Comparative Analysis of DNA Nanoparticles and AAVs for Ocular Gene Delivery

Gene therapy is a critical tool for the treatment of monogenic retinal diseases. However, the limited vector capacity of the current benchmark delivery strategy, adeno-associated virus (AAV), makes development of larger capacity alternatives, such as compacted DNA nanoparticles (NPs), critical. Here we conduct a side-by-side comparison of self-complementary AAV and CK30PEG NPs using matched ITR plasmids. We report that although AAVs are more efficient per vector genome (vg) than NPs, NPs can drive gene expression on a comparable scale and longevity to AAV. We show that subretinally injected NPs do not leave the eye while some of the AAV-injected animals exhibited vector DNA and GFP expression in the visual pathways of the brain from PI-60 onward. As a result, these NPs have the potential to become a successful alternative for ocular gene therapy, especially for the multitude of genes too large for AAV vectors.     

AAV-mediated gene therapy in mouse models of recessive retinal degeneration

In recent years, more and more mutant genes that cause retinal diseases have been detected. At the same time, many naturally occurring mouse models of retinal degeneration have also been found, which show similar changes to human retinal diseases. These, together with improved viral vector quality allow more and more traditionally incurable inherited retinal disorders to become potential candidates for gene therapy. Currently, the most common vehicle to deliver the therapeutic gene into target retinal cells is the adenoassociated viral vector (AAV). Following delivery to the immuno-privileged subretinal space, AAV-vectors can efficiently target both retinal pigment epithelium and photoreceptor cells, the origin of most retinal degenerations. This review focuses on the AAV-based gene therapy in mouse models of recessive retinal degenerations, especially those in which delivery of the correct copy of the wild-type gene has led to significant beneficial effects on visual function, as determined by morphological, biochemical, electroretinographic and behavioral analysis. The past studies in animal models and ongoing successful LCA2 clinical trials, predict a bright future for AAV gene replacement treatment for inherited recessive retinal diseases.     

Adeno-associated virus vectors for gene transfer to the brain

Gene therapy is a novel method under investigation for the treatment of neurological disorders. Considerable interest has focused on the possibility of using viral vectors to deliver genes to the central nervous system. Adeno-associated virus (AAV) is a potentially useful gene transfer vehicle for neurologic gene therapies. The advantages of AAV vector include the lack of any associated disease with a wild-type virus, the ability to transduce nondividing cells, the possible integration of the gene into the host genome, and the long-term expression of transgenes. The development of novel therapeutic strategies for neurological disorder by using AAV vector has an increasing impact on gene therapy research. This article describes methods that can be used to generate rodent and nonhuman primate models for testing treatment strategies linked to pathophysiological events in the ischemic brain and neurodegenerative disorders such as Parkinson's disease.     

Controlled release of adeno-associated virus from alginate hydrogel microbeads with enhanced sensitivity to ultrasound

Adeno-associated virus (AAV)-based gene therapy holds promise as a fundamental treatment for genetic disorders. For clinical applications, it is necessary to control AAV release timing to avoid an immune response to AAV. Here we propose an ultrasound (US)-triggered on-demand AAV release system using alginate hydrogel microbeads (AHMs) with a release enhancer. By using a centrifuge-based microdroplet shooting device, the AHMs encapsulating AAV with tungsten microparticles (W-MPs) are fabricated. Since W-MPs work as release enhancers, the AHMs have high sensitivity to the US with localized variation in acoustic impedance for improving the release of AAV. Furthermore, AHMs were coated with poly-l -lysine (PLL) to adjust the release of AAV. By applying US to the AAV encapsulating AHMs with W-MPs, the AAV was released on demand, and gene transfection to cells by AAV was confirmed without loss of AAV activity. This proposed US-triggered AAV release system expands methodological possibilities in gene therapy.     

Adeno-associated virus-mediated gene delivery approaches for the treatment of CNS disorders

Over the last few years, a large number of preclinical and clinical studies have demonstrated the potential of gene therapy applications using adeno-associated viral (AAV) vectors. Gene transfer via AAV vectors has been particularly successful for the treatment or adjunct therapy of several CNS disorders. The present review summarizes the progress on AAV gene delivery models for three different CNS disorders. In particular, we discuss advances in AAV-mediated gene transfer strategies in animal models of Parkinson's disease, Alzheimer's disease and spinal cord trauma and summarize the results from the first clinical studies using AAV systems.     

Therapeutic in vivo gene transfer for genetic disease using AAV: progress and challenges

In vivo gene replacement for the treatment of inherited disease is one of the most compelling concepts in modern medicine. Adeno-associated virus (AAV) vectors have been extensively used for this purpose and have shown therapeutic efficacy in a range of animal models. Successful translation to the clinic was initially slow, but long-term expression of donated genes at therapeutic levels has now been achieved in patients with inherited retinal disorders and haemophilia B. Recent exciting results have raised hopes for the treatment of many other diseases. As we discuss here, the prospects and challenges for AAV gene therapy are to a large extent dependent on the target tissue and the specific disease.     

