Packaging cell lines for simian foamy virus type 1 vectors

Foamy viruses are nonpathogenic retroviruses that offer several unique opportunities for gene transfer in various cell types from different species. We have previously demonstrated the utility of simian foamy virus type 1 (SFV-1) as a vector system by transient expression assay (M. Wu et al., J. Virol. 72:3451-3454, 1998). In this report, we describe the first stable packaging cell lines for foamy virus vectors based on SFV-1. We developed two packaging cell lines in which the helper DNA is placed under the control of either a constitutive cytomegalovirus (CMV) immediate-early gene or inducible tetracycline promoter for expression. Although the constitutive packaging expressing cell line had a higher copy number of packaging DNA, the inducible packaging cell line produced four times more vector particles. This result suggested that the structural gene products in the constitutively expressing packaging cell line were expressed at a level that is not toxic to the cells, and thus vector production was reduced. The SFV-1 vector in the presence of vesicular stomatitis virus envelope protein G (VSV-G) produced an insignificant level of transduction, indicating that foamy viruses could not be pseudotyped with VSV-G to generate high-titer vectors. The availability of stable packaging cell lines represents a step toward the use of an SFV-1 vector delivery system that will allow scaled-up production of vector stocks for gene therapy.     

A High-Capacity, Capsid-Modified Hybrid Adenovirus/Adeno-Associated Virus Vector for Stable Transduction of Human Hematopoietic Cells

To achieve stable gene transfer into human hematopoietic cells, we constructed a new vector, DeltaAd5/35.AAV. This vector has a chimeric capsid containing adenovirus type 35 fibers, which conferred efficient infection of human hematopoietic cells. The DeltaAd5/35.AAV vector genome is deleted for all viral genes, allowing for infection without virus-associated toxicity. To generate high-capacity DeltaAd5/35.AAV vectors, we employed a new technique based on recombination between two first-generation adenovirus vectors. The resultant vector genome contained an 11.6-kb expression cassette including the human gamma-globin gene and the HS2 and HS3 elements of the beta-globin locus control region. The expression cassette was flanked by adeno-associated virus (AAV) inverted terminal repeats (ITRs). Infection with DeltaAd5/35.AAV allowed for stable transgene expression in a hematopoietic cell line after integration into the host genome through the AAV ITR(s). This new vector exhibits advantages over existing integrating vectors, including an increased insert capacity and tropism for hematopoietic cells. It has the potential for stable ex vivo transduction of hematopoietic stem cells in order to treat sickle cell disease.     

Hybrid Sindbis/Epstein-Barr virus episomal expression vector for inducible production of proteins

Alphavirus vectors are attractive as recombinant protein expression systems due to the high level of gene expression achieved. The combination of two mutations in the viral replicase, which render the replicase noncytopathic and temperature-sensitive, allowed the generation of a DNA-based vector (CytTs) that shows temperature inducible expression. This vector is of significant value for the production of toxic protein. However, like for other stable expression systems, tedious screening of individual cell clones are required in order to get a high producer cell clone. To circumvent this, we generated an episomally replicating vector by introducing an Epstein-Barr virus mini-replicon unit into CytTs. This novel vector allowed rapid generation of cell populations that showed tight regulation of expression and comparable expression levels to the ones achieved with high producer cell clones with CytTs. Moreover, protein production with selected cell populations could easily be scaled-up to a fermentation process.     

Effects of viral strain, transgene position, and target cell type on replication kinetics, genomic stability, and transgene expression of replication-competent murine leukemia virus-based vectors

The limited efficiency of in vivo gene transfer by replication-deficient retroviral vectors remains an obstacle to achieving effective gene therapy for solid tumors. One approach to circumvent this problem is the use of replication-competent retroviral vectors. However, the application of such vectors is at a comparatively early stage and the effects which virus strain, transgene cassette position, and target cell can exert on vector spread kinetics, genomic stability, and transgene expression levels remain to be fully elucidated. Thus, in this study a panel of vectors allowing the investigation of different design features on an otherwise genetically identical background were analyzed with respect to these readout parameters in cultures of both murine and human cells and in preformed tumors in nude mice. The obtained data revealed that (i) Moloney murine leukemia virus (Mo-MLV)-based vectors spread with faster kinetics, drive higher levels of transgene expression, and are more stable than equivalent Akv-MLV-based vectors; (ii) vectors containing the transgene cassette directly downstream of the envelope gene are genomically more stable than those containing it within the 3'-long terminal repeat U3 region; and (iii) the genomic stability of both strains seems to be cell line dependent.     

