Development of Improved Adenosine Deaminase Retroviral Vectors

A series of adenosine deaminase (ADA) retroviral vectors were designed and constructed with the goal of improved performance over the PA317/LASN vector currently used in clinical trials. First, the bacterial selectable-marker neomycin phosphotransferase (neo) gene was removed to create a “simplified” vector. Second, the Moloney murine leukemia virus long terminal repeat (LTR) promoter used for ADA expression was replaced with either the myeloproliferative sarcoma virus (MPSV) or SL3-3 LTR. Supernatant from each ADA vector was used to transduce ADA-deficient (ADA⁻) B- and T-cell lines as well as primary peripheral blood mononuclear cells (PBMC) from an ADA⁻ severe combined immunodeficiency patient. Total ADA enzyme activity and ADA activity per integrant in the transduced cells demonstrated that the MPSV LTR splicing vector design provided the highest level of ADA expression per cell. This ADA(MPSV) vector was then tested in packaging cell lines containing either the gibbon ape leukemia virus envelope (PG13 cells), the murine amphotropic envelope (FLYA13 cells), or the feline endogenous virus RD114 envelope (FLYRD18 cells). The results indicate that FLYRD18/ADA(MPSV), a simplified ADA retroviral vector with the MPSV LTR, provides a 17-fold-higher level of ADA expression in human lymphohematopoietic cells than the PA317/LASN vector currently in use.Retroviral vectors have been the most common gene transfer vehicles in clinical gene therapy trials (15). These vectors can integrate into the host genome to provide permanent transgene expression in the targeted cells (20). The first generation of retroviral vectors have been useful in demonstrating the feasibility of gene therapy approaches, but vectors capable of higher levels of gene transfer and transgene expression would be beneficial. For example, gene transfer levels achieved by first-generation retroviral vectors in large mammals (28) and in human gene therapy trials (7, 13) have been disappointing. There are at least two avenues for improving retroviral vectors. First, molecular changes can be made in the retroviral vector sequence. Second, different packaging cell lines could be tested to modify the host range, increase transduction in a given cell type, and/or render the virions resistant to inactivation by human complement.A clinically useful model for improving retroviral vector design is the vector LASN packaged in the amphotropic line PA317. PA317/LASN was the first therapeutic vector used in a gene therapy clinical trial (1). This vector has yielded gene transfer levels of generally less than 10% in peripheral blood T cells of adenosine deaminase-deficient (ADA⁻) severe combined immunodeficiency (SCID) patients. Two possibilities to improve this vector include eliminating the dominant selectable marker gene and changing the long terminal repeat (LTR) promoter to optimize expression. LASN, like many of the retroviral vectors used in clinical trials to date, contains two genes: the therapeutic gene (the ADA gene) and a dominant selectable marker gene (the bacterial neomycin phosphotransferase II gene; neo). Dominant selectable marker genes have historically been included to facilitate the generation, isolation, and titration of retroviral producer cell clones and to permit the evaluation and selection of successfully targeted cells. neo is the most commonly used selectable marker gene, although other genes have been used, including a mutant dihydrofolate reductase gene (dhfr) (19), the multidrug resistance gene (mdr) (10), and genes for cell surface markers such as cd24 (24) and the human nerve growth factor receptor (2). Vectors carrying dominant selectable marker genes, particularly those of nonhuman origin, have two theoretical disadvantages. First, careful analysis of some patients has revealed an immune response directed against the dominant selectable marker protein expressed from the retroviral integrant (20a, 25). Second, the more complex retroviral genomes required to express two separate genes may result in lower titers or suboptimal expression of the therapeutic gene product due to promoter interference (8, 29). On the other hand, cloning and determining the titers of useful retroviral vectors without selectable markers have been laborious. Using a recently developed rapid-screening procedure, we have been able to identify a number of “simple” ADA retroviral vectors which lack dominant selectable markers (23).Different packaging cell lines may also improve gene transfer of retroviral vectors into specific target cells. Retroviral vectors are limited by the host range specified by the envelope protein on the surface of the retrovirus. Most gene therapy trials have used retroviruses with a murine amphotropic (4070A) host range. However, packaging cell lines with the gibbon ape leukemia virus (GALV) envelope (PG13 cells) (18) and the cat endogenous virus RD114 envelope (FLYRD18 cells) (5) have become available; these may improve transduction frequencies into various target cell populations. For example, there is evidence that GALV-pseudotyped retroviral vectors may facilitate gene transfer into human peripheral blood T cells with greater efficiency than vectors with an amphotropic envelope (3). Packaging cell lines derived from murine cells have the additional disadvantage that they produce retroviruses which are inactivated by complement in human sera. Packaging cell lines of human origin (FLYA13 and FLYRD18) (5) produce vectors which are complement resistant. Testing both new simple retroviral vector designs and new packaging cells may therefore improve retrovirus-mediated gene transfer.We report the construction and characterization of three simplified ADA vectors by using either the Moloney murine leukemia virus (MLV) LTR, the myeloproliferative sarcoma virus (MPSV) LTR, or the SL3-3 LTR. We tested these vectors to determine which LTR provided the highest level of ADA expression in our target cells of interest: human ADA⁻ lymphohematopoietic cells. The ADA retroviral vector with the highest level of transduction/expression was then evaluated in different packaging cell lines including PG13, FLYA13, and FLYRD18.     