Developing protocols for recombinant adeno-associated virus-mediated gene therapy in space

With the advent of the era of International Space Station (ISS) and Mars exploration, it is important more than ever to develop means to cure genetic and acquired diseases, which include cancer and AIDS, for these diseases hamper human activities. Thus, our ultimate goal is to develop protocols for gene therapy, which are suitable to humans on the earth as well as in space. Specifically, we are trying to cure the hemoglobinopathies, beta-thalassemia (Cooley's anemia) and sickle cell anemia, by gene therapy. These well-characterized molecular diseases serve as models for developing ex vivo gene therapy, which would apply to other disorders as well. For example, the procedure may become directly relevant to treating astronauts for space-anemia, immune suppression and bone marrow derived tumors, e.g. leukemia. The adeno-associated virus serotype 2 (AAV2) is a non-pathogenic human parvovirus with broad host-range and tissue specificity. Exploiting these characteristics we have been developing protocols for recombinant AAV2 (rAAV)-based gene therapy. With the rAAV constructs and hematopoietic stem cell (HSC) culture systems in hand, we are currently attempting to cure the mouse model of beta-thalassemia [C57BL/6- Hbbth/Hbbth, Hb(d-minor)] by HSC transplantation (HST) as well as by gene therapy. This paper describes the current status of our rAAV-gene therapy research.     

Efficacious and safe tissue-selective controlled gene therapy approaches for the cornea

Untargeted and uncontrolled gene delivery is a major cause of gene therapy failure. This study aimed to define efficient and safe tissue-selective targeted gene therapy approaches for delivering genes into keratocytes of the cornea in vivo using a normal or diseased rabbit model. New Zealand White rabbits, adeno-associated virus serotype 5 (AAV5), and a minimally invasive hair-dryer based vector-delivery technique were used. Fifty microliters of AAV5 titer (6.5×10(12) vg/ml) expressing green fluorescent protein gene (GFP) was topically applied onto normal or diseased (fibrotic or neovascularized) rabbit corneas for 2-minutes with a custom vector-delivery technique. Corneal fibrosis and neovascularization in rabbit eyes were induced with photorefractive keratectomy using excimer laser and VEGF (630 ng) using micropocket assay, respectively. Slit-lamp biomicroscopy and immunocytochemistry were used to confirm fibrosis and neovascularization in rabbit corneas. The levels, location and duration of delivered-GFP gene expression in the rabbit stroma were measured with immunocytochemistry and/or western blotting. Slot-blot measured delivered-GFP gene copy number. Confocal microscopy performed in whole-mounts of cornea and thick corneal sections determined geometric and spatial localization of delivered-GFP in three-dimensional arrangement. AAV5 toxicity and safety were evaluated with clinical eye exam, stereomicroscopy, slit-lamp biomicroscopy, and H&E staining. A single 2-minute AAV5 topical application via custom delivery-technique efficiently and selectively transduced keratocytes in the anterior stroma of normal and diseased rabbit corneas as evident from immunocytochemistry and confocal microscopy. Transgene expression was first detected at day 3, peaked at day 7, and was maintained up to 16 weeks (longest tested time point). Clinical and slit-lamp eye examination in live rabbits and H&E staining did not reveal any significant changes between AAV5-treated and untreated control corneas. These findings suggest that defined gene therapy approaches are safe for delivering genes into keratocytes in vivo and has potential for treating corneal disorders in human patients.     

Corneal transduction by intra-stromal injection of AAV vectors in vivo in the mouse and ex vivo in human explants

The cornea is a transparent, avascular tissue that acts as the major refractive surface of the eye. Corneal transparency, assured by the inner stroma, is vital for this role. Disruption in stromal transparency can occur in some inherited or acquired diseases. As a consequence, light entering the eye is blocked or distorted, leading to decreased visual acuity. Possible treatment for restoring transparency could be via viral-based gene therapy. The stroma is particularly amenable to this strategy due to its immunoprivileged nature and low turnover rate. We assayed the potential of AAV vectors to transduce keratocytes following intra-stromal injection in vivo in the mouse cornea and ex vivo in human explants. In murine and human corneas, we transduced the entire stroma using a single injection, preferentially targeted keratocytes and achieved long-term gene transfer (up to 17 months in vivo in mice). Of the serotypes tested, AAV2/8 was the most promising for gene transfer in both mouse and man. Furthermore, transgene expression could be transiently increased following aggression to the cornea.     