Construction of avian adenovirus CELO recombinants in cosmids

The avian adenovirus CELO is a promising vector for gene transfer applications. In order to study this potentiality, we developed an improved method for construction of adenovirus vectors in cosmids that was used to engineer the CELO genome. For all the recombinant viruses constructed by this method, the ability to produce infectious particles and the stability of the genome were evaluated in a chicken hepatocarcinoma cell line (LMH cell line). Our aim was to develop a replication-competent vector for vaccination of chickens, so we first generated knockout point mutations into 16 of the 22 unassigned CELO open reading frames (ORFs) to determine if they were essential for virus replication. As the 16 independent mutant viruses replicated in our cellular system, we constructed CELO genomes with various deletions in the regions of these nonessential ORFs. An expression cassette coding for the enhanced green fluorescent protein (eGFP) was inserted in place of these deletions to easily follow expression of the transgene and propagation of the vector in cell monolayers. Height-distinct GFP-expressing CELO vectors were produced that were all replication competent in our system. We then retained the vector backbone with the largest deletion (i.e., 3.6 kb) for the construction of vectors carrying cDNA encoding infectious bursal disease virus proteins. These CELO vectors could be useful for vaccination in the chicken species.     

Effect of genetic background and culture conditions on the production of herpesvirus-based gene therapy vectors.

Herpes simplex virus type-1 (HSV-1) represents a unique vehicle for the introduction of foreign DNA to cells of a variety of tissues. The nature of the vector, the cell line used for propagation of the vector, and the culture conditions will significantly impact vector yield. An ideal vector should be deficient in genes essential for replication as well as those that contribute to its cytotoxicity. Advances in the engineering of replication-defective HSV-1 vectors to reduce vector-associated cytotoxicity and attain sustained expression of target genes make HSV-1 an attractive gene-delivery vehicle. However, the yield of the less-cytotoxic vectors produced in standard tissue-culture systems is at least three order of magnitudes lower than that achieved with wild-type virus. The low overall yield and the complexity involved in the preparation of HSV vectors at high concentrations represent major obstacles in use of replication-defective HSV-derived vectors in gene therapy applications. In this work, the dependence of the vector yield on the genetic background of the virus is examined. In addition, we investigated the production of the least toxic, lowest-yield vector in a CellCube bioreactor system. After initial optimization of the operational parameters of the cellcube system, we were able to attain virus yields similar to or better than those values attained using the tissue culture flask system for vector production with significant savings with respect to time, labor, and cost.     

A novel family of retroviral vectors for the rapid production of complex stable cell lines

The production of stable cell lines is an important technique in cell biology, and it is often the rate-limiting step in studies involving the characterization of the function of novel genes or gene mutations. To facilitate this process, a novel family of retroviral vectors, the pE vector family, has been generated. The retroviral sequences in the pE vectors have been taken from the Moloney murine leukemia virus (MMLV) vector pMFG, which has been shown to express cDNA inserts more consistently and at higher levels than earlier generations of MMLV vectors. These vectors contain four different internal ribosome entry site-selectable markers, allowing high-efficiency selection of transductants expressing the desired cDNA. The pE vectors have an episomal design to allow long-term production of high-titer virus without the need for subcloning the producer line. Using a strategy of combinatorial infection followed by combinatorial drug selection, we demonstrate that the pE vectors can be used to generate stable, polyclonal cell lines expressing at least three novel cDNAs in less than 2 weeks. The use of these vectors will thus dramatically accelerate the production of complex stable cell lines.     

An efficient gene transfer system for hematopoietic cell line using transient and stable vectors

The hematopoietic system represents an interesting model for gene transfer protocols. Here, we have evaluated the efficiency of a gene transfer system using the polycationic compound SuperFect (Qiagen) and the K562 hematopoietic cell line. Transient and stable vectors carrying the enhanced green fluorescent protein (EGFP) reporter gene were employed. The stable vector was constructed based on Epstein-Barr virus sequences such as EBV oriP (origin of replication) and EBNA (EBV nuclear antigen)-1, both for DNA replication. The transfection efficiency of the viable cells was estimated by flow cytometry at approximately 98% for transient and stable vectors. Transiently transfected cells presented optimal EGFP expression until day 2 when fluorescence started to decrease. In contrast, stable transfectants continuously expressed the marker gene product for 10 weeks in the presence of G418. Our results represent an efficient gene transfer method for K562 hematopoietic cells and may be used as an alternative approach for further gene transfer studies involving hematopoietic cells.     