Production of retroviral vectors for gene therapy with the human packaging cell line FLYRD18.

The development of gene therapy is hampered by the difficulty of producing large stocks of retroviral vectors at high titer. This study aimed to improve culture conditions and to intensify the production of retroviruses by FLYRD18, a packaging cell line derived from the HT1080 human fibrosarcoma line. Batch virus production proved to be feasible in unsupplemented basal medium and provided significantly higher titers and productivities than medium supplemented with 10% serum. For longer-term production, however, AIM-V complete serum-free medium and basal medium supplemented with 2% serum gave superior results. Serum supplementation should nevertheless be optimized to take into account the presence of inhibitors of viral production. In monolayer cultures with 0.2 mL/cm(2), the cell concentration was increased up to 2 x 10(6) cells/mL without loss of cell productivity. A semicontinuous production process, which enables the collection of larger amounts of viruses from the same culture, has also been successfully used. Suspension culture processes were prevented by the anchorage dependency of the FLYRD18 cell line. Microcarrier cultures were able to produce viruses but will require further investigation and optimization for their performance to become competitive with monolayer cultures. In the course of this study, more than a 10-fold increase of titer has been achieved.     

Exploiting heparin-binding properties of MoMLV-based retroviral vectors for affinity chromatography

Chromatography is deemed the most promising technology for large-scale purification of viral vectors. The authors have previously shown that heparin affinity chromatography could be successfully employed for the purification of VSV-G pseudotyped Moloney murine leukemia virus (MoMLV)-derived vectors giving excellent results in terms of recovery of active particles, reproducibility and selectivity. In this study, the authors examined whether the ability of retrovirus particles to specifically bind to heparin ligands is restricted to VSV-G pseudotypes produced by 293-based packaging cells. It is shown that VSV-G deficient retrovirus particles are captured by a heparin chromatography column as efficiently as VSV-G containing particles. Most strikingly, RD114 pseudotyped retrovirus particles derived from a HT1080-based cell line were found to bind heparin with the same affinity as 293-derived VSV-G pseudotypes. RD114 pseudotyped retrovirus particles were successfully isolated using heparin affinity chromatography obtaining good recoveries of functional particles (43%). These results indicate that heparin affinity chromatography can be extended to the purification of retroviral vectors produced by different packaging cell lines independently of the Env-protein used for pseudotyping.     

RD114-pseudotyped retroviral vectors kill cancer cells by syncytium formation and enhance the cytotoxic effect of the TK/GCV gene therapy strategy

BACKGROUND: Wild-type RD114 virus is capable of generating syncytia during its replication, and it is believed that cell-free viruses direct the fusion of neighboring cells. The RD114 envelope (Env) that mediates this fusion event is now widely used to pseudotype retroviral and lentiviral vectors in gene therapy. Indeed, vectors pseudotyped with RD114 Env are very efficient to transfer genes into human hematopoietic cells, and they are resistant to human complement inactivation. In this study, we have tested the potential of RD114-pseudotyped vectors produced from the FLYRD18 packaging cell line to induce syncytia. METHODS: RD114-pseudotyped vectors produced from the FLYRD18 packaging cells were added on tumor cell lines, and the formation of syncytia was assessed by microscopy after cell fixation and methylene blue staining. The kinetics of syncytium formation was analyzed by time-lapse microscopy. Finally, the cytotoxic effect of RD114-pseudotyped vectors was measured by the MTT assay on tumor cells, and in combination with the TK/GCV strategy. RESULTS: We have found that these vectors were able to mediate cell-to-cell fusion of human tumor cell lines. A few hours after addition of the vector, cells started to aggregate to form syncytia that eventually evolved toward cell death 48 h postinfection. RD114-pseudotyped vectors were very efficient at killing human cancer cells, and they were also able to enhance dramatically the cytotoxic effect of the TK/GCV strategy. CONCLUSIONS: These findings indicate that RD114-pseudotyped vectors used alone, or in combination with a suicide gene therapy approach, have great potential for the treatment of cancer.     