Gene therapy using AAV

AAV (adeno-associated virus) vectors are considered to be promising gene-delivery vehicles for gene therapy, because they are derived from non-pathogenic virus, efficiently transduce non-dividing cells, and cause long-term gene expression. Appropriate AAV serotypes are utilized depending on the type of target cells. Among various neurological disorders, Parkinson's disease (PD) is one of the most promising candidates of gene therapy. PD is a progressive neurodegenerative disorder that predominantly affects dopaminergic neurons in the substantia nigra. One of the major approaches to gene therapy of PD is the intrastriatal expression of dopamine (DA)-synthesizing enzyme genes. As for the initial step of clinical application, AAV vector-mediated AADC (aromatic L-amino acid decarboxylase; the enzyme converting L-DOPA to DA) gene transfer in combination with oral administration of L-DOPA would be appropriate, since DA production can be regulated by adjusting the dose of L-DOPA. Second, intramuscular injection of AAV vectors is appropriate to protein-supplement gene therapy. Monogenic diseases such as hemophilia and Fabry disease are suitable candidates. Regarding cancer gene therapy, AAV vectors may be utilized to inhibit tumor angiogenesis, metastasis, and invasion. When long-term transgene expression in stem cells is needed, a therapeutic gene should be introduced with a minimal risk of insertional mutagenesis. To this end, site-specific integration into the AAVS1 locus on the chromosome 19 (19q13.4) by using the integration machinery of AAV would be particularly valuable.     

Enhanced genome editing to ameliorate a genetic metabolic liver disease through co-delivery of adeno-associated virus receptor

Science China Life Sciences - Genome editing through adeno-associated viral (AAV) vectors is a promising gene therapy strategy for various diseases, especially genetic disorders. However,...     

High-level transgene expression in nonhuman primate liver with novel adeno-associated virus serotypes containing self-complementary genomes

Adeno-associated virus (AAV) vectors are being considered for in vivo applications of gene therapy in the treatment of a variety of disorders. This study evaluates the biology of second-generation vectors based on the novel serotypes AAV7 and AAV8 and containing self-complementary genomes in the nonhuman primate liver. Stable levels of transgene expression were achieved in cynomolgus macaques and suggest efficiencies at least 2 log higher than what could be achieved with AAV2 vectors using traditional single-stranded genomes. Analysis of DNAs from tissues revealed high levels of vector in the liver that appeared proportional to the relative amounts of transgene expression.     

Novel AAV serotypes for improved ocular gene transfer

Some of the most successful gene therapy results have been obtained using recombinant viral vectors to treat animal models of inherited and acquired ocular diseases. Clinical trials using adenovirus vector systems have been initiated for two ocular diseases. Adeno-associated viruses (AAVs) represent an attractive alternative to adenoviral vector systems as they enable stable and long-term expression and can target a variety of different ocular cell types depending on the capsid serotype; recently clinical trails for congenital blindness was initiated with a vector-based AAV serotype 2. High levels of retinal gene transfer have been achieved using vectors based on AAV serotypes 1, 2, 4 and 5. This report compares the gene transfer efficacy and stability of expression of vector systems based on three novel AAV serotypes: AAV7, 8, 9, with the established vectors AAV1, 2, 5. We show here that AAV7 and 8 enable superior long-term transduction of retinal and also anterior chamber structures.     

Treatment of human disease by adeno-associated viral gene transfer

During the past decade, in vivo administration of viral gene transfer vectors for treatment of numerous human diseases has been brought from bench to bedside in the form of clinical trials, mostly aimed at establishing the safety of the protocol. In preclinical studies in animal models of human disease, adeno-associated viral (AAV) vectors have emerged as a favored gene transfer system for this approach. These vectors are derived from a replication-deficient, non-pathogenic parvovirus with a single-stranded DNA genome. Efficient gene transfer to numerous target cells and tissues has been described. AAV is particularly efficient in transduction of non-dividing cells, and the vector genome persists predominantly in episomal forms. Substantial correction, and in some instances complete cure, of genetic disease has been obtained in animal models of hemophilia, lysosomal storage disorders, retinal diseases, disorders of the central nervous system, and other diseases. Therapeutic expression often lasted for months to years. Treatments of genetic disorders, cancer, and other acquired diseases are summarized in this review. Vector development, results in animals, early clinical experience, as well as potential hurdles and challenges are discussed.     

