Mapping an Adeno-associated Virus 9-Specific Neutralizing Epitope To Develop Next-Generation Gene Delivery Vectors.

Recent clinical trials have demonstrated the potential of adeno-associated virus (AAV)-based vectors for treating rare diseases. However, significant barriers remain for the translation of these vectors into widely available therapies. In particular, exposure to the AAV capsid can generate an immune response of neutralizing antibodies. One approach to overcome this response is to map the AAV-specific neutralizing epitopes and rationally design an AAV capsid able to evade neutralization. To accomplish this, we isolated a monoclonal antibody against AAV9 following immunization of BALB/c mice and hybridoma screening. This antibody, PAV9.1, is specific for intact AAV9 capsids and has a high neutralizing titer of >1:160,000. We used cryo-electron microscopy to reconstruct PAV9.1 in complex with AAV9. We then mapped its epitope to the 3-fold axis of symmetry on the capsid, specifically to residues 496-NNN-498 and 588-QAQAQT-592. Capsid mutagenesis demonstrated that even a single amino acid substitution within this epitope markedly reduced binding and neutralization by PAV9.1. In addition, in vivo studies showed that mutations in the PAV9.1 epitope conferred a "liver-detargeting" phenotype to the mutant vectors, unlike AAV9, indicating that the residues involved in PAV9.1 interactions are also responsible for AAV9 tropism. However, we observed minimal changes in binding and neutralizing titer when we tested these mutant vectors for evasion of polyclonal sera from mice, macaques, or humans previously exposed to AAV. Taken together, these studies demonstrate the complexity of incorporating mapped neutralizing epitopes and previously identified functional motifs into the design of novel capsids able to evade immune response.IMPORTANCE Gene therapy utilizing viral vectors has experienced recent success, culminating in U.S. Food and Drug Administration approval of the first adeno-associated virus vector gene therapy product in the United States: Luxturna for inherited retinal dystrophy. However, application of this approach to other tissues faces significant barriers. One challenge is the immune response to viral infection or vector administration, precluding patients from receiving an initial or readministered dose of vector, respectively. Here, we mapped the epitope of a novel neutralizing antibody generated in response to this viral vector to design a next-generation capsid to evade immune responses. Epitope-based mutations in the capsid interfered with the binding and neutralizing ability of the antibody but not when tested against polyclonal samples from various sources. Our results suggest that targeted mutation of a greater breadth of neutralizing epitopes will be required to evade the repertoire of neutralizing antibodies responsible for blocking viral vector transduction.

Giles AR ，Govindasamy L ，Somanathan S ，Wilson JM ... -  《-》

Structurally Mapping Antigenic Epitopes of Adeno-associated Virus 9: Development of Antibody Escape Variants.

Emmanuel SN ，Smith JK ，Hsi J ，Tseng YS ，Kaplan M ，Mietzsch M ，Chipman P ，Asokan A ，McKenna R ，Agbandje-McKenna M ... -  《-》

High-Resolution Structural Characterization of a New Adeno-associated Virus Serotype 5 Antibody Epitope toward Engineering Antibody-Resistant Recombinant Gene Delivery Vectors.

Adeno-associated virus serotype 5 (AAV5) is being developed as a gene delivery vector for several diseases, including hemophilia and Huntington's disease, and has a demonstrated efficient transduction in liver, lung, skeletal muscle, and the central nervous system. One limitation of AAV gene delivery is preexisting neutralizing antibodies, which present a significant challenge for vector effectiveness in therapeutic applications. Here, we report the cryo-electron microscopy (cryo-EM) and image-reconstructed structure of AAV5 in complex with a newly generated monoclonal antibody, HL2476, at 3.1-Å resolution. Unlike other available anti-AAV5 capsid antibodies, ADK5a and ADK5b, with epitopes surrounding the 5-fold channel of the capsid, HL2476 binds to the 3-fold protrusions. To elucidate the capsid-antibody interactions, the heavy and light chains were sequenced and their coordinates, along with the AAV5 viral protein, assigned to the density map. The high resolution of the complex enabled the identification of interacting residues at the 3-fold protrusions of the capsid, including R483, which forms two hydrogen bonds with the light chain of HL2476. A panel of AAV5 variants was generated and analyzed by native dot immunoblot and transduction assays. This identified variants with antibody escape phenotypes that maintain infectivity.IMPORTANCE Biologics based on recombinant AAVs (rAAVs) are increasingly becoming attractive human gene delivery vehicles, especially after the approval of Glybera in Europe and Luxturna in the United States. However, preexisting neutralizing antibodies against the AAV capsids in a large percentage of the human population limit wide-spread utilization of these vectors. To circumvent this problem, stealth vectors must be generated that are undetectable by these antibodies. This study details the high-resolution characterization of a new antigenic region on AAV5, a vector being developed for numerous delivery applications. The structure of AAV5 complexed with HL2476, a novel antibody, was determined by cryo-EM to 3.1-Å resolution. The resolution of the density map enabled the identification of interacting residues between capsid and antibody and the determinants of neutralization. Thus, the information obtained from this study can facilitate the generation of host immune escape vectors.

