorter than those required for TALEN or ZFN designs, CRISPR/Cas9 components are significantly easier and more cost effective to synthesize, making this technology more widely available to the research community at large. Despite lower costs and greater accessibility, the functional activity of CRISPR/Cas systems appears to be equal to or greater than their ZFN and TALEN counterparts.
As the CRISPR/Cas9 system is a relatively new genome engineering technology, it will be important for the field to thoroughly study any potential shortcomings. For instance, since a relatively short DNA binding domain and cleavage site are utilized, the risk of low specificity and potential off-target recognition may be greater [56].
5.4. Dimeric CRISPR RNA-guided Fok I nucleases
In an effort to reduce the risk of unwanted off-target mutations associated with monomeric CRISPR/Cas9 nucleases, a modified dimeric version has now been developed [57]. Where the monomeric Cas9 nuclease is recruited by one sgRNA of only ~100 nucleotides in length (with 17–20 nucleotides of complementarity to the target), dimerization offers an attractive strategy for improving the binding specificity of the Cas9 system (Figure 4D).
In this approach, a wild-type
5.5. Meganucleases
Meganucleases are another form of endonuclease utilized for genome editing approaches. They are unique in that their DNA recognition and cleavage functions are naturally combined in a single domain. There are five classes available, where I-SceI, I-CreI, and I-DmoI are perhaps the most widely used. Consisting of a large recognition site of 12 to 40 base pairs, meganucleases also offer high specificity and precision; however, historically, they were only capable of tolerating minor variations in their recognition site sequence, decreasing the probability of an available meganuclease for each desired application. In recent years, investigators have begun customizing meganucleases to expand their targeting repertoire. Two main approaches have been taken: modifying the specificity of existing meganucleases, and/or developing chimeric meganucleases with new recognition sites. In the latter approach, by fusing the DNA-binding domains of two different meganucleases, functional heterodimers can be designed for optimal efficacy and specificity (Figure 4E).
6. The best vehicle for the job
In genome editing, the identification of components capable of eliciting HDR is only half the battle. Efficiently delivering those components to the target cell can be an equally important hurdle to overcome. Unlike gene and transcript replacement therapies, where the goal is to achieve stable, long-term expression of a supplemental protein, gene editing has the advantage of requiring only short-term expression of the foreign components in the cell. Once these components have been expressed, induced a DSB, and triggered HDR, their presence is no longer necessary. In fact, in the attempt to minimize unwanted off-target cleavage activity and prolonged DSB induction, the ideal nuclease-delivery vehicle should only be transiently expressed.
Additionally, without the need for integration to promote stable expression, non-integrating delivery vehicles are also preferable, to minimize the risk of insertional mutagenesis. Delivery vehicles must also be capable of transducing target cells efficiently, to facilitate gene correction in enough cells to overcome the initial defect. To summarize, since transient expression of the nuclease is sufficient for stable modification of the genome, the ideal nuclease delivery vehicle should be:
Short-lived,
Non-integrating, and
Able to enter target cells efficiently.
A variety of vectors have been utilized to deliver genome-editing reagents to the cell. Initial
Due to its short half-life and inability to integrate into the genome, modified mRNA is gaining interest as an ideal vector for site-specific nuclease delivery: one that would address two of the main outstanding issues previously discussed. Transient expression of mRNA-encoded nucleases would also minimize the long-term threat of off-target events associated with the use of stably expressing, and possibly integrating viral vectors.
7. Gene correction in the lung
In a recent study, nuclease-encoding chemically modified mRNA (nec-mRNA) was described as a novel vehicle for delivering genome-editing components directly to the lung [37]. Using a murine model of SP-B deficiency, nec-mRNA-encoded ZFNs were able to demonstrate the first report of life-prolonging gene correction specifically within lung tissue.