Construction and properties of retrovirus packaging cells based on gibbon ape leukemia virus.

We have constructed hybrid retrovirus packaging cell lines that express the gibbon ape leukemia virus env and the Moloney murine leukemia virus gag-pol proteins. These cells were used to produce a retrovirus vector at over 10(6) CFU/ml, with a host range that included rat, hamster, bovine, cat, dog, monkey, and human cells. The gag-pol and env expression plasmids were separately transfected to reduce the potential for helper virus production, which was not observed. The NIH 3T3 mouse cells from which the packaging lines were made are not infectable by gibbon ape leukemia virus; thus, the generation and spread of possible recombinant viruses in the packaging cells is greatly reduced. These simian virus-based packaging cells extend the host range of currently available murine and avian packaging cells and should be useful for efficient gene transfer into higher mammals.     

Relationship between cell proliferation, cell-cycle phase, and retroviral vector production in FLYRD18 human packaging cells

The relatively low concentrations of retroviral vectors produced by most packaging cells requires the optimization and intensification of their production to make a commercially viable product for gene therapy. While a number of reports exist concerning target cell-cycle effects on retroviral vector infection efficiency, no studies have been reported on the effects of packaging cell cycle on vector production. We have studied the effect of proliferation of the human packaging cell line, FLYRD18, on vector production. In addition, the titer levels of vector produced by cells in each phase of the cell cycle were compared. Numerous studies suggested progression of the cells through the cell cycle to be essential for vector production. However, vector release was found not to be predominant in any particular phase of the cell cycle. These findings indicate that packaging cell proliferation is important for optimal virus production and that arrest of the cells in any particular phase of the cell cycle affords no benefits in retroviral vector production. In contrast to previous reports (using other cell lines), we observed no temporary inhibition of cell cycle progression after detachment of cells from their substratum and that virus production occurred immediately after re-plating of the cells. The findings in this report are important for determining the optimal culture conditions for vector production by packaging cells in vitro.     

Construction of recombinant murine retroviruses that express the human T-cell leukemia virus type II and human T-cell lymphotropic virus type III trans activator genes.

Recombinant retroviruses containing the trans activator genes of human T-cell leukemia virus (HTLV) type II and human T-cell lymphotropic virus type III were constructed. The trans activator genes tat II and tat III were inserted into the murine retroviral vector pZIPNEOSV(X)1. Recombinant plasmids were transfected into the psi 2 and psi AM packaging cell lines that produce murine leukemia virions containing no retroviral RNA. Functional tat II and tat III gene products were expressed as demonstrated by trans activation of HTLV type I and II and human T-cell lymphotropic virus type III long terminal repeat-directed gene expression in the respective infected cells. Use of these recombinant vectors permits high-efficiency gene transfer into a wide variety of cells, thereby providing the opportunity to study the biochemical effects associated with tat II and tat III gene expression.     

Packaging system for rapid production of murine leukemia virus vectors with variable tropism.

A method for rapidly producing helper-free murine leukemia virus (MLV) without using packaging cell lines is described. Viruses bearing ecotropic or amphotropic MLV or Rous sarcoma virus envelope glycoprotein and containing various retroviral vector genomes have been prepared with titers 30 to 40-fold higher than those produced by transient transfection of standard packaging cells. This system can be used to alter the cellular tropism of MLV by incorporating other envelope glycoproteins and to prepare retroviral vector stocks without establishing stable producer cell lines. This method will be particularly useful for preparing viruses that encode toxic proteins and for the rapid analysis of panels of mutant envelope glycoproteins.     

Gene-transfer into bone marrow cells

We have intended to improve gene-transfer technique into hematopoietic stem cells for somatic gene therapy. 1) We have developed a new packaging cell line, ampGPE for retroviral production. LTR-less gag, pol or env genes from Moloney murine leukemia virus were separately inserted into BMGNeo vector. Packaging cell lines containing 20-50 copies of these two kinds of plasmid were obtained. Retrovirus stock for gene-transfer have been produced at a high titer (10(5)-10(6) cfu/ml) and without replication-competent viruses by using ampGPE. 2) Retrovirus-transduced murine CFU-GM have been found to selectively proliferate (5-10 fold/week) in liquid capture with recombinant murine IL-3, human IL-6 and G418 to consequently obtain enough amount of, highly concentrated (70-100%), and gene-transferred murine CFU-GM for gene-delivery system.