Fast-Seq: A Simple Method for Rapid and Inexpensive Validation of Packaged Single-Stranded Adeno-Associated Viral Genomes in Academic Settings

Self-complementary AAV Vectors; Advances and Applications

Adeno-associated Virus of a Single-polarity DNA Genome Is Capable of Transduction In Vivo

My Pathway to Adeno-Associated Virus and Adeno-Associated Virus Gene Therapy: A Personal Perspective.

Gene therapy with recombinant adeno-associated viral (AAV) vectors is a promising modality for the treatment of a variety of human diseases. Nonetheless, there remain significant gaps in our understanding of AAV vector biology, due in part to the lack of robust methods to track AAV capsids and genomes. In this study, we describe a novel application of signal amplification by exchange reaction fluorescence in situ hybridization (SABER-FISH) that enabled the visualization and quantification of individual AAV genomes after vector administration in mice. These genomes could be seen in retinal cells within 3 h of subretinal AAV delivery, were roughly full length, and correlated with vector expression in both photoreceptors and the retinal pigment epithelium. SABER-FISH readily detected AAV genomes in the liver and muscle following retro-orbital and intramuscular AAV injections, respectively, demonstrating its utility in different tissues. Using SABER-FISH, we also found that retinal microglia, a cell type deemed refractory to AAV transduction, are in fact efficiently infected by multiple AAV serotypes, but appear to degrade AAV genomes prior to nuclear localization. Our findings show that SABER-FISH can be used to visualize AAV genomes in situ, allowing for studies of AAV vector biology and the tracking of transduced cells following vector administration.

The histological findings in 18 cases of parathyroid hyperplasia associated with chronic renal failure and haemodialysis have been compared with a series of 35 cases of primary adenomatous hyperparathyroidism. Analysis...

Recombinant adeno-associated viruses (AAV) are among the most promising vectors for gene therapy of genetic diseases, including cystic fibrosis (CF). However, because of its small genome size, the capacity of AAV to package a therapeutic gene is limited. The efficiency of packaging the cystic fibrosis transmembrane conductance Regulator (CFTR) gene into AAV will be an important factor in determining whether recombinant AAV can be developed as a vector for transferring CFTR cDNA to the airway epithelia of patients with CF. Current understanding of the AAV biology suggests that AAV can package a genome slightly larger than the size of a wild-type genome. The precise range of the genome size and the efficiency of packaging have not been defined. Using a series of AAV vectors with progressively-increasing genome size, we were able to analyze quantitatively the packaging efficiency in relation to the vector size and to determine the size limit for packaging. The packaging efficiencies of AAV vectors of variable sizes were determined directly by assaying DNA contents of viral particles, and indirectly by analyzing their efficiency in transfer of a chloramphenicol acetyltransferase (CAT) reporter gene into target cells. Our studies showed that the optimal size of AAV vector is between 4.1 and 4.9 kb. Although AAV can package a vector larger than its genome size, up to 5.2 kb, the packaging efficiencies in this large size range were sharply reduced. When the AAV genome size was smaller than 4.1 kb, the packaging efficiency was also suboptimal. In contrast, when the size of the genome was less than half the length of the wild-type genome, two copies of the vector were packaged into each virion, suggesting that the copy number control during packaging is a "head-full" mechanism. Because the length of the minimal cDNA of CFTR is about 4.5 kb, these results suggest it is possible to package the CFTR gene into AAV if the combined length of transcriptional elements and ITRs is kept under 500 bp. The results of this study are important for directing the design of AAV vectors for efficient gene transfer, as well as for a better understanding of the mechanism of AAV genome packaging.