In the transgenic mouse model of SP-B deficiency, SP-B cDNA is under the control of a Tetracycline-inducible promoter [58]. Administration of doxycycline allows SP-B to be expressed at wild-type levels. If doxycycline is removed, SP-B expression drops and mice begin to exhibit phenotypic changes similar to those seen in humans with the disease: thickened alveolar walls, heavy cellular infiltration, increased macrophages and neutrophils, interstitial edema, congestion, augmented cytokines in the lavage, a significant drop in lung function, and acute onset of respiratory distress leading to death within days [59,60].
In order to demonstrate the value of nec-mRNA for lung-based genome-editing applications, this report utilized HDR to insert a constitutive CAG promoter immediately upstream of the SP-B cDNA. The resulting doxycycline-independent expression was able to significantly prolong the life of treated mice [37].
While this study was not performed in a humanized mouse model, the approach was able to demonstrate that extra-chromosomal nec-mRNA is capable of transducing airway epithelial cells, expressing genome-editing reagents, and achieving HDR rates sufficient for therapeutic levels of protein expression. Main findings from the study include:
mRNA modification schemes can be customized to optimize expression and minimize immunity.
Intratracheal delivery of nec-mRNA is able to target airway epithelial cells.
Complexing nec-mRNA to chitosan-coated nanoparticles can increase transduction efficiency in the lung.
nec-mRNA expression is transient in comparison to AAV-encoded ZFNs.
nec-mRNA-mediated ZFN delivery can facilitate HDR rates comparable to AAV-encoded ZFNs.
8. Hurdles to success: Limitations to gene correction for cystic fibrosis
The lung has evolved with natural defense mechanisms against foreign pathogens. As such, a number of intracellular and extracellular barriers must be overcome in order to target new technologies to the lung [61]. In addition to this, the lungs of CF patients are even more difficult to target, owing to the increased airway mucus (sputum) lining the lungs. Especially in more progressed CF patients, thickened mucus linings have proven prohibitive in several gene replacement therapy approaches. Hida and colleagues reported that expectorated sputum from CF patients effectively traps and slows the diffusion of both Ad and AAV viral vectors [62]. For instance, where the sputum penetration of muco-inert nanoparticles is reduced by only 40-fold compared with pure water, that of Ad and AAV particles is slowed by 3,000-fold and 12,000-fold, respectively. Poor penetration of mucus layers may be a major component preventing effective viral gene replacement therapy or the use of viral vectors to deliver genome-editing components for CF.
Limits to stable expression of functional CFTR also play an important role. For gene replacement therapy approaches, this may include immune responses against the vector capsid, the inability to re-administer, as well as turnover of CFTR-expressing lung cells. For gene correction approaches, transient expression of nucleases does not destabilize the downstream effects of HDR. However, lung cell turnover continues to be an issue, making the possibility of re-administration important.
The levels of CFTR expression required to halt the progression of CF lung disease remain largely unknown, as well as the cell types most suited as targets. While airway epithelial cells are generally considered to be the ideal target, airway histology and entry receptor expression patterns may impact the ability of this cell type to be transduced. The absence of adenoviral entry receptors on the apical surface of airway epithelium, for instance, is one of the major reasons that adenoviral gene therapy vectors are no longer pursued. Furthermore, turnover of these terminally differentiated cells will eventually require therapeutics to be redelivered to new target cells.
In addition to the most relevant cell type, another question remains: is it preferable to obtain low levels of CFTR in a high percentage of cells, or high levels of CFTR in only ~10% of cells? Gene replacement and correction approaches are more likely to attain the latter, although it remains unknown whether this will be sufficient to show therapeutic effect. One recent study has shown that restoration of normal mucus transport rates in cultured CF human airway epithelial cells required at least 25% of surface epithelial cells to be targeted by CFTR gene replacement therapy [63]. Whether this figure will translate to clinical benefit in an
9. Supplemental strategies and future directions
Due to the limitations of targeting the lung, it remains unclear whether novel replacement and correction approaches will find success for Cystic Fibrosis lung disease. Efforts to overcome these barriers remain the subject of further investigation.
