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Browsing by Author "Guo, Ping"
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Item "D" matters in recombinant AAV DNA packaging(Elsevier, 2021) Zhang, Junping; Guo, Ping; Xu, Yinxia; Mulcrone, Patrick L.; Samulski, R. Jude; Xiao, Weidong; Pediatrics, School of MedicineItem Effects of Thermally Induced Configuration Changes on rAAV Genome’s Enzymatic Accessibility(Elsevier, 2020-09-11) Xu, Yinxia; Guo, Ping; Zhang, Junping; Chrzanowski, Matthew; Chew, Helen; Firrman, Jenni A.; Sang, Nianli; Diao, Yong; Xiao, Weidong; Pediatrics, School of MedicinePhysical titers for recombinant adeno-associated viral (rAAV) vectors are measured by quantifying viral genomes. It is generally perceived that AAV virions disassemble and release DNA upon thermal treatment. Here, we present data on enzymatic accessibility of rAAV genomes when AAV virions were subjected to thermal treatment. For rAAV vectors with a normal genome size (≤4.7 kb), thermal treatment at 75°C–99°C allowed only ∼10% of genomes to be detectable by quantitative real-time PCR. In contrast, greater than 70% of AAV genomes can be detected under similar conditions for AAV vectors with an oversized genome (≥5.0 kb). The permeability of virions, as measured by ethidium bromide (EB) staining, was enhanced by thermal stimulation. These results suggest that in rAAV virions with standard-sized genomes, the capsid and DNA are close enough in proximity for heat-induced “crosslinking,” which results in inaccessibility of vector DNA to enzymatic reactions. In contrast, rAAV vectors with oversized genomes release their DNA readily upon thermal treatment. These findings suggested that the spatial arrangement of capsid protein and DNA in AAV virions is genome-size dependent. These results provide a foundation for future improvement of vector assays, design, and applications.Item Satellite Subgenomic Particles Are Key Regulators of Adeno-Associated Virus Life Cycle(MDPI, 2021-06-21) Zhang, Junping; Yu, Xiangping; Guo, Ping; Firrman, Jenni; Pouchnik, Derek; Diao, Yong; Samulski, Richard Jude; Xiao, Weidong; Pediatrics, School of MedicineHistorically, adeno-associated virus (AAV)-defective interfering particles (DI) were known as abnormal virions arising from natural replication and encapsidation errors. Through single virion genome analysis, we revealed that a major category of DI particles contains a double-stranded DNA genome in a "snapback" configuration. The 5'- snapback genomes (SBGs) include the P5 promoters and partial rep gene sequences. The 3'-SBGs contains the capsid region. The molecular configuration of 5'-SBGs theoretically may allow double-stranded RNA transcription in their dimer configuration. Our studies demonstrated that 5-SBG regulated AAV rep expression and improved AAV packaging. In contrast, 3'-SBGs at its dimer configuration increased levels of cap protein. The generation and accumulation of 5'-SBGs and 3'-SBGs appears to be coordinated to balance the viral gene expression level. Therefore, the functions of 5'-SBGs and 3'-SBGs may help maximize the yield of AAV progenies. We postulate that AAV virus population behaved as a colony and utilizes its subgenomic particles to overcome the size limit of a viral genome and encodes additional essential functions.Item Subgenomic particles in rAAV vectors result from DNA lesion/break and non-homologous end joining of vector genomes(Elsevier, 2022-08-24) Zhang, Junping; Guo, Ping; Yu, Xiangping; Frabutt, Dylan A.; Lam, Anh K.; Mulcrone, Patrick L.; Chrzanowski, Matthew; Firrman, Jenni; Pouchnik, Derek; Sang, Nianli; Diao, Yong; Herzog, Roland W.; Xiao, Weidong; Pediatrics, School of MedicineRecombinant adeno-associated virus (rAAV) vectors have been developed for therapeutic treatment of genetic diseases. Current rAAV vectors administered to affected individuals often contain vector DNA-related contaminants. Here we present a thorough molecular analysis of the configuration of non-standard AAV genomes generated during rAAV production using single-molecule sequencing. In addition to the sub-vector genomic-size particles containing incomplete AAV genomes, our results showed that rAAV preparations were contaminated with multiple categories of subgenomic particles with a snapback genome (SBG) configuration or a vector genome with deletions. Through CRISPR and nuclease-based modeling in tissue culture cells, we identified that a potential mechanism leading to formation of non-canonical genome particles occurred through non-homologous end joining of fragmented vector genomes caused by genome lesions or DNA breaks present in the host cells. The results of this study advance our understanding of AAV vectors and provide new clues for improving vector efficiency and safety profiles for use in human gene therapy.Item Thorough molecular configuration analysis of noncanonical AAV genomes in AAV vector preparations(Elsevier, 2024-02-19) Zhang, Junping; Yu, Xiangping; Chrzanowski, Matthew; Tian, Jiahe; Pouchnik, Derek; Guo, Ping; Herzog, Roland W.; Xiao, Weidong; Pediatrics, School of MedicineThe unique palindromic inverted terminal repeats (ITRs) and single-stranded nature of adeno-associated virus (AAV) DNA are major hurdles to current sequencing technologies. Due to these characteristics, sequencing noncanonical AAV genomes present in AAV vector preparations remains challenging. To address this limitation, we developed thorough molecule configuration analysis of noncanonical AAV genomes (TMCA-AAV-seq). TMCA-AAV-seq takes advantage of the documented AAV packaging mechanism in which encapsidation initiates from its 3′ ITR, for AAV-seq library construction. Any AAV genome with a 3′ ITR is converted to a template suitable to adapter addition by a Bst DNA polymerase-mediated extension reaction. This extension reaction helps fix ITR heterogeneity in the AAV population and allows efficient adapter addition to even noncanonical AAV genomes. The resulting library maintains the original AAV genome configurations without introducing undesired changes. Subsequently, long-read sequencing can be performed by the Pacific Biosciences (PacBio) single-molecule, real-time (SMRT) sequencing technology platform. Finally, through comprehensive data analysis, we can recover canonical, noncanonical AAV DNA, and non-AAV vector DNA sequences, along with their molecular configurations. Our method is a robust tool for profiling thorough AAV-population genomes. TMCA-AAVseq can be further extended to all parvoviruses and their derivative vectors.