Adeno-associated virus (AAV) genome replication only occurs in the presence of a co-infecting helper virus such as adenovirus type 5 (AdV5) or herpes simplex virus type 1 (HSV-1). AdV5-supported replication of the AAV genome has been described to occur in a strand-displacement rolling hairpin replication (RHR) mechanism initiated at the AAV 3’ inverted terminal repeat (ITR) end. It has been assumed that the same mechanism applies to HSV-1-supported AAV genome replication. Using Southern analysis and nanopore sequencing as a novel, high-throughput approach to study viral genome replication we demonstrate the formation of double-stranded head-to-tail concatemers of AAV genomes in the presence of HSV-1, thus providing evidence for an unequivocal rolling circle replication (RCR) mechanism. This stands in contrast to the textbook model of AAV genome replication when HSV-1 is the helper virus.

Biochemical, Pathological, and Skeletal Improvement of Mucopolysaccharidosis VI After Gene Transfer to Liver but Not to Muscle

Proteasome Inhibitors Enhance Gene Delivery by AAV Virus Vectors Expressing Large Genomes in Hemophilia Mouse and Dog Models: A Strategy for Broad Clinical Application

484. Murine Liver as a Model for AAV Replication, Recombination and Evolution

Accurate titration of adeno-associated viral (AAV) vector genome copies is critical for ensuring correct and reproducible dosing in both preclinical and clinical settings. Quantitative PCR (qPCR) is the current method of choice for titrating AAV genomes because of the simplicity, accuracy, and robustness of the assay. However, issues with qPCR-based determination of self-complementary AAV vector genome titers, due to primer-probe exclusion through genome self-annealing or through packaging of prematurely terminated defective interfering (DI) genomes, have been reported. Alternative qPCR, gel-based, or Southern blotting titering methods have been designed to overcome these issues but may represent a backward step from standard qPCR methods in terms of simplicity, robustness, and precision. Droplet digital PCR (ddPCR) is a new PCR technique that directly quantifies DNA copies with an unparalleled degree of precision and without the need for a standard curve or for a high degree of amplification efficiency; all properties that lend themselves to the accurate quantification of both single-stranded and self-complementary AAV genomes. Here we compare a ddPCR-based AAV genome titer assay with a standard and an optimized qPCR assay for the titration of both single-stranded and self-complementary AAV genomes. We demonstrate absolute quantification of single-stranded AAV vector genomes by ddPCR with up to 4-fold increases in titer over a standard qPCR titration but with equivalent readout to an optimized qPCR assay. In the case of self-complementary vectors, ddPCR titers were on average 5-, 1.9-, and 2.3-fold higher than those determined by standard qPCR, optimized qPCR, and agarose gel assays, respectively. Droplet digital PCR-based genome titering was superior to qPCR in terms of both intra- and interassay precision and is more resistant to PCR inhibitors, a desirable feature for in-process monitoring of early-stage vector production and for vector genome biodistribution analysis in inhibitory tissues.

Efficient Intrathymic Gene Transfer Following In Situ Administration of a rAAV Serotype 8 Vector in Mice and Nonhuman Primates

The isolation of adeno-associated virus (AAV) genomes from biomaterials at the molecular level has traditionally relied on polymerase chain reaction-based and cloning-based techniques. However, when applied to samples containing multiple species, traditional techniques for isolating viral genomes can amplify artificial recombinants and introduce polymerase misincorporation errors. In this study, we describe AAV single-genome amplification (AAV-SGA): a powerful technique to isolate, amplify, and sequence single AAV genomes from mammalian genomic DNA, which can then be used to construct vectors for gene therapy. We used AAV-SGA to precisely isolate 15 novel AAV genomes belonging to AAV clades A, D, and E and the Fringe outgroup. This technique also enables investigations of AAV population dynamics and recombination events to provide insights into virus-host interactions and virus biology. Using AAV-SGA, we identified regional heterogeneity within AAV populations from different lobes of the liver of a rhesus macaque and found evidence of frequent genomic recombination between AAV populations. This study highlights the strengths of AAV-SGA and demonstrates its capability to provide valuable insights into the biology and diversity of AAVs.

A Hybrid Vector System Expands Adeno-associated Viral Vector Packaging Capacity in a Transgene-independent Manner

Role of the terminal repeat GAGC trimer, the major Rep78 binding site, in adeno-associated virus DNA replication