Abstract:Adeno-associated virus (AAV) has many advantages for gene therapy over other vector systems. However, after the production of recombinant AAV (Raav) vectors, the biological titration of rAAV stocks is still cumbersome. Different investigators used laboratory-specific methods or internal reference standards that may limit preclinical and clinical applications. The inverted terminal repeats (ITR) sequences are the only cis-regulated viral elements required for rAAV packaging and remain within viral vector genomes. ITR is the excellent target sequences for qPCR quantification of rAAV titer. In this study, we developed a novel qPCR strategy to quantify rAAVs’ vector genome titer via targeting the ITR2 or ITR2-CMV element. In conclusion, the method is fast and accurate for the titration of rAAV2-derived vector genomes. It will promote the standardization of rAAV titration in the future.

Abstract:Interferon β (IFN-β) and TNF-related apoptosis-inducing ligand (TRAIL) are effective anticancer agents. Adeno-associated virus (AAV) is one of the current most promising gene delivery vectors. Previously, we constructed tumor-targeting AAV-hTERT-IFN-β and AAV-hTERT-TRAIL by inserting IFN-β or TRAIL gene into AAV controlled by hTERT promoter. The studies showed that either single IFN-β or TRAIL gene therapy exhibited a certain extent anticancer effect. Here, we report their inhibitory effects on A549 lung cancer cell growth in vitro and in vivo by combined AAV-hTERT-IFN-β and AAV-hTERT-TRAIL. Expression of secreted IFN-β in lung cancer A549 cells infected by AAV-hTERT-IFN-β was detected by enzyme-linked immunosorbent assay (ELISA). The growth-suppressing effect of AAV-hTERT-IFN-β in combination with AAV-hTERT-TRAIL on several cancer cell lines was assessed by MTT assay. Apoptosis of A549 cancer cells infected by AAV-hTERT-IFN-β alone, AAV-hTERT-TRAIL alone, and their combination was evaluated by apoptotic cell staining and flow cytometry (FCM), respectively. The antitumor effect of the combination of AAV-hTERT-IFN-β with AAV-hTERT-TRAIL in vivo was further evaluated through A549 lung cancer xenograft in nude mice. The results showed that the combinational treatment was superior to any alone and presented intensified tumor cytotoxic and apoptotic effect on A549 cancer cells. Most importantly, the combination of AAV-hTERT-IFN-β with AAV-hTERT-TRAIL exhibited significant antitumor effect and eliminated all tumor masses in nude mice, which lay a foundation for exploring the molecular mechanisms of combined IFN-β and TRAIL anti-tumor activity.

Abstract:Numerous studies and clinical trials have demonstrated the efficacy of recombinant adeno-associated virus gene delivery vectors. However, prior to expression, it is necessary to convert the single-stranded DNA genome into double-stranded DNA, which hinders the efficiency of these vectors. We can entirely circumvent this step through the use of self-complementary recombinant adeno-associated virus vector (scrAAV). ScrAAV packages an inverted repeat genome that can fold into double-stranded DNA without the requirement for DNA synthesis or base-pairing between multiple vector genomes. By using scrAAV, we could increase expression efficiency and reduce immune response caused by vectors themselves. Therefore, it is a promising vector for gene therapy. So far, it has been used in the treatment of hepatic diseases, central nervous system diseases, and eye diseases. It has also been used in the modifications of stem cells and as vectors for siRNA/miRNA and ribozymes. In this review, we focused on the preparation, expression and location of scrAAV both in vitro and in vivo. We mainly introduced the recent progress of scrAAV based therapy of Hemophilia B, in order to elucidate the potential and prospects of scrAAV in gene therapy.

Abstract:Recombinant adeno-associated virus (rAAV)-based vectors that can stably express therapeutic genes in vivo without detectable side-effect have shown great promise for human gene therapy. A major challenge for translation of promising research to clinical development is how to establish clinically compatible purification methods in separating rAAV from potentially pathogenic impurities, especially rAAV vector-related impurities, a class of impurities corresponding to AAV particles that closely resemble bona fide vectors and are difficult to remove. In this review we summarize the assembly process of rAAV vector-related impurities and their characteristics differed with rAAV vectors, and evaluate several current technologies to prevent their formation or separate them from rAAV stocks.