Jose A ，Mietzsch M ，Smith JK ，Kurian J ，Chipman P ，McKenna R ，Chiorini J ，Agbandje-McKenna M ... -  《-》

Adeno-associated virus serotype 1 (AAV1)- and AAV5-antibody complex structures reveal evolutionary commonalities in parvovirus antigenic reactivity.

The clinical utility of the adeno-associated virus (AAV) gene delivery system has been validated by the regulatory approval of an AAV serotype 1 (AAV1) vector for the treatment of lipoprotein lipase deficiency. However, neutralization from preexisting antibodies is detrimental to AAV transduction efficiency. Hence, mapping of AAV antigenic sites and engineering of neutralization-escaping vectors are important for improving clinical efficacy. We report the structures of four AAV-monoclonal antibody fragment complexes, AAV1-ADK1a, AAV1-ADK1b, AAV5-ADK5a, and AAV5-ADK5b, determined by cryo-electron microscopy and image reconstruction to a resolution of ∼11 to 12 Å. Pseudoatomic modeling mapped the ADK1a epitope to the protrusions surrounding the icosahedral 3-fold axis and the ADK1b and ADK5a epitopes, which overlap, to the wall between depressions at the 2- and 5-fold axes (2/5-fold wall), and the ADK5b epitope spans both the 5-fold axis-facing wall of the 3-fold protrusion and portions of the 2/5-fold wall of the capsid. Combined with the six antigenic sites previously elucidated for different AAV serotypes through structural approaches, including AAV1 and AAV5, this study identified two common AAV epitopes: one on the 3-fold protrusions and one on the 2/5-fold wall. These epitopes coincide with regions with the highest sequence and structure diversity between AAV serotypes and correspond to regions determining receptor recognition and transduction phenotypes. Significantly, these locations overlap the two dominant epitopes reported for autonomous parvoviruses. Thus, rather than the amino acid sequence alone, the antigenic sites of parvoviruses appear to be dictated by structural features evolved to enable specific infectious functions. The adeno-associated viruses (AAVs) are promising vectors for in vivo therapeutic gene delivery, with more than 20 years of intense research now realized in a number of successful human clinical trials that report therapeutic efficacy. However, a large percentage of the population has preexisting AAV capsid antibodies and therefore must be excluded from clinical trials or vector readministration. This report represents our continuing efforts to understand the antigenic structure of the AAVs, specifically, to obtain a picture of "polyclonal" reactivity as is the situation in humans. It describes the structures of four AAV-antibody complexes determined by cryo-electron microscopy and image reconstruction, increasing the number of mapped epitopes to four and three, respectively, for AAV1 and AAV5, two vectors currently in clinical trials. The results presented provide information essential for generating antigenic escape vectors to overcome a critical challenge remaining in the optimization of this highly promising vector delivery system.

Tseng YS ，Gurda BL ，Chipman P ，McKenna R ，Afione S ，Chiorini JA ，Muzyczka N ，Olson NH ，Baker TS ，Kleinschmidt J ，Agbandje-McKenna M ... -  《-》

Coevolution of Adeno-associated Virus Capsid Antigenicity and Tropism through a Structure-Guided Approach.

Adeno-associated viruses (AAV) are composed of nonenveloped, icosahedral protein shells that can be adapted to package and deliver recombinant therapeutic DNA. Approaches to engineer recombinant capsids for gene therapy applications have focused on rational design or library-based approaches that can address one or two desirable attributes; however, there is an unmet need to comprehensively improve AAV vector properties. Such cannot be achieved by utilizing sequence data alone but requires harnessing the three-dimensional (3D) structural properties of AAV capsids. Here, we solve the structures of a natural AAV isolate complexed with antibodies using cryo-electron microscopy and harness this structural information to engineer AAV capsid libraries through saturation mutagenesis of different antigenic footprints. Each surface loop was evolved by infectious cycling in the presence of a helper adenovirus to yield a new AAV variant that then serves as a template for evolving the next surface loop. This stepwise process yielded a humanized AAV8 capsid (AAVhum.8) displaying nonnatural surface loops that simultaneously display tropism for human hepatocytes, increased gene transfer efficiency, and neutralizing antibody evasion. Specifically, AAVhum.8 can better evade neutralizing antisera from multiple species than AAV8. Further, AAVhum.8 displays robust transduction in a human liver xenograft mouse model with expanded tropism for both murine and human hepatocytes. This work supports the hypothesis that critical properties, such as AAV capsid antibody evasion and tropism, can be coevolved by combining rational design and library-based evolution for clinical gene therapy.IMPORTANCE Clinical gene therapy with recombinant AAV vectors has largely relied on natural capsid isolates. There is an unmet need to comprehensively improve AAV tissue tropism, transduction efficiency, and antibody evasion. Such cannot be achieved by utilizing capsid sequence data alone but requires harnessing the 3D structural properties of AAV capsids. Here, we combine rational design and library-based evolution to coevolve multiple, desirable properties onto AAV by harnessing 3D structural information.

Havlik LP ，Simon KE ，Smith JK ，Klinc KA ，Tse LV ，Oh DK ，Fanous MM ，Meganck RM ，Mietzsch M ，Kleinschmidt J ，Agbandje-McKenna M ，Asokan A ... -  《-》