Michael Lukason

Preclinical safety evaluation of AAV2-sFLT01- a gene therapy for age-related macular degeneration.

AAV2-sFLT01 is a vector that expresses a modified soluble Flt1 receptor designed to neutralize the proangiogenic activities of vascular endothelial growth factor (VEGF) for treatment of age-related macular degeneration (AMD) via an intravitreal injection. Owing to minimal data available for the intravitreal route of administration for adeno-associated virus (AAV), we initiated a 12-month safety study of AAV2-sFLT01 administered intravitreally at doses of 2.4 × 10(9) vector genomes (vg) and 2.4 × 10(10) vg to cynomolgus monkeys. Expression of sFlt01 protein peaked at ~1-month postadministration and remained relatively constant for the remainder of the study. Electroretinograms, fluorescein angiograms, and tonometry were assessed every 3 months, with no test article-related findings observed in any group. Indirect ophthalmoscopy and slit lamp exams performed monthly revealed a mild to moderate but self-resolving vitreal inflammation in the high-dose group only, which follow-up studies suggest was directed against the AAV2 capsid. Histological evaluation revealed no structural changes in any part of the eye and occasional inflammatory cells in the trabecular meshwork, vitreous and retina in the high-dose group. Biodistribution analysis in rats and monkeys found only trace amounts of vector outside the injected eye. In summary, these studies found AAV2-sFLT01 to be well-tolerated, localized, and capable of long-term expression.

Novel anti-VEGF chimeric molecules delivered by AAV vectors for inhibition of retinal neovascularization.

Vascular endothelial growth factor (VEGF) is important in pathological neovascularization, which is a key component of diseases such as the wet form of age-related macular degeneration, proliferative diabetic retinopathy and cancer. One of the most potent naturally occurring VEGF binders is VEGF receptor Flt-1. We have generated two novel chimeric VEGF-binding molecules, sFLT01 and sFLT02, which consist of the second immunoglobulin (IgG)-like domain of Flt-1 fused either to a human IgG1 Fc or solely to the CH3 domain of IgG1 Fc through a polyglycine linker 9Gly. In vitro analysis showed that these novel molecules are high-affinity VEGF binders. We have demonstrated that adeno-associated virus serotype 2 (AAV2)-mediated intravitreal gene delivery of sFLT01 efficiently inhibits angiogenesis in the mouse oxygen-induced retinopathy model. There were no histological observations of toxicity upon persistent ocular expression of sFLT01 for up to 12 months following intravitreal AAV2-based delivery in the rodent eye. Our data suggest that AAV2-mediated intravitreal gene delivery of our novel molecules may be a safe and effective treatment for retinal neovascularization.

Preexisting Immunity and Low Expression in Primates Highlight Translational Challenges for Liver-directed AAV8-mediated Gene Therapy

Liver-directed gene therapy with adeno-associated virus (AAV) vectors effectively treats mouse models of lysosomal storage diseases (LSDs). We asked whether these results were likely to translate to patients. To understand to what extent preexisting anti-AAV8 antibodies could impede AAV8-mediated liver transduction in primates, commonly preexposed to AAV, we quantified the effects of preexisting antibodies on liver transduction and subsequent transgene expression in mouse and nonhuman primate (NHP) models. Using the highest viral dose previously reported in a clinical trial, passive transfer of NHP sera containing relatively low anti-AAV8 titers into mice blocked liver transduction, which could be partially overcome by increasing vector dose tenfold. Based on this and a survey of anti-AAV8 titers in 112 humans, we predict that high-dose systemic gene therapy would successfully transduce liver in >50% of human patients. However, although high-dose AAV8 administration to mice and monkeys with equivalent anti-AAV8 titers led to comparable liver vector copy numbers, the resulting transgene expression in primates was ~1.5-logs lower than mice. This suggests vector fate differs in these species and that strategies focused solely on overcoming preexisting vector-specific antibodies may be insufficient to achieve clinically meaningful expression levels of LSD genes using a liver-directed gene therapy approach in patients.