As one recent study demonstrated, combining nec-mRNA with chitosan-coated poly(lactide-co-glycolide) nanoparticles may be one viable method for overcoming the CF sputum barrier to lung cell targeting [37,64]. Recent progress in the development of mucus penetrating nanoparticles (MPP) may provide an opportunity to further overcome this barrier [65]. Drug-loaded MPPs with non-adhesive coatings have been shown to penetrate mucus layers at rates nearly as fast as pure water. These developments may allow the penetration of delivery vehicles to airway epithelium, without reducing the protective function of the mucus itself. Furthermore, adjuvant regimens of N-acetylcysteine (NAC) with or without recombinant human DNase (rhDNase) were used to increase diffusivity of nanocomplexed, non-viral gene delivery vectors through sputum layers [66]. This strategy was able to increase gene expression by ~12-fold, making it another potential avenue for improving targeting in the lungs of CF patients. Complexes of pDNA or mRNA with GL67:DOPE:DMPE-PEG5000 (GL67) liposomes have also been described as a potential avenue for augmenting non-viral respiratory gene transfer [67]. Overall, developments in nanoparticle technology combined with advancements in aerosol-delivery devices may hold promise for the field.
Route of administration may be an important consideration as well, especially given the tendency for inhaled therapeutics to be entrapped in the mucus layer. Intratracheal high-pressure spraying approaches have been effective in targeting airway epithelial cells in pre-clinical models [30,31,37], although efficiency is likely to decrease in the face of CF sputum. Preliminary evidence supports the claim that intravenous routes of administration may also target airway cells efficiently, while avoiding the barriers to a direct airway approach.
The continued development of humanized animal models of CF, including mouse, pig, and ferret models, will further our ability to investigate novel therapeutic strategies [68,69]. An early mouse model,
In addition to the development of novel animal models, the identification of human lung stem cell populations has offered new hope for overcoming the issue of lung cell turnover [73]. If genome-editing vehicles could be efficiently targeted to lung stem cell populations, such as bronchioalveolar stem cells (BASCs) [74], Clara cells [75], or alveolar type II (ATII) progenitors [76], HDR in these self-renewing populations could support indefinite CFTR production.
Engineering strategies to minimize the risk of off-target cleavage and donor integration will also continue to be an important area of development. Along these lines, it will be critical to more thoroughly define standardized parameters for measuring off-target effects. State-of-the-art techniques that can be used for measuring outcome parameters will also aid in assessing overall efficacy. Combining efforts to overcome these barriers to lung targeting, cell turnover, proper animal models, and off-target effects will enable the field to make continued progress toward a novel gene correction strategy for the treatment of Cystic Fibrosis.
10. Conclusion
Over two decades since the cloning of the CFTR gene, numerous strategies have been investigated to identify clinically relevant genetic variants, target cells of the airway, and overcome deleterious mutations. Rather than masking symptoms of the disease, novel therapies strive to address the underlying genetic cause of the Cystic Fibrosis phenotype. Agents have approached this goal with varying strategies, including attempts to overcome the patient’s functional CFTR defects, supplement their cells with a functional copy of the protein, or directly repair genomic mutations at their source. Innovations in viral and non-viral delivery vehicles and methods for overcoming barriers to lung targeting have allowed for promising progress in recent years. Coupled with novel genome-editing reagents, such as ZFNs, TALENs, and the CRISPR/Cas9 system, the promise of a novel therapeutic approach is becoming an increasingly attainable goal within the field. Further advancement in minimizing off-target activity, increasing the efficiency of site-specific cleavage, and optimizing robust, transient, non-integrating nuclease delivery vehicles will bring us closer to achieving stable modification of the genome in the race toward
References
- 1.
Tobias ES, Connor M, Ferguson-Smith M. Essential Medical Genetics. John Wiley & Sons; 2011. - 2.
WHO | Genes and human disease. WHO. n.d. http://www.who.int/genomics/public/geneticdiseases/en/index2.html (accessed February 16, 2015). - 3.
O’Sullivan BP, Freedman SD. Cystic fibrosis. Lancet. 2009;373:1891–904. DOI:10.1016/S0140-6736(09)60327–5. - 4.
