Promoter interactions in retrovirus vectors introduced into fibroblasts and embryonic stem cells.

The activity of the Moloney murine leukemia virus promoter is restricted in mouse embryonic stem cells. Gene expression with retrovirus vectors can be achieved in these cells if internal promoters are used. To address the possible influence of the viral enhancer sequences on expression from the internal promoter, we have constructed high-titer, self-inactivating retrovirus vectors which delete viral regulatory sequences upon integration in the host genome. We show that deleting most of the viral enhancer sequences has no significant effect on viral titer. This enhancer deletion leads to either an increase or a decrease in the amount of RNA transcribed from the internal promoter, but no consistent change can be found with any type of vector. The same changes in expression from the internal promoter observed in embryonic stem cells are also observed in 3T3 fibroblast cells, in which the viral promoter is active. These results indicate that viral regulatory elements influence expression from an internal promoter independently of expression from the virus promoter.     

New retrovirus helper cells with almost no nucleotide sequence homology to retrovirus vectors.

We prepared retrovirus packaging cell lines containing gag-pol genes from spleen necrosis virus (expressed from a cytomegalovirus promoter and the simian virus 40 (SV40) polyadenylation sequences) and, on a separate vector, either the env gene from spleen necrosis virus (expressed from the Rous sarcoma virus promoter and the SV40 polyadenylation sequences) or the env gene from amphotropic murine leukemia virus (expressed from a cytomegalovirus promoter and the SV40 polyadenylation sequences). The nucleotide sequences in these packaging cell lines have almost no homology to the retrovirus vectors we used. Retrovirus vectors were produced from these new helper cell lines without any genetic interactions between the vectors and sequences in the helper cells and without transfer of the packaging sequences.     

Production of retrovirus and adenovirus vectors for gene therapy: a comparative study using microcarrier and stationary cell culture

In gene therapy, retrovirus and adenovirus vectors are extensively used as gene-delivery vehicles and further large-scale processing of these viral vectors will be increasingly important. This study examined stationary and microcarrier cell culture systems with respect to the production of a retrovirus vector (encoding a monounit hammerhead ribozyme gene with an intron) and an adenovirus vector (encoding a reporter lacZ gene). Cytodex 1 and Cytodex 3 solid microcarriers were found to be able to provide good cell growth and high-titer vector production in suspension cultures. Porous microcarriers such as Cytopore 2 gave slightly lower but still efficient growth but produced significantly lower titers of retrovirus and adenovirus vector from the producer cells. The specific retrovirus production was not proportionally related to the specific growth rate of the producer cells. High MOI infection was essential for high-titer production of adenovirus vector in 293 cells. Hydrodynamic shear forces on microcarrier-grown cells increased the production yield for retrovirus vector but decreased for adenovirus vector. The cellular productivity was much more efficient for adenovirus vector produced in 293 cells as compared to the retrovirus vector produced in PA317-RCM1 cells. These findings can provide further insight into the feasibility of applying microcarrier cell culture technology to produce gene-therapy virus vectors.     

Redesign of retrovirus packaging cell lines to avoid recombination leading to helper virus production.

Retrovirus vectors can be made in the absence of helper virus by using retrovirus packaging cell lines. Helper-free virus is critical for a variety of gene transfer studies. The most useful packaging cell lines contain helper virus DNA from which the signal required for packaging of the viral RNA genome into virions has been deleted. However, we showed that the ability to package virus is conferred at very low frequency to cells infected with virus from these packaging cell lines, presumably by low-frequency transmission of the deleted virus genome. In addition, these packaging cell lines can interact with some retroviral vectors to yield replication-competent virus. We constructed packaging cell lines containing helper virus DNA that had several alterations in addition to deletion of the packaging signal. The new packaging cells retained the useful features of previously available lines but did not yield helper virus after introduction of any of the vectors tested, and transfer of the packaging function was not detected.     

Expression of IMP1 enhances production of murine leukemia virus vector by facilitating viral genomic RNA packaging

Murine leukemia virus (MLV)-based retroviral vector is widely used for gene transfer. Efficient packaging of the genomic RNA is critical for production of high-titer virus. Here, we report that expression of the insulin-like growth factor II mRNA binding protein 1 (IMP1) enhanced the production of infectious MLV vector. Overexpression of IMP1 increased the stability of viral genomic RNA in virus producer cells and packaging of the RNA into progeny virus in a dose-dependent manner. Downregulation of IMP1 in virus producer cells resulted in reduced production of the retroviral vector. These results indicate that IMP1 plays a role in regulating the packaging of MLV genomic RNA and can be used for improving production of retroviral vectors.     

Production of high-titer helper virus-free retroviral vectors by cocultivation of packaging cells with different host ranges.