Dawn of ocular gene therapy: implications for molecular diagnosis in retinal disease

Personalized medicine aims to utilize genomic information about patients to tailor treatment. Gene replacement therapy for rare genetic disorders is perhaps the most extreme form of personalized medicine, in that the patients’ genome wholly determines their treatment regimen. Gene therapy for retinal disorders is poised to become a clinical reality. The eye is an optimal site for gene therapy due to the relative ease of precise vector delivery, immune system isolation, and availability for monitoring of any potential damage or side effects. Due to these advantages, clinical trials for gene therapy of retinal diseases are currently underway. A necessary precursor to such gene therapies is accurate molecular diagnosis of the mutation(s) underlying disease. In this review, we discuss the application of Next Generation Sequencing (NGS) to obtain such a diagnosis and identify disease causing genes, using retinal disorders as a case study. After reviewing ocular gene therapy, we discuss the application of NGS to the identification of novel Mendelian disease genes. We then compare current, array based mutation detection methods against next NGS-based methods in three retinal diseases: Leber’s Congenital Amaurosis, Retinitis Pigmentosa, and Stargardt’s disease. We conclude that next-generation sequencing based diagnosis offers several advantages over array based methods, including a higher rate of successful diagnosis and the ability to more deeply and efficiently assay a broad spectrum of mutations. However, the relative difficulty of interpreting sequence results and the development of standardized, reliable bioinformatic tools remain outstanding concerns. In this review, recent advances NGS based molecular diagnoses are discussed, as well as their implications for the development of personalized medicine.     

Retrograde axonal transport property of adeno-associated virus and its possible application in future

Gene therapy has become a treatment method for many diseases. Adeno-associated virus (AAV) is one of the most common virus vectors, is also widely used in the gene therapy field. During the past two decades, the retrograde axonal transportability of AAV has been discovered and utilized. Many studies have worked on the retrograde axonal transportability of AAV, and more and more people are interested in this field. This review describes the current application, influence factors, and mechanism of retrograde axonal transportability of AAV and predicted its potential use in disease treatment in near future.     

Adeno-associated virus-mediated gene transfer to the neonatal brain

For many metabolic diseases, early treatment is necessary to prevent irreversible developmental damage. This is particularly true for childhood diseases that affect the central nervous system (CNS). The development of effective techniques for gene transfer to the neonatal brain would provide a new set of therapeutic options for many of these disorders. Vectors based on adeno-associated virus (AAV) have shown promise as agents for neonatal CNS transduction. In preclinical animal models, a single treatment with AAV vectors at birth has been shown to produce persistent CNS expression of transduced genes into adulthood. Transduction of the neonatal brain has been accomplished by a variety of methods, including direct intraparenchymal injection, intraventricular infusion, and intravenous administration. Of these methods, intraparenchymal injection provides the highest levels of localized activity, while intraventricular infusion results in a more widespread distribution of activity when performed in the neonate. Here we describe a method for direct, intraparenchymal injection of AAV into the neonatal brain. This technique provides a method for investigators to evaluate the effects of in vivo expression of exogenous genes on the process of early brain development.     

Adeno-associated virus-mediated antiapoptotic gene delivery: in vivo gene therapy for neurological disorders

Apoptosis is an important mechanism of physiological and pathological cell death and is known to occur in various neurological disorders. Apoptosis is associated with activation of genetic programs in which apoptosis-effector genes promote cell death, thereby opposing repressor genes that enhance cell survival. In this review, we describe various apoptotic pathways, with a special reference to the caspase cascade and discuss the role of individual antiapoptotic factors in various target diseases. Apoptosis could be suppressed by in vivo gene delivery of antiapoptotic factors directly into the central nervous system. The adeno-associated virus (AAV) vector is a good candidate for such gene therapy because it can infect postmitotic neurons. We also describe our in vivo system for overexpression of apoptotic protease activating factor-1 (Apaf-1) caspase recruitment domain as an Apaf1-dominant negative inhibitor (Apaf-1-DN) to regulate the mitochondrial caspase cascade. Apaf-1-DN delivery using an AAV vector system inhibited mitochondrial apoptotic signaling pathway and prevented dopaminergic cell death in a mouse model of Parkinson's disease. Our results suggest that AAV-Apaf-1-DN is potentially useful as an antimitochondrial apoptotic gene therapy for neurodegenerative disorders such as Parkinson's disease.     

基于腺相关病毒的多手段联合肿瘤治疗策略

腺相关病毒(adeno-associated virus,AAV)本身具有抗肿瘤活性,以其为基础构建的重组腺相关病毒(rAAV)作为肿瘤基因治疗载体已应用于临床试验研究。与其他的药物一样,单一的AAV基因药物,可能无法对肿瘤这一多基因、多步骤的复杂疾病发挥有效的治疗作用。国内外实验研究发现,多种化疗药物和放疗手段,不但可以提高rAAV载体的基因表达效率,也能促进AAV病毒本身的复制;反过来,AAV可以提高肿瘤细胞对放化疗的敏感性。联合AAV与其他的肿瘤治疗策略将有助于优化肿瘤治疗效果。