Murine Antithymocyte Globulin Therapy Alters Disease Progression in NOD Mice by a Time-Dependent Induction of Immunoregulation

OBJECTIVE—Antilymphocyte serum can reverse overt type 1 diabetes in NOD mice; yet, the therapeutic parameters and immunological mechanisms underlying the ability for this agent to modulate autoimmune responses against β-cells are unclear, forming the rationale for this investigation. RESEARCH DESIGN AND METHODS—A form of antilymphocyte serum, rabbit anti-mouse thymocyte globulin (mATG), was utilized in a variety of in vivo and in vitro settings, each for the purpose of defining the physiological, immunological, and metabolic activities of this agent, with particular focus on actions influencing development of type 1 diabetes. RESULTS—We observed that mATG attenuates type 1 diabetes development in an age-dependent fashion, only proving efficacious at disease onset or in the late pre-diabetic phase (12 weeks of age). When provided at 12 weeks of age, mATG reversed pancreatic insulitis, improved metabolic responses to glucose challenge, and rapidly increased frequency of antigen-presenting cells in spleen and pancreatic lymph nodes. Surprisingly, mATG therapy dramatically increased, in an age-dependent fashion, the frequency and the functional activity of CD4+CD25+ regulatory T-cells. Adoptive transfer/cotransfer studies of type 1 diabetes also support the concept that mATG treatment induces a stable and transferable immunomodulatory repertoire in vivo. CONCLUSIONS—These findings indicate that an induction of immunoregulation, rather than simple lymphocyte depletion, contributes to the therapeutic efficacy of antithymocyte globulin and suggest that time-dependent windows for the ability to delay or reverse type 1 diabetes exist based on the capacity to enhance the functional activity of regulatory T-cells.

Inhibition of choroidal neovascularization in a nonhuman primate model by intravitreal administration of an AAV2 vector expressing a novel anti-VEGF molecule.

Inhibition of vascular endothelial growth factor (VEGF) for the management of the pathological ocular neovascularization associated with diseases such as neovascular age-related macular degeneration is a proven paradigm; however, monthly intravitreal injections are required for optimal treatment. We have previously shown that a novel, secreted anti-VEGF molecule sFLT01 delivered by intravitreal injection of an AAV2 vector (AAV2-sFLT01) gives persistent expression and is efficacious in a murine model of retinal neovascularization. In the present study, we investigate transduction and efficacy of an intravitreally administered AAV2-sFLT01 in a nonhuman primate (NHP) model of choroidal neovascularization (CNV). A dose-dependent and persistent expression of sFLT01 was observed by collecting samples of aqueous humor at different time points over 5 months. The location of transduction as elucidated by in situ hybridization was in the transitional epithelial cells of the pars plana and in retinal ganglion cells. AAV2-sFLT01 was able to effectively inhibit laser-induced CNV in a dose-dependent manner as determined by comparing the number of leaking CNV lesions in the treated versus control eyes using fluorescein angiography. Our data suggest that intravitreal delivery of AAV2-sFLT01 may be an effective long-term treatment for diseases caused by ocular neovascularization.

CRISPR/Cas9-Mediated Genome Editing as a Therapeutic Approach for Leber Congenital Amaurosis 10