The titer of retroviral vectors can be increased by cocultivation of retrovirus packaging cells that produce a vector with packaging cells having a different host range. Multiple rounds of infection occur in such cultures, producing an amplification of vector copy number and titer. Production of a vector with a very high titer of over 10(10) CFU per ml of conditioned medium has been reported, although replication-competent helper virus was also present. Since helper-free virus is a requirement for many applications of retroviral vectors, we repeated this procedure with a modified vector and achieved a 2- to 10-fold amplification of vector titer in the absence of helper virus, up to 2 x 10(7) CFU/ml. We have also repeated these experiments with the same vector and methods described previously or have assayed virus from the high-titer vector-producing cell line reported previously and observed maximum titers of 10(8) CFU/ml, invariably accompanied by helper virus. Thus, while amplification of vector titer in the absence of helper virus is possible, some unexplained difference in the assays for virus titer must account for our inability to obtain the exceptionally high vector titers that were reported previously.     

脂质体DC-Chol/DOPE对HEK293FT细胞的高效转染及其在腺病毒制备中的应用

重组病毒载体系统因为具有高效的基因转移能力得到了广泛应用,而病毒包装细胞的转染是重组病毒制备过程中的关键步骤。优化了脂质体DC-Chol/DOPE介导的转染常用的病毒包装细胞系HEK293FT的实验条件,比较了DC-Chol/DOPE、Lipofectamine2000和磷酸钙共沉淀法转染细胞的效率,并且比较了用DC-Chol/DOPE和磷酸钙共沉淀法转染293FT细胞制备重组腺病毒的结果,发现DC-Chol/DOPE对293FT细胞的转染效率以及最终收获的病毒滴度都远高于磷酸钙共沉淀法转染。所以,利用DC-Chol/DOPE转染293FT细胞制备重组病毒是一种简单、高效、成本低廉的方法。     

Retrovirus vectors bearing jaagsiekte sheep retrovirus Env transduce human cells by using a new receptor localized to chromosome 3p21.3

Jaagsiekte sheep retrovirus (JSRV) is a type D retrovirus associated with a contagious lung tumor of sheep, ovine pulmonary carcinoma. Other than sheep, JSRV is known to infect goats, but there is no evidence of human infection. Until now it has not been possible to study the host range for JSRV because of the inability to grow this virus in culture. Here we show that the JSRV envelope protein (Env) can be used to pseudotype Moloney murine leukemia virus (MoMLV)-based retrovirus vectors and that such vectors can transduce human cells in culture. We constructed hybrid retrovirus packaging cells that express the JSRV Env and the MoMLV Gag-Pol proteins and can produce JSRV-pseudotype vectors at titers of up to 10(6) alkaline phosphatase-positive focus-forming units/ml. Using this high-titer virus, we have studied the host range for JSRV, which includes sheep, human, monkey, bovine, dog, and rabbit cells but not mouse, rat, or hamster cells. Considering the inability of the JSRV-pseudotype vector to transduce hamster cells, we used the hamster cell line-based Stanford G3 panel of whole human genome radiation hybrids to phenotypically map the JSRV receptor (JVR) gene within the p21.3 region of human chromosome 3. JVR is likely a new retrovirus receptor, as none of the previously identified retrovirus receptors localizes to the same position. Several chemokine receptors that have been shown to serve as coreceptors for lentivirus infection are clustered in the same region of chromosome 3; however, careful examination shows that the JSRV receptor does not colocalize with any of these genes.     

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.     

Exploration of critical parameters for transient retrovirus production

The pCL system was developed to aid in the production of retrovirus that encodes cytotoxic or cytostatic cDNA's. A principal feature of this system is the transient production of virus after co-transfection of the viral and packaging vectors in the 293T cell line. This approach obviates the need for selection of the producer cells, thus minimizing potential affects of the encoded genes. However, the transient nature of this system also creates a number of experimental variables. In this study we have examined and optimized elements related to the production of the pCL retrovirus. For example, co-transfection of the packaging sequence along with the viral vector has been optimized in terms of both the total amount of DNA transfected and the relative proportion of each plasmid. We have also tested the affect of increased synthesis of viral proteins in the producer cells and the kinetics of virus accumulation in the supernatant. These findings may be of interest to those who use pCL or any transient packaging system in their gene transfer studies. In addition, these studies may aid in the validation and development of transient retrovirus production systems for clinical applications.     

Production of viral vectors for gene therapy applications

Advances in cell culture engineering, cell metabolism, bioreactor design and operation, and downstream processing will all positively impact the bioprocessing of viral vectors. Design of appropriate vectors and tailoring of packaging cells to support more productive infections will be of paramount importance for production of high-titer and high-quality vectors. Furthermore, quantitative analysis of the infection parameters during virus propagation, such as time of infection, multiplicity of infection, the length of replication cycle, virus half-life, and burst size, will also be important to the process optimization. Finally, procedures for separation, purification and formulation of vector preparations have to be further developed.     

Construction of a helper cell line for avian reticuloendotheliosis virus cloning vectors.