Abstract:Adeno-associated virus (AAV) is one of the most frequently used viral vectors in the field of gene therapy. However, the industrial production of AAV is facing key bottlenecks such as low yield and high-cost. The aim of this study was to establish a technology system for production of AAV in the double virus infected insects by using multiple-gene deleted baculovirus. First, a multiple gene deleted baculovirus for AAV production was constructed, and the baculovirus titer and its effect on infected cells was examined. Subsequently, the insect cells were co-infected with the double baculovirus and the infection conditions were optimized. At the final stage, we performed AAV production based on optimized conditions, and evaluated relevant parameters including production titer and quality. The results showed that the titer of AAV produced in the multiple gene deleted baculovirus was not different from that of the wild type, but the rate of cell death was significantly slower upon infection. Using the double virus route for optimized production of AAV, the genome titers were 1.63×1011 VG/mL for Bac4.0-1 and 1.02×1011 VG/mL for Bac5.0-2, which were elevated 240% and 110%, respectively, compared with that of the wild-type. Electron microscopy observations revealed that all three groups exhibited normal AAV viral morphology and they showed similar transduction activity. Taken together, we developed an AAV production system based on the infection of insect cells using multiple-gene deleted baculovirus, which significantly improved the virus yield and showed application potential.

Abstract:AAV-ITR single strand DNA mini vector (AAV-ITR ssDNA mini vector) is a novel gene expression vector based on AAV-ITR. We have shown efficient gene expression of AAV-ITR ssDNA mini vector in HEK 293T. Here, we studied the efficacy of gene expression of AAV-ITR ssDNA mini vector in vivo. We injected the skeletal muscle of ICR mice separately with equal molars of AAV-ITR ssDNA mini vector, ITR mutated AAV-ITR single strand DNA mini vector (AAV-ITRmm ssDNA mutant vector), AAV-ITR dsDNA and pUC57-minivector-GFP, combined with TurboFect. Florescence microscope analysis of skeletal muscle section shows that AAV-ITR ssDNA mini vector had higher expression efficiency and longer expression period. We extracted DNA from the muscle three months after injection and quantified three vectors by Real-time PCR. RT-PCR analysis shows that there were highest copy numbers of AAV-ITR ssDNA mini vector existing in muscle. Stable existing of AAV-ITR ssDNA mini vector in muscle could be the molecular basis of long term gene expression of the vector. The results suggest that AAV-ITR ssDNA mini vector might be a promising vector for gene therapy.

Abstract:Vasostatin, a 180-amino acid fragment from the N-terminal domain of calreticulin, is a potent endogenous angiogenesis inhibitor, which can inhibit the growth of many kinds of experimental tumor. But a recent report that vasostatin can enhance the malignant behavior of neuroendocrine tumor reminds us to be cautious to develop it as an anti-tumor medicine. VAS cDNA was cloned into pAAV-2 expression vector; recombinant virus rAAV-VAS was generated by a three plasmids, helper free packaging method. MS1 mouse pancreatic endothelial cell and human colon tumor HCT-116 cell were infected with rAAV-VAS. Transgene expression was analyzed by Western blotting analysis; cell proliferation was determined by MTT assay. The therapeutic potential of rAAV-VAS was evaluated in subcutaneous HCT-116 xenograft mouse model. rAAV-VAS inhibited the proliferation of MS1 but not HCT-116 cell. HCT-116 cell infected with rAAV-VAS secreted VAS protein into the supernatant effectively. The intratumoral delivery of rAAV-VAS inhibited the xenograft growth and microvessel density in tumors significantly. Our results show the effectiveness of rAAV-VAS as an angiogenesis inhibitor in suppressing tumor growth, validating the application of rAAV-VAS gene therapy in treatment against colon cancer.

Abstract:We developed a scalable AAV5/5 vector packaging system by using replication competent recombinant herpes simplex type 1 virus as helper virus. The fragment containing rep and cap genes of AAV5 was inserted into the non-necessary gene (UL2) of HSV1 genome, resulting in the helper virus rHSV1-rep5cap5. An AAV5/5 vector pAAV5neo carrying two AAV5 ITRs was constructed by inserting a neo gene expression cassette into the plasmid backbone of pAV5CMV-GFP. pAAV5neo-EGFP was constructed by inserting EGFP gene into pAAV5neo. BHK21 cell was transfected with pAAV5neo-EGFP and cultured in the presence of G418. EGFP expression positive monoclonal cells were picked up, and one that produced rAAV5/5-EGFP with the highest efficiency under the help of rHSV1-rep5cap5 was chosen as the production cell line named as C020. rAAV5/5-EGFP was produced by infecting C020 cells with rHSV1-rep5cap5, and crudely purified by our previous method of ‘chloroform treatment- PEG8000/NaCl precipitation- chloroform extract’. rAAV5/5-EGFP preparation with high purity was obtained by ultrafiltration with molecular weight cut-off value of 100 kDa. SDS-PAGE stained with Coomassie brilliant blue R250 showed clearly specific pattern of three bands of AAV capsid proteins. rAAV5/5-EGFP was also assayed using negative stain transmission electron microscopy and the majority of the virus particles were found solid. About 30% green fluorescent cells could be seen after infecting HEK293 cells with rAAV5/5-EGFP 24 h at 1×105 vg/cell. In conclusion, we have established an efficient AAV5/5 vector production system and could produce recombinant AAV5/5 virus in large amounts for gene therapy research.