Stutts MJ, Canessa CM, Olsen JC, Hamrick M, Cohn JA, Rossier BC, et al. CFTR as a cAMP-dependent regulator of sodium channels. Science. 1995;269:847–50. - 5.
Mall M, Hipper A, Greger R, Kunzelmann K. Wild type but not deltaF508 CFTR inhibits Na+ conductance when coexpressed in Xenopus oocytes. FEBS Letters. 1996;381:47–52. - 6.
Matsui H, Grubb BR, Tarran R, Randell SH, Gatzy JT, Davis CW, et al. Evidence for periciliary liquid layer depletion, not abnormal ion composition, in the pathogenesis of cystic fibrosis airways disease. Cell. 1998;95:1005–15. - 7.
Bobadilla JL, Macek M, Fine JP, Farrell PM. Cystic fibrosis: a worldwide analysis of CFTR mutations--correlation with incidence data and application to screening. Human Mutation. 2002;19:575–606. DOI:10.1002/humu.10041. - 8.
Rowe SM, Miller S, Sorscher EJ. Cystic fibrosis. The New England Journal of Medicine. 2005;352:1992–2001. DOI:10.1056/NEJMra043184. - 9.
Drumm ML, Konstan MW, Schluchter MD, Handler A, Pace R, Zou F, et al. Genetic modifiers of lung disease in cystic fibrosis. The New England Journal of Medicine. 2005;353:1443–53. DOI:10.1056/NEJMoa051469. - 10.
Gu Y, Harley ITW, Henderson LB, Aronow BJ, Vietor I, Huber LA, et al. Identification of IFRD1 as a modifier gene for cystic fibrosis lung disease. Nature. 2009;458:1039–42. DOI:10.1038/nature07811. - 11.
Hector A, Kormann M, Kammermeier J, Burdi S, Marcos V, Rieber N, et al. Expression and regulation of interferon-related development regulator-1 in cystic fibrosis neutrophils. American Journal of Respiratory Cell and Molecular Biology. 2013;48:71–7. DOI:10.1165/rcmb.2012-0061OC. - 12.
Anderson P. Emerging therapies in cystic fibrosis. Therapeutic Advances in Respiratory Disease. 2010;4:177–85. DOI:10.1177/1753465810371107. - 13.
Rogan MP, Stoltz DA, Hornick DB. Cystic fibrosis transmembrane conductance regulator intracellular processing, trafficking, and opportunities for mutation-specific treatment. Chest. 2011;139:1480–90. DOI:10.1378/chest.10-2077. - 14.
Boyle MP, Bell SC, Konstan MW, McColley SA, Rowe SM, Rietschel E, et al. A CFTR corrector (lumacaftor) and a CFTR potentiator (ivacaftor) for treatment of patients with cystic fibrosis who have a phe508del CFTR mutation: a phase 2 randomised controlled trial. The Lancet Respiratory Medicine. 2014;2:527–38. DOI:10.1016/S2213-2600(14)70132–8. - 15.
Kerem E, Konstan MW, De Boeck K, Accurso FJ, Sermet-Gaudelus I, Wilschanski M, et al. Ataluren for the treatment of nonsense-mutation cystic fibrosis: a randomised, double-blind, placebo-controlled phase 3 trial. The Lancet Respiratory Medicine. 2014;2:539–47. DOI:10.1016/S2213-2600(14)70100-6. - 16.
Griesenbach U, Alton EWFW. Moving forward: cystic fibrosis gene therapy. Human Molecular Genetics. 2013;22:R52–8. DOI:10.1093/hmg/ddt372. - 17.
Zhou R, Norton JE, Zhang N, Dean DA. Electroporation-mediated transfer of plasmids to the lung results in reduced TLR9 signaling and inflammation. Gene Therapy. 2007;14:775–80. DOI:10.1038/sj.gt.3302936. - 18.
Gao G, Vandenberghe LH, Wilson JM. New recombinant serotypes of AAV vectors. Current Gene Therapy. 2005;5:285–97. - 19.