As the most common subtype of Leber congenital amaurosis (LCA), LCA10 is a severe retinal dystrophy caused by mutations in the CEP290 gene. The most frequent mutation found in patients with LCA10 is a deep intronic mutation in CEP290 that generates a cryptic splice donor site. The large size of the CEP290 gene prevents its use in adeno-associated virus (AAV)-mediated gene augmentation therapy. Here, we show that targeted genomic deletion using the clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9 system represents a promising therapeutic approach for the treatment of patients with LCA10 bearing the CEP290 splice mutation. We generated a cellular model of LCA10 by introducing the CEP290 splice mutation into 293FT cells and we showed that guide RNA pairs coupled with SpCas9 were highly efficient at removing the intronic splice mutation and restoring the expression of wild-type CEP290. In addition, we demonstrated that a dual AAV system could effectively delete an intronic fragment of the Cep290 gene in the mouse retina. To minimize the immune response to prolonged expression of SpCas9, we developed a self-limiting CRISPR/Cas9 system that minimizes the duration of SpCas9 expression. These results support further studies to determine the therapeutic potential of CRISPR/Cas9-based strategies for the treatment of patients with LCA10.

Cytotoxic T Lymphocyte Responses to Transgene Product, Not Adeno-Associated Viral Capsid Protein, Limit Transgene Expression in Mice

The use of adeno-associated viral (AAV) vectors for gene replacement therapy is currently being explored in several clinical indications. However, reports have suggested that input capsid proteins from AAV-2 vector particles may result in the stimulation of cytotoxic T lymphocyte (CTL) responses that can result in a loss of transduced cells. To explore the impact of anti-AAV CTLs on AAV-mediated transgene expression, both immunocompetent C57BL=6 mice and B cell-deficient muMT mice were immunized against the AAV2 capsid protein (Cap) and were injected intravenously with an AAV-2 vector encoding alpha-galactosidase (alpha-Gal). C57BL=6 mice, which developed both CTL and neutralizing antibody responses against Cap, failed to show any detectable alpha-Gal expression. In contrast, serum alpha-Gal levels comparable to those of naive mice were observed in muMT mice despite the presence of robust CTL activity against Cap, indicating that preexisting Cap-specific CTLs did not have any effect on the magnitude and duration of transgene expression. The same strategy was used to assess the impact of CTLs against the alpha-Gal transgene product on AAV-mediated gene delivery and persistence of transgene expression. Preimmunization of muMT mice with an Ad=alpha-Gal vector induced a robust CTL response to alpha-Gal. When these mice were injected with AAV2=alpha-Gal vector, initial levels of alpha-Gal expression were reduced by more than 1 log and became undetectable by 2 weeks postinjection. Overall, our results indicate that CTLs against the transgene product as opposed to AAV capsid protein are more likely to interfere with AAV transgene expression.

Rationally designed AAV2 and AAVrh8R capsids provide improved transduction in the retina and brain

The successful application of adeno-associated virus (AAV) gene delivery vectors as a therapeutic paradigm will require efficient gene delivery to the appropriate cells in affected organs. In this study, we utilized a rational design approach to introduce modifications to the AAV2 and AAVrh8R capsids and the resulting variants were evaluated for transduction activity in the retina and brain. The modifications disrupted either capsid/receptor binding or altered capsid surface charge. Specifically, we mutated AAV2 amino acids R585A and R588A, which are required for binding to its receptor, heparan sulfate proteoglycans, to generate a variant referred to as AAV2-HBKO. In contrast to parental AAV2, the AAV2-HBKO vector displayed low-transduction activity following intravitreal delivery to the mouse eye; however, following its subretinal delivery, AAV2-HBKO resulted in significantly greater photoreceptor transduction. Intrastriatal delivery of AAV2-HBKO to mice facilitated widespread striatal and cortical expression, in contrast to the restricted transduction pattern of the parental AAV2 vector. Furthermore, we found that altering the surface charge on the AAVrh8R capsid by modifying the number of arginine residues on the capsid surface had a profound impact on subretinal transduction. The data further validate the potential of capsid engineering to improve AAV gene therapy vectors for clinical applications.