Herpes simplex virus type 1/adeno-associated virus rep(+) hybrid amplicon vector improves the stability of transgene expression in human cells by site-specific integration

Herpes simplex virus type 1 (HSV-1) amplicon vectors are promising gene delivery tools, but their utility in gene therapy has been impeded to some extent by their inability to achieve stable transgene expression. In this study, we examined the possibility of improving transduction stability in cultured human cells via site-specific genomic integration mediated by adeno-associated virus (AAV) Rep and inverted terminal repeats (ITRs). A rep(-) HSV/AAV hybrid amplicon vector was made by inserting a transgene cassette flanked with AAV ITRs into an HSV-1 amplicon backbone, and a rep(+) HSV/AAV hybrid amplicon was made by inserting rep68/78 outside the rep(-) vector 3' AAV ITR sequence. Both vectors also had a pair of loxP sites flanking the ITRs. The resulting hybrid amplicon vectors were successfully packaged and compared to a standard amplicon vector for stable transduction frequency (STF) in human 293 and Gli36 cell lines and primary myoblasts. The rep(+), but not the rep(-), hybrid vector improved STF in all three types of cells; 84% of Gli36 and 40% of 293 stable clones transduced by the rep(+) hybrid vector integrated the transgene into the AAVS1 site. Due to the difficulty in expanding primary myoblasts, we did not assess site-specific integration in these cells. A strategy to attempt further improvement of STF by "deconcatenating" the hybrid amplicon DNA via Cre-loxP recombination was tested, but it did not increase STF. These data demonstrate that introducing the integrating elements of AAV into HSV-1 amplicon vectors can significantly improve their ability to achieve stable gene transduction by conferring the AAV-like capability of site-specific genomic integration in dividing cells.     

Oncoretrovirus and Lentivirus Vectors Pseudotyped with Lymphocytic Choriomeningitis Virus Glycoprotein: Generation, Concentration, and Broad Host Range

Lymphocytic choriomeningitis virus (LCMV) is a noncytopathic arenavirus shown to infect a broad range of different cell types. Here, we combined the beneficial characteristics of the LCMV glycoprotein (LCMV-GP) and those of retroviral vectors to generate a new, safe, and efficient gene transfer system. These LCMV-GP pseudotypes were systematically compared with vectors containing the widely used amphotropic murine leukemia virus envelope (A-MLVenv) or the vesicular stomatitis virus G protein (VSV-G). Production of LCMV-GP-pseudotyped oncoretroviral and lentiviral vectors by transient transfection resulted in vector titers similar to those with A-MLVenv or VSV-G. In contrast to A-MLVenv particles, LCMV-GP pseudotypes could be efficiently concentrated by ultracentrifugation without loss of vector titer. Unlike the cell-toxic VSV-G, a stable retroviral packaging cell line constitutively expressing LCMV-GP could be established. Vectors pseudotyped with LCMV-GP efficiently transduced many cell lines from different species and tissues relevant for gene therapy. Transduction of human glioma cells was studied in detail. These cells are a major target for cancer gene therapy and were transduced more efficiently with LCMV-GP-pseudotyped vectors than with the generally used A-MLVenv particles. The high stability, low toxicity, and broad host range make LCMV-GP-pseudotyped vectors attractive for gene transfer applications. The recombinant LCMV-GP-pseudotyped vectors will also allow functional characterization of naturally occurring and recombinant LCMV-GP variants.     

A human immunodeficiency virus type 1 (HIV-1)-based retroviral vector system utilizing stable HIV-1 packaging cell lines.

We have constructed stable human immunodeficiency virus (HIV) packaging cell lines that when transfected with an HIV-based retroviral vector produce packaged vectors capable of transducing susceptible CD4+ cells. This HIV-1-based retroviral vector system has the potential for providing targeted delivery and regulated expression of immunogens or antiviral agents in CD4+ cells.     

基于逆转录病毒载体的外源基因表达系统的评价和应用

逆转录病毒表达系统是基因治疗研究和RNA干扰技术广泛采用的外源基因表达系统。文中以增强型绿色荧光蛋白 (EGFP) 基因的表达水平和稳定性为指标,比较逆转录病毒表达载体pQCXIN和pcDNA3.1(+) 表达质粒介导的外源基因在HEK293细胞和CHO-K1细胞的表达效率。病毒感染HEK293细胞和CHO-K1细胞的相对荧光强度 (Relative fluorescence intensity,RFI) 均约为对应的质粒转染细胞的2倍。多轮反复感染逆转录病毒表达载体能有效提高HEK293细胞表达EGFP的效率。HEK293细胞经4轮病毒感染后的RFI值较1次病毒感染HEK293细胞的RFI值约提高2倍。此外,逆转录病毒表达载体介导的外源基因表达的稳定性优于质粒转染的外源基因表达。采用携带人重组活性蛋白C (Recombinant human activated protein C,rhAPC) 基因的pQCXIN和HEK293细胞进一步验证了逆转录病毒载体介导的外源基因表达效率,构建了rhAPC表达水平为10~15 mg/(106 cells·d) 的HEK293细胞系。研究结果表明,逆转录病毒表达系统是有应用价值的介导外源基因在哺乳动物细胞高效表达的技术途径。     

