A single point mutation activates the Moloney murine leukemia virus long terminal repeat in embryonal stem cells.

The expression of Moloney murine leukemia virus (Mo-MuLV) and Mo-MuLV-derived vectors is restricted in undifferentiated mouse embryonal carcinoma and embryonal stem (ES) cells. We have previously described the isolation of retroviral mutants with host range properties expanded to embryonal cell lines. One of these mutants, the murine embryonic stem cell virus (MESV), is expressed in ES cell lines. Expression of MESV in these cells relies on DNA sequence motifs within the enhancer region of the viral long terminal repeat (LTR). Here we show that replacement of the Mo-MuLV enhancer region by sequences derived from the MESV LTR results in the activation of the Mo-MuLV LTR in ES cells. The enhancer regions of MESV and Mo-MuLV differ by seven point mutations. Of these, a single point mutation at position -166 is sufficient to activate the Mo-MuLV LTR and to confer enhancer-dependent expression to Mo-MuLV-derived retroviral vectors in ES cells. This point mutation creates a recognition site for a sequence-specific DNA-binding factor present in nuclear extracts of ES cells. This factor was found by functional assays to be the murine equivalent to human Sp1.     

An array of murine leukemia virus-related elements is transmitted and expressed in a primate recipient of retroviral gene transfer.

Direct RNA-PCR analyses of T-cell lymphomas that developed in rhesus macaques during a gene transfer experiment revealed the presence of several different recombinant murine leukemia viruses (MuLV). Most prominent was the expected MuLV recombinant, designated MoLTRAmphoenv in which the amphotropic env of the helper packaging virus was joined to the long terminal repeat (LTR) of the Moloney MuLV-derived vector. This retrovirus does not exist in nature. An additional copy of the core enhancer acquired from the vector LTR may have augmented the replicative properties of MoLTRAmphoenv MuLV in several different rhesus cell types compared with the prototype amphotropic MuLV4070A. Unexpectedly, at least two types of mink cell focus-forming MuLV elements, arising from endogenous retroviral sequences expressed in the murine packaging cell line, were also transmitted and highly expressed in one of the macaques. Furthermore, murine virus-like VL-30 sequences were detected in the rhesus lymphomas, but these were not transcribed into RNA. The unanticipated presence of an array of MuLV-related structures in a primate gene transfer recipient demands ever-vigilant scrutiny for the existence of transmissible retroviral elements and replication-competent viruses possessing altered tropic or growth properties in packaging cells producing retroviral vectors.     

The Moloney murine leukemia virus repressor binding site represses expression in murine and human hematopoietic stem cells

The Moloney murine leukemia virus (MLV) repressor binding site (RBS) is a major determinant of restricted expression of MLV in undifferentiated mouse embryonic stem (ES) cells and mouse embryonal carcinoma (EC) lines. We show here that the RBS repressed expression when placed outside of its normal MLV genome context in a self-inactivating (SIN) lentiviral vector. In the lentiviral vector genome context, the RBS repressed expression of a modified MLV long terminal repeat (MNDU3) promoter, a simian virus 40 promoter, and three cellular promoters: ubiquitin C, mPGK, and hEF-1a. In addition to repressing expression in undifferentiated ES and EC cell lines, we show that the RBS substantially repressed expression in primary mouse embryonic fibroblasts, primary mouse bone marrow stromal cells, whole mouse bone marrow and its differentiated progeny after bone marrow transplant, and several mouse hematopoietic cell lines. Using an electrophoretic mobility shift assay, we show that binding factor A, the trans-acting factor proposed to convey repression by its interaction with the RBS, is present in the nuclear extracts of all mouse cells we analyzed where expression was repressed by the RBS. In addition, we show that the RBS partially repressed expression in the human hematopoietic cell line DU.528 and primary human CD34(+) CD38(-) hematopoietic cells isolated from umbilical cord blood. These findings suggest that retroviral vectors carrying the RBS are subjected to high rates of repression in murine and human cells and that MLV vectors with primer binding site substitutions that remove the RBS may yield more-effective gene expression.     

A murine leukemia virus (MuLV) long terminal repeat derived from rhesus macaques in the context of a lentivirus vector and MuLV gag sequence results in high-level gene expression in human T lymphocytes