329. Using CRISPR/Cas9 as a Therapeutic Approach for Leber Congenital Amaurosis 10 (LCA10)

Introduction: Leber congenital amaurosis (LCA) is the most severe form of inherited retinal diseases with early onset of symptoms in the first year of life. The most frequent genetic cause of LCA, accounting for approximately 15% of all LCA cases in western countries, is a deep-intronic mutation c. 2991+1655A>G located in the intron 26 of human CEP290 gene. LCA caused by CEP290 mutation is known as LCA10. The intronic mutation of CEP290 generates a cryptic splice donor site, resulting in the inclusion of a pseudoexon that leads to a premature stop codon and a truncated protein. The size of human CEP290 cDNA (~7.4 kb) exceeds the cargo size (~4.8 kb) of recombinant adeno-associated viral vectors (rAAVs), which makes this gene challenging for gene replacement therapy. In this regard, we tested if we can use the new genome editing technology CRISPR/Cas9 as an alternative strategy for LCA10 by removing the intronic mutation of CEP290 and preventing the cryptic splicing.Methods: CRISPR/SpCas9 was employed to introduce the intronic splice mutation c. 2991+1655 A>G into HEK 293FT cells to create a cellular model for LCA10/CEP290. In this cellular model, we used guide RNA pairs coupled with SpCas9 to delete the intronic region flanking the intronic mutation.Results: The deep-intronic mutation c. 2991+1655 A>G was successfully introduced into 293FT cells through the homology directed repair (HDR) pathway of CRISPR/spCas9. CEP290 expression levels were markedly reduced in the mutant cell line. Using this cellular model, we identified three sgRNA pairs that could efficiently (>50%) delete the intronic mutation, significantly rescue wild-type CEP290 expression levels and reduce mutant CEP290 expression.Conclusions: Our results demonstrate that the paired sgRNAs coupled with SpCas9 are capable of removing the c. 2991+1655A>G mutation and are highly efficient in preventing the splicing of the mutant cryptic exon and restoring wild-type CEP290 expression.

301. AAV Capsid Engineering to Improve Transduction in Retina and Brain

Gene therapy vectors based on adeno-associated virus (AAV) are currently in clinical studies for numerous disease indications including Lebers congenital amaurosis, age-related macular degeneration, hemophilia, muscular dystrophy and Parkinsons disease. AAV vectors hold considerable promise as therapeutic agents; however there is potential to further improve the efficiency of AAV gene delivery and efficacy by making modifications to the AAV capsid. The AAV capsid can be engineered to incorporate mutations that alter its transduction activity, tropism, biodistribution and immunogenicity. We have constructed variant AAV vectors harboring a variety of capsid modifications including those that negate receptor binding and have tested these vectors in several tissues including the eye and brain. One variant, AAV2HBKO, is an AAV2 based vector containing mutations of critical amino acids known to be required for binding to its receptor, heparin sulfate proteoglycan. Interestingly, an AAV2HBKO vector delivering a secreted transgene, sFLT02, unexpectedly resulted in a 2-log increase in transduction compared to parental AAV2 when delivered subretinally to the mouse eye. Subretinal delivery of an AAV2HBKO vector expressing EGFP demonstrated that these capsid modifications resulted in an increase in photoreceptor transduction compared to the unmodified AAV2 vector. In contrast, the AAV2HBKO vector demonstrated a lack of transduction activity following intravitreal delivery to the mouse eye. In addition, we evaluated the transduction and tropism of AAV2HBKO in the mouse brain. In a head to head comparison with AAV2, the AAV2HBKO vector facilitated widespread striatal and cortical expression following an intrastriatal injection while AAV2-mediated expression was restricted to the site of injection. Similar to AAV2, the tropism of AAV2HBKO was primarily neuronal with little to no transduction of astrocytes or microglia. Biodistribution data suggests that this vector, when delivered systemically in the mouse, has significantly reduced liver transduction but a higher propensity to be delivered to skeletal muscle and heart compared to the wild-type AAV2 vector. We will present data evaluating the transduction activity, tropism and biodistribution of the AAV2HBKO variant. These studies illustrate the potential for improving the efficiency of AAV gene transfer via targeted capsid engineering.