Marking and gene expression by a lentivirus vector in transplanted human and nonhuman primate CD34(+) cells

Recently, gene delivery vectors based on human immunodeficiency virus (HIV) have been developed as an alternative mode of gene delivery. These vectors have a number of advantages, particularly in regard to the ability to infect cells which are not actively dividing. However, the use of vectors based on human immunodeficiency virus raises a number of issues, not the least of which is safety; therefore, further characterization of marking and gene expression in different hematopoietic lineages in primate animal model systems is desirable. We use two animal model systems for gene therapy to test the efficiency of transduction and marking, as well as the safety of these vectors. The first utilizes the rhesus animal model for cytokine-mobilized autologous peripheral blood CD34(+) cell transplantation. The second uses the SCID-human (SCID-hu) thymus/liver chimeric graft animal model useful specifically for human T-lymphoid progenitor cell reconstitution. In the rhesus macaques, detectable levels of vector were observed in granulocytes, lymphocytes, monocytes, and, in one animal with the highest levels of marking, erythrocytes and platelets. In transplanted SCID-hu mice, we directly compared marking and gene expression of the lentivirus vector and a murine leukemia virus-derived vector in thymocytes. Marking was observed at comparable levels, but the lentivirus vector bearing an internal cytomegalovirus promoter expressed less efficiently than did the murine retroviral vector expressed from its own long terminal repeats. In assays for infectious HIV type 1 (HIV-1), no replication-competent HIV-1 was detected in either animal model system. Thus, these results indicate that while lentivirus vectors have no apparent deleterious effects and may have advantages over murine retroviral vectors, further study of the requirements for optimal use are warranted.     

A gene transfer vector-cell line system for complete functional complementation of adenovirus early regions E1 and E4.

The improvements to adenovirus necessary for an optimal gene transfer vector include the removal of virus gene expression in transduced cells, increased transgene capacity, complete replication incompetence, and elimination of replication-competent virus that can be produced during the growth of first-generation adenovirus vectors. To achieve these aims, we have developed a vector-cell line system for complete functional complementation of both adenovirus early region 1 (E1) and E4. A library of cell lines that efficiently complement both E1 and E4 was constructed by transforming 293 cells with an inducible E4-ORF6 expression cassette. These 293-ORF6 cell lines were used to construct and propagate viruses with E1 and E4 deleted. While the construction and propagation of AdRSV beta gal.11 (an E1-/E4- vector engineered to contain a deletion of the entire E4 coding region) were possible in 293-ORF6 cells, the yield of purified virus was depressed approximately 30-fold compared with that of E1- vectors. The debilitation in AdRSV beta gal.11 vector growth was found to correlate with reduced fiber protein and mRNA accumulation. AdCFTR.11A, a modified E1-/E4- vector with a spacer sequence placed between late region 5 and the right inverted terminal repeat, efficiently expressed fiber and grew with the same kinetic profile and virus yield as did E1- vectors. Moreover, purified AdCFTR.11A yields were equivalent to E1- vector levels. Since no overlapping sequences exist in the E4 regions of E1-/E4- vectors and 293-ORF6 cell lines, replication-competent virus cannot be generated by homologous recombination. In addition, these second-generation E1-/E4- vectors have increased transgene capacity and have been rendered virus replication incompetent outside of the new complementing cell lines.     

Frequency and Stability of Chromosomal Integration of Adenovirus Vectors

One of the limitations of adenovirus vectors is the lack of machinery necessary for their integration into host chromosomes, resulting in short-term gene expression in dividing cells. We analyzed frequencies of integration and persistence of gene expression from integrated adenovirus vectors. Both E1-substituted and helper-dependent adenovirus vectors achieved similar integration efficiencies of approximately 10(-3) to 10(-5) per cell, with the helper-dependent vector showing slightly higher efficiencies. In stable cell pools, gene expression of the integrated vector persisted for at least 50 cell divisions without selection. However, some stable cell clones showed changes in gene expression, which were accompanied by structural changes in the integrated vector DNA.     

靶向肿瘤治疗的腺相关病毒载体

靶向性是肿瘤治疗取得成功的关键因素。病毒载体用于治疗肿瘤的过程中必须要求特异性作用于肿瘤细胞的同时降低对正常细胞的毒性。腺相关病毒(adeno-associated virus,AAV)较其他病毒载体具有免疫原性小、宿主范围广和介导基因可长期表达等优点,因此得到了广泛的应用。然而,AAV载体针对肿瘤的靶向性一直是近年研究的热点和难点。现就AAV载体治疗肿瘤的概况和靶向策略以及其安全性等方面作一综述。