We constructed human immunodeficiency virus type 1 (HIV-1) vectors that will allow higher levels of gene expression in T cells. Gene expression under the control of an internal cytomegalovirus (CMV) immediate-early promoter in a self-inactivating lentiviral vector (CSCG) is 4- to 15-fold lower in T-cell lines (SUPT1 and CEMX174) than in non-lymphoid-cell lines (HeLa and 293T). This is in contrast to a Moloney murine leukemia virus (MoMLV)-based retrovirus vector (SRalphaLEGFP). We therefore replaced the internal CMV promoter of CSCG with three different murine oncoretroviral long terminal repeat (LTR) promoters-murine sarcoma virus (MSV), MoMLV (MLV), and the LTR (termed Rh-MLV) that is derived from the ampho-mink cell focus-forming (AMP/MCF) retrovirus in the serum of one rhesus macaque monkey that developed T-cell lymphoma following autologous transplantation of enriched bone marrow stem cells transduced with a retrovirus vector preparation containing replication-competent viruses (E. F. Vanin, M. Kaloss, C. Broscius, and A. W. Nienhuis, J. Virol. 68:4241-4250, 1994). We found that the combination of Rh-MLV LTR and a partial gag sequence of MoMLV (Deltagag(871-1612)) in CS-Rh-MLV-E gave the highest level of enhanced green fluorescent protein (EGFP) gene expression compared with MLV, MSV LTR, phosphoglycerate kinase, and CMV promoters in T-cell lines, as well as activated primary T cells. Interestingly, there was a further two- to threefold increase in EGFP expression (thus, 10-fold-higher expression than with CMV) when the Rh-MLV promoter and Deltagag(871-1612) were used in a self-inactivating-vector setting that has a further deletion in the U3 region of the HIV-1 LTR. These hybrid vectors should prove useful in gene therapy applications for T cells.     

Adeno-associated virus type 2-mediated transfer of ecotropic retrovirus receptor cDNA allows ecotropic retroviral transduction of established and primary human cells.

The cellular receptors that mediate binding and internalization of retroviruses have recently been identified. The concentration and accessibility of these receptors are critical determinants in accomplishing successful gene transfer with retrovirus-based vectors. Murine retroviruses containing ecotropic glycoproteins do not infect human cells since human cells do not express the receptor that binds the ecotropic glycoproteins. To enable human cells to become permissive for ecotropic retrovirus-mediated gene transfer, we have developed a recombinant adeno-associated virus type 2 (AAV) vector containing ecotropic retroviral receptor (ecoR) cDNA under the control of the Rous sarcoma virus (RSV) long terminal repeat (LTR) promoter (vRSVp-ecoR). Established human cell lines, such as HeLa and KB, known to be nonpermissive for murine ecotropic retroviruses, became permissive for infection by a retroviral vector containing a bacterial gene for resistance to neomycin (RV-Neo(r)), with a transduction efficiency of up to 47%, following transduction with vRSVp-ecoR, as determined by the development of colonies that were resistant to the drug G418, a neomycin analog. No G418-resistant colonies were present in cultures infected with either vRSVp-ecoR or RV-Neo(r) alone. Southern and Northern blot analyses revealed stable integration and long-term expression, respectively, of the transduced murine ecoR gene in clonal isolates of HeLa and KB cells. Similarly, ecotropic retrovirus-mediated Neo(r) transduction of primary human CD34+ hematopoietic progenitor cells from normal bone marrow was also documented, but only following infection with vRSVp-ecoR. The retroviral transduction efficiency was approximately 7% without prestimulation and approximately 14% with prestimulation of CD34+ cells with cytokines, as determined by hematopoietic clonogenic assays. No G418-resistant progenitor cell colonies were present in cultures infected with either vRSVp-ecoR or RV-Neo(r) alone. These results suggest that sequential transduction of primary human cells with two different viral vectors may overcome limitations encountered with a single vector. Thus, the combined use of AAV- and retrovirus-based vectors may have important clinical implications for ex vivo and in vivo human gene therapy.     

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.     

A simple and efficient procedure for generating stable expression libraries by cDNA cloning in a retroviral vector.

cDNA expression cloning is a powerful method for the rescue and identification of genes that are able to confer a readily identifiable phenotype on specific cell types. Retroviral vectors provide several advantages over DNA-mediated gene transfer for the introduction of expression libraries into eukaryotic cells since they can be used to express genes in a wide range of cell types, including those that form important experimental systems such as the hemopoietic system. We describe here a straightforward and efficient method for generating expression libraries by using a murine retroviral vector. Essentially, the method involves the directional cloning of cDNA into the retroviral vector and the generation of pools of stable ecotropic virus producing cells from this DNA. The cells so derived constitute the library, and the virus they yield is used to infect appropriate target cells for subsequent functional screening. We have demonstrated the feasibility of this procedure by constructing several large retroviral libraries (10(5) to 10(6) individual clones) and then using one of these libraries to isolate cDNAs for interleukin-3 and granulocyte-macrophage colony-stimulating factor on the basis of the ability of these factors to confer autonomous growth on the factor-dependent hemopoietic cell line FDC-P1. Moreover, the frequency at which these factor-independent clones were isolated approximated the frequency at which they were represented in the original plasmid library. These results suggest that expression cloning with retroviruses is a practical and efficient procedure and should be a valuable method for the isolation of important regulatory genes.     