We wished to construct cell lines that supply the gene products of gag, pol, and env for the growth of replication-defective reticuloendotheliosis retrovirus vectors without production of the helper virus. To do this, first we located by S1 mapping the donor and acceptor splice sites of reticuloendotheliosis virus strain A. The donor splice site is ca. 850 base pairs from the 5' end of proviral DNA. It is close to or overlaps the encapsidation sequences for viral RNA. The splice acceptor site is ca. 5.6 kilobase pairs from the 5' end of proviral DNA. Therefore, the encapsidation sequences and the donor splice site were removed from viral DNA to give expression of the gag and pol genes without virus production. The promoter in the long terminal repeat was fused to a site near the first ATG codon of the env gene, thereby deleting the encapsidation sequences and the gag and pol genes to give expression of the env gene without virus production. The permissive canine cell line D17 was transfected with the two modified viral DNAs. Two cell clones that contain both modified viral DNAs support the production of replication-defective spleen necrosis virus-thymidine kinase recombinant retrovirus vectors without the production of helper virus. To prevent recombination, the vector contains deletions that overlap with deletions in the integrated helper virus DNAs. This helper cell-vector system will be useful to derive infectious recombinant virus stocks of high titer (over 10(5) thymidine kinase transforming units per ml) which are able to infect avian, rat, and dog cells without the aid of helper virus.     

The pCL vector system: rapid production of helper-free, high-titer, recombinant retroviruses.

We describe the construction and characterization of retroviral vectors and packaging plasmids that produce helper-free retrovirus with titers of 1 X 10(6) to 5 X 10(6) within 48 h. These vectors contain the immediate early region of the human cytomegalovirus enhancer-promoter fused to the Moloney murine leukemia virus long terminal repeat at the TATA box in the 5' U3 region, yielding the pCL promoter. By selecting vectors designed to express genes from one of four promoters (dihydrofolate reductase, Rous sarcoma virus, long terminal repeat, or cytomegalovirus), the pCL system permits the investigator to control the level of gene expression in target cells over a 100-fold range, while maintaining uniformly high titers of virus from transiently transfected producer cells. The pCL packaging plasmids lack a packaging signal (delta-psi) and include an added safety modification that renders them self-inactivating through the deletion of the 3' U3 enhancer. Ecotropic, amphotropic (4070A), and amphotropic-mink cell focus-forming hybrid (10A1) envelope constructions have been prepared and tested, permitting flexible selection of vector pseudotype in accordance with experimental needs. Vector supernatants are free of helper virus and are of sufficiently high titer within 2 days of transient transfection in 293 cells to permit infection of more than 50% of randomly cycling target cells in culture. We demonstrated the efficacy of these vectors by using them to transfer three potent cell cycle control genes (the p16(INK4A), p53, and Rb1 genes) into human glioblastoma cells.     

High-titer bicistronic retroviral vectors employing foot-and-mouth disease virus internal ribosome entry site.

Bicistronic retroviral vectors were constructed containing the foot-and-mouth disease virus (FMDV) internal ribosome entry site (IRES) followed by the coding region of beta-galactosidase (beta-gal) or therapeutic genes, with the selectable neomycin phosphotransferase gene under the control of the viral long terminal repeat (LTR) promoter. LNFX, a vector with a multiple cloning site 3' to foot-and-mouth disease virus IRES, was used to construct vectors encoding rat erythropoietin (EP), rat granulocyte colony-stimulating factor (G-CSF), human adenosine deaminase (ADA) and beta-gal. In transduced primary rat vascular smooth muscle cells the cytokines were expressed at high levels, similar to those obtained from vectors employing the viral LTR promoter. LNFZ, a vector encoding beta-gal, had a 10-fold increase in titer over that of LNPoZ, a comparable vector containing the poliovirus (Po) internal ribosome entry site. Primary canine vascular smooth muscle cells infected with LNFZ and LNPoZ expressed similar activities of beta-gal and neomycin phosphotransferase (NPT). Overall, these vectors had titers between 10(6) and 2 x 10(7) c.f.u./ml, indicating that foot-and-mouth disease virus IRES provides high-titer bicistronic vectors with high-level two gene expression.     

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.     

Improved enzootic nasal tumor virus pseudotype packaging cell lines reveal virus entry requirements in addition to the primary receptor Hyal2

Enzootic nasal tumor virus (ENTV) and jaagsiekte sheep retrovirus (JSRV) are closely related retroviruses that cause epithelial cancers of the respiratory tract in sheep and goats. Both viruses use the glycosylphosphatidylinositol (GPI)-anchored cell surface protein hyaluronidase 2 (Hyal2) as a receptor for cell entry, and entry is mediated by the envelope (Env) proteins encoded by these viruses. Retroviral vectors bearing JSRV Env can transduce cells from a wide range of species, with the exception of rodent cells. Because of the low titer of vectors bearing ENTV Env, it has been difficult to determine the tropism of ENTV vectors, which appeared to transduce cells from sheep and humans only. Here we have developed high-titer ENTV packaging cells and confirm that ENTV has a restricted host range compared to that of JSRV. Most cells that are not transduced by JSRV or ENTV vectors can be made susceptible following expression of human Hyal2 on the cells. However, five rat cell lines from different rat strains and different tissues that were engineered to express human Hyal2 were still only poorly infected by ENTV vectors, even though the ENTV Env protein could bind well to human Hyal2 expressed on four of these cell lines. These results indicate the possibility of a coreceptor requirement for these viruses.