Limberis MP, Vandenberghe LH, Zhang L, Pickles RJ, Wilson JM. Transduction efficiencies of novel AAV vectors in mouse airway epithelium in vivo and human ciliated airway epithelium in vitro. Molecular Therapy: The Journal of the American Society of Gene Therapy. 2009;17:294–301. DOI:10.1038/mt.2008.261. - 20.
Faust SM, Bell P, Cutler BJ, Ashley SN, Zhu Y, Rabinowitz JE, et al. CpG-depleted adeno-associated virus vectors evade immune detection. The Journal of Clinical Investigation. 2013;123:2994–3001. DOI:10.1172/JCI68205. - 21.
Mays LE, Wang L, Tenney R, Bell P, Nam H-J, Lin J, et al. Mapping the structural determinants responsible for enhanced T cell activation to the immunogenic adeno-associated virus capsid from isolate rhesus 32.33. Journal of Virology. 2013;87:9473–85. DOI:10.1128/JVI.00596-13. - 22.
Liu X, Luo M, Guo C, Yan Z, Wang Y, Lei-Butters DCM, et al. Analysis of adeno-associated virus progenitor cell transduction in mouse lung. Molecular Therapy: The Journal of the American Society of Gene Therapy. 2009;17:285–93. DOI:10.1038/mt.2008.248. - 23.
Mitomo K, Griesenbach U, Inoue M, Somerton L, Meng C, Akiba E, et al. Toward gene therapy for cystic fibrosis using a lentivirus pseudotyped with Sendai virus envelopes. Molecular Therapy: The Journal of the American Society of Gene Therapy. 2010;18:1173–82. DOI:10.1038/mt.2010.13. - 24.
Hacein-Bey-Abina S, von Kalle C, Schmidt M, Le Deist F, Wulffraat N, McIntyre E, et al. A serious adverse event after successful gene therapy for X-linked severe combined immunodeficiency. The New England Journal of Medicine. 2003;348:255–6. DOI:10.1056/NEJM200301163480314. - 25.
Hacein-Bey-Abina S, Von Kalle C, Schmidt M, McCormack MP, Wulffraat N, Leboulch P, et al. LMO2-associated clonal T cell proliferation in two patients after gene therapy for SCID-X1. Science. 2003;302:415–9. DOI:10.1126/science.1088547. - 26.
Lorenz C, Fotin-Mleczek M, Roth G, Becker C, Dam TC, Verdurmen WPR, et al. Protein expression from exogenous mRNA: uptake by receptor-mediated endocytosis and trafficking via the lysosomal pathway. RNA Biology. 2011;8:627–36. DOI:10.4161/rna.8.4.15394. - 27.
Kariko K, Muramatsu H, Ludwig J, Weissman D. Generating the optimal mRNA for therapy: HPLC purification eliminates immune activation and improves translation of nucleoside-modified, protein-encoding mRNA. Nucleic Acids Research. 2011;39:e142. DOI:10.1093/nar/gkr695. - 28.
Kariko K, Muramatsu H, Welsh FA, Ludwig J, Kato H, Akira S, et al. Incorporation of pseudouridine into mRNA yields superior nonimmunogenic vector with increased translational capacity and biological stability. Molecular Therapy. 2008;16:1833–40. DOI:10.1038/mt.2008.200. - 29.
Kariko K, Muramatsu H, Keller JM, Weissman D. Increased erythropoiesis in mice injected with submicrogram quantities of pseudouridine-containing mRNA encoding erythropoietin. Molecular Therapy. 2012;20:948–53. DOI:10.1038/mt.2012.7. - 30.
Kormann MS, Hasenpusch G, Aneja MK, Nica G, Flemmer AW, Herber-Jonat S, et al. Expression of therapeutic proteins after delivery of chemically modified mRNA in mice. Nature Biotechnology. 2011;29:154–7. DOI:10.1038/nbt.1733. - 31.
Mays LE, Ammon-Treiber S, Mothes B, Alkhaled M, Rottenberger J, Muller-Hermelink ES, et al. Modified Foxp3 mRNA protects against asthma through an IL-10-dependent mechanism. The Journal of Clinical Investigation. 2013;123:1216–28. DOI:10.1172/JCI65351. - 32.