Q vectors, bicistronic retroviral vectors for gene transfer

We have developed a retroviral vector that incorporates unique features of some previously described vectors. This vector includes: 3' long terminal repeats (LTRs) of the self-inactivating class; a 5' LTR that is a hybrid of the cytomegalovirus (CMV) enhancer and the mouse sarcoma virus promoter; an internal CMV immediate early region promoter to drive expression of the transduced gene and the neomycin phosphotransferase selectable marker; an expanded multiple cloning site and an internal ribosome entry site. An SV40 ori was introduced into the vector backbone to promote high copy number replication in packaging cell lines that express the SV40 large T antigen. We demonstrate that these retroviral constructs, designated Q vectors, can be used in applications where high viral titers and high level stable or transient gene expression are desirable.     

Generation of RCAS vectors useful for functional genomic analyses.

Avian leukosis type A virus-derived retroviral vectors have been used to introduce genes into cells expressing the corresponding avian receptor tv-a. This includes the use of Replication-Competent Avian sarcoma-leukosis virus (ASLV) long terminal repeat (LTR) with Splice acceptor (RCAS) vectors in the analysis of avian development, human and murine cell cultures, murine cell lineage studies and cancer biology. Previously, cloning of genes into this virus was difficult due to the large size of the vector and sparse cloning sites. To overcome some of the disadvantages of traditional cloning using the RCASBP-Y vector, we have modified the RCASBP-Y to incorporate "Gateway" site-specific recombination cloning of genes into the construct, either with or without HA epitope tags. We have found the repetitive "att" sequences, which are the targets for site-specific recombination, do not impair the production of infectious viral particles or the expression of the gene of interest. This is the first instance of site-specific recombination being used to generate retroviral gene constructs. These viral constructs will allow for the efficient transfer and expression of cDNAs needed for functional genomic analyses.     

Expression from cell type-specific enhancer-modified retroviral vectors after transduction: influence of marker gene stability

The enhanced green fluorescent protein (EGFP) is increasingly used as a reporter gene in viral vectors for a number of applications. To establish a system to study the activity of cis-acting cellular regulatory sequences, we deleted the viral enhancer in EGFP-carrying retroviral vectors and replaced it with cell type-specific elements. In this study, we use this system to demonstrate the activity of the human CD2 lymphoid-specific and the Tie2 endothelial cell type-specific enhancers in cell lines and in primary cells transduced by retroviral vectors. Furthermore, we compare findings obtained with EGFP as the reporter gene to those obtained replacing EGFP with d2EGFP, an unstable variant of EGFP characterized by a much shorter half-life compared to EGFP, and by reduced accumulation in the cells. d2EGFP-carrying vectors were generated at titers which were not different from those generated by the corresponding vectors carrying EGFP. Moreover, the activity of a Moloney murine leukemia virus enhancer could be readily detected following transduction of target cells with either EGFP- or d2EGFP-carrying vectors. However, the activity of the relatively weak CD2 and Tie2 enhancers was exclusively detected using EGFP as the reporter gene.These findings indicate that enhancer replacement is a feasible and promising approach to address the function of cell type-specific regulatory elements in retroviral vectors carrying the EGFP gene.     

Transient gene expression mediated by integrase-defective retroviral vectors

Nonintegrating retroviral vectors were produced from a Moloney murine leukemia virus (MoMLV)-based retroviral vector system by introducing a point mutation into the integrase (IN) gene of the packaging plasmid. The efficacy of IN-defective retroviral vectors was measured through the transient expression of ZsGreen or luciferase in human cell lines. The IN-defective retroviral vectors could transduce target cells efficiently, but their gene expression was transient and lower than that seen with the integrating vectors. IN-defective retroviral vector gene expression decreased to background levels in fewer than 10 days. Southern blot analysis of transduced K562 cells confirmed the loss of a detectable vector sequence by 15 days. The residual integration activity of the IN-defective vector was 1000- to 10,000-fold lower than that of the integrating vector. These results demonstrate that the IN-defective retroviral vectors can provide a useful tool for efficient transient gene expression targeting of primary hematopoietic stem cells and lymphoid cells.     

Mock retroviral infection alters the developmental potential of murine bone marrow stem cells.

Retroviral vectors were used to introduce an activated ras gene into murine pluripotent hemopoietic stem cells. We attempted to reconstitute the hemopoietic system of lethally irradiated mice with isolated spleen colonies obtained in vivo after injection of infected bone marrow cells. Spleen colonies derived from infected bone marrow were inefficient in promoting long-term survival of irradiated hosts. This loss of reconstitutive capacity of spleen colonies was not due to the retroviral infection per se but to the in vitro culture of spleen colony precursors. Incubation for 24 h in the presence of fetal calf serum and interleukin-3 without virus-producing cells was sufficient to abolish completely the reconstitutive capacity of spleen colonies while maintaining both self-renewal and pluripotential capacities of spleen colony precursors. These results show that the in vitro manipulation of stem cells that is included in current protocols for retroviral infection can modify the developmental potential of these cells. This finding clearly indicates that the use of retroviral vectors can introduce a bias in the analysis of hemopoiesis.