Perez EE, Wang J, Miller JC, Jouvenot Y, Kim KA, Liu O, et al. Establishment of HIV-1 resistance in CD4+ T cells by genome editing using zinc-finger nucleases. Nature Biotechnology. 2008;26:808–16. DOI:10.1038/nbt1410. - 33.
Mali P, Yang L, Esvelt KM, Aach J, Guell M, DiCarlo JE, et al. RNA-guided human genome engineering via Cas9. Science. 2013;339:823–6. DOI:10.1126/science.1232033. - 34.
Cong L, Ran FA, Cox D, Lin S, Barretto R, Habib N, et al. Multiplex genome engineering using CRISPR/Cas systems. Science. 2013;339:819–23. DOI:10.1126/science.1231143. - 35.
Cox DBT, Platt RJ, Zhang F. Therapeutic genome editing: prospects and challenges. Nature Medicine. 2015;21:121–31. DOI:10.1038/nm.3793. - 36.
Li H, Haurigot V, Doyon Y, Li T, Wong SY, Bhagwat AS, et al. In vivo genome editing restores haemostasis in a mouse model of haemophilia. Nature. 2011;475:217–21. DOI:10.1038/nature10177. - 37.
Dewerth A, Mays L, Mahiny A, et al. In vivo genome editing using nuclease-encoding mRNA corrects SP-B deficiency. Nature Biotechnology. 2015. Manuscript accepted. - 38.
Segal DJ. Bacteria herald a new era of gene editing. eLife. 2013;2:e00563. DOI:10.7554/eLife.00563. - 39.
Urnov FD, Rebar EJ, Holmes MC, Zhang HS, Gregory PD. Genome editing with engineered zinc finger nucleases. Nature Reviews Genetics. 2010;11:636–46. DOI:10.1038/nrg2842. - 40.
Doyon Y, Vo TD, Mendel MC, Greenberg SG, Wang J, Xia DF, et al. Enhancing zinc-finger-nuclease activity with improved obligate heterodimeric architectures. Nature Methods. 2011;8:74–9. DOI:10.1038/nmeth.1539. - 41.
Szczepek M, Brondani V, Büchel J, Serrano L, Segal DJ, Cathomen T. Structure-based redesign of the dimerization interface reduces the toxicity of zinc-finger nucleases. Nature Biotechnology. 2007;25:786–93. DOI:10.1038/nbt1317. - 42.
Guo J, Gaj T, Barbas CF. Directed evolution of an enhanced and highly efficient FokI cleavage domain for zinc finger nucleases. Journal of Molecular Biology. 2010;400:96–107. DOI:10.1016/j.jmb.2010.04.060. - 43.
Didigu CA, Wilen CB, Wang J, Duong J, Secreto AJ, Danet-Desnoyers GA, et al. Simultaneous zinc-finger nuclease editing of the HIV coreceptors ccr5 and cxcr4 protects CD4+ T cells from HIV-1 infection. Blood. 2014;123:61–9. DOI:10.1182/blood-2013-08-521229. - 44.
Rusk N. TALEs for the masses. Nature Methods. 2011;8:197. - 45.
Miller JC, Tan S, Qiao G, Barlow KA, Wang J, Xia DF, et al. A TALE nuclease architecture for efficient genome editing. Nature Biotechnology. 2011;29:143–8. DOI:10.1038/nbt.1755. - 46.
Boch J. TALEs of genome targeting. Nature Biotechnology. 2011;29:135–6. DOI:10.1038/nbt.1767. - 47.
Zhang F, Cong L, Lodato S, Kosuri S, Church GM, Arlotta P. Efficient construction of sequence-specific TAL effectors for modulating mammalian transcription. Nature Biotechnology. 2011;29:149–53. DOI:10.1038/nbt.1775. - 48.
Mussolino C, Cathomen T. TALE nucleases: tailored genome engineering made easy. Current Opinion in Biotechnology. 2012;23:644–50. DOI:10.1016/j.copbio.2012.01.013. - 49.
Bedell VM, Wang Y, Campbell JM, Poshusta TL, Starker CG, Krug RG, et al. In vivo genome editing using a high-efficiency TALEN system. Nature. 2012;491:114–8. DOI:10.1038/nature11537. - 50.
Reyon D, Tsai SQ, Khayter C, Foden JA, Sander JD, Joung JK. FLASH assembly of TALENs for high-throughput genome editing. Nature Biotechnology. 2012;30:460–5. DOI:10.1038/nbt.2170. - 51.
Jinek M, Chylinski K, Fonfara I, Hauer M, Doudna JA, Charpentier E. A programmable dual-RNA-guided DNA endonuclease in adaptive bacterial immunity. Science (New York, NY). 2012;337:816–21. DOI:10.1126/science.1225829. - 52.
Jinek M, East A, Cheng A, Lin S, Ma E, Doudna J. RNA-programmed genome editing in human cells. eLife. 2013;2:e00471. DOI:10.7554/eLife.00471. - 53.
Cho SW, Kim S, Kim JM, Kim J-S. Targeted genome engineering in human cells with the Cas9 RNA-guided endonuclease. Nature Biotechnology. 2013;31:230–2. DOI:10.1038/nbt.2507. - 54.
Hwang WY, Fu Y, Reyon D, Maeder ML, Tsai SQ, Sander JD, et al. Efficient genome editing in zebrafish using a CRISPR-Cas system. Nature Biotechnology. 2013;31:227–9. DOI:10.1038/nbt.2501. - 55.
Barrangou R. RNA-mediated programmable DNA cleavage. Nature Biotechnology. 2012;30:836–8. DOI:10.1038/nbt.2357. - 56.
Lin Y, Cradick TJ, Brown MT, Deshmukh H, Ranjan P, Sarode N, et al. CRISPR/Cas9 systems have off-target activity with insertions or deletions between target DNA and guide RNA sequences. Nucleic Acids Research. 2014;42:7473–85. DOI:10.1093/nar/gku402. - 57.
Tsai SQ, Wyvekens N, Khayter C, Foden JA, Thapar V, Reyon D, et al. Dimeric CRISPR RNA-guided FokI nucleases for highly specific genome editing. Nature Biotechnology. 2014;32:569–76. DOI:10.1038/nbt.2908. - 58.
Schultze N, Burki Y, Lang Y, Certa U, Bluethmann H. Efficient control of gene expression by single step integration of the tetracycline system in transgenic mice. Nature Biotechnology. 1996;14:499–503. DOI:10.1038/nbt0496-499. - 59.
Nogee LM. Alterations in SP-B and SP-C expression in neonatal lung disease. The Annual Review of Physiology. 2004;66:601–23. DOI:10.1146/annurev.physiol.66.032102.134711. - 60.
Clark JC, Wert SE, Bachurski CJ, Stahlman MT, Stripp BR, Weaver TE, et al. Targeted disruption of the surfactant protein B gene disrupts surfactant homeostasis, causing respiratory failure in newborn mice. Proceedings of the National Academy of Sciences of the United States of America. 1995;92:7794–8. - 61.
Ruge CA, Kirch J, Lehr C-M. Pulmonary drug delivery: from generating aerosols to overcoming biological barriers-therapeutic possibilities and technological challenges. The Lancet Respiratory Medicine. 2013;1:402–13. DOI:10.1016/S2213-2600(13)70072–9. - 62.
Hida K, Lai SK, Suk JS, Won SY, Boyle MP, Hanes J. Common gene therapy viral vectors do not efficiently penetrate sputum from cystic fibrosis patients. PloS One. 2011;6:e19919. DOI:10.1371/journal.pone.0019919. - 63.
Zhang L, Button B, Gabriel SE, Burkett S, Yan Y, Skiadopoulos MH, et al. CFTR delivery to 25% of surface epithelial cells restores normal rates of mucus transport to human cystic fibrosis airway epithelium. PLoS Biology. 2009;7:e1000155. DOI:10.1371/journal.pbio.1000155. - 64.
Nafee N, Taetz S, Schneider M, Schaefer UF, Lehr CM. Chitosan-coated PLGA nanoparticles for DNA/RNA delivery: effect of the formulation parameters on complexation and transfection of antisense oligonucleotides. Nanomedicine: Nanotechnology, Biology, and Medicine. 2007;3:173–83. DOI:10.1016/j.nano.2007.03.006. - 65.
Ensign LM, Schneider C, Suk JS, Cone R, Hanes J. Mucus penetrating nanoparticles: biophysical tool and method of drug and gene delivery. Advanced Materials (Deerfield Beach, FL). 2012;24:3887–94. - 66.
Suk JS, Boylan NJ, Trehan K, Tang BC, Schneider CS, Lin J-MG, et al. N-acetylcysteine enhances cystic fibrosis sputum penetration and airway gene transfer by highly compacted DNA nanoparticles. Molecular Therapy: The Journal of the American Society of Gene Therapy. 2011;19:1981–9. DOI:10.1038/mt.2011.160. - 67.
Andries O, De Filette M, Rejman J, De Smedt SC, Demeester J, Van Poucke M, et al. Comparison of the gene transfer efficiency of mRNA/GL67 and pDNA/GL67 complexes in respiratory cells. Molecular Pharmaceutics. 2012;9:2136–45. DOI:10.1021/mp200604h. - 68.
Yan Z, Stewart ZA, Sinn PL, Olsen JC, Hu J, McCray PB, et al. Ferret and pig models of cystic fibrosis: prospects and promise for gene therapy. Human Gene Therapy Clinical Development. 2015. DOI:10.1089/humc.2014.154. - 69.
Olivier AK, Gibson-Corley KN, Meyerholz DK. Animal models of cystic fibrosis: gastrointestinal, pancreatic and hepatobiliary disease and pathophysiology. American Journal of Physiology Gastrointestinal and Liver Physiology. 2015:ajpgi.00146.2014. DOI:10.1152/ajpgi.00146.2014. - 70.
Snouwaert JN, Brigman KK, Latour AM, Malouf NN, Boucher RC, Smithies O, et al. An animal model for cystic fibrosis made by gene targeting. Science (New York, NY). 1992;257:1083–8. - 71.
Clarke LL, Grubb BR, Gabriel SE, Smithies O, Koller BH, Boucher RC. Defective epithelial chloride transport in a gene-targeted mouse model of cystic fibrosis. Science (New York, NY). 1992;257:1125–8. - 72.
Zhou L, Dey CR, Wert SE, DuVall MD, Frizzell RA, Whitsett JA. Correction of lethal intestinal defect in a mouse model of cystic fibrosis by human CFTR. Science (New York, NY). 1994;266:1705–8. - 73.
Kajstura J, Rota M, Hall SR, Hosoda T, D’Amario D, Sanada F, et al. Evidence for human lung stem cells. The New England Journal of Medicine. 2011;364:1795–806. DOI:10.1056/NEJMoa1101324. - 74.
Kim CFB, Jackson EL, Woolfenden AE, Lawrence S, Babar I, Vogel S, et al. Identification of bronchioalveolar stem cells in normal lung and lung cancer. Cell. 2005;121:823–35. DOI:10.1016/j.cell.2005.03.032. - 75.
Hong KU, Reynolds SD, Giangreco A, Hurley CM, Stripp BR. Clara cell secretory protein-expressing cells of the airway neuroepithelial body microenvironment include a label-retaining subset and are critical for epithelial renewal after progenitor cell depletion. American Journal of Respiratory Cell and Molecular Biology. 2001;24:671–81. DOI:10.1165/ajrcmb.24.6.4498. - 76.
Fujino N, Kubo H, Suzuki T, Ota C, Hegab AE, He M, et al. Isolation of alveolar epithelial type II progenitor cells from adult human lungs. Laboratory Investigation; a Journal of Technical Methods and Pathology. 2011;91:363–78. DOI:10.1038/labinvest.2010.187.