Retroviral Vector-mediated Gene Transfer Research Articles

Retrovirus-mediated gene transfer of the human gamma-IFN gene: a therapy for cancer.

A retroviral vector-mediated gene transfer system was used to introduce m gamma-IFN and h gamma-IFN genes into mouse and human tumor cells, respectively. Murine tumor cell lines and primary human melanoma tumor cells were successfully transduced with gamma-IFN vector, and these transduced cells secreted measurable levels of biologically active m gamma-IFN and h gamma-IFN, respectively. Both murine and human tumor cell lines that expressed gamma-IFN exhibited increased surface expression of HLA class I antigens when tested by Western blot and FACS analysis. gamma-IFN--transduced human melanoma cells were more active in stimulating tumor-specific cytolytic activity of CTLs from melanoma patients in vitro. m gamma-IFN--transduced tumor cells were substantially less tumorigenic than the corresponding parent tumor cell lines in immune-competent mice. In addition, injection of m gamma-IFN--transduced tumor cells resulted in activation of tumor-specific CTL in vivo. We plan to use gamma-IFN--transduced autologous tumor cells to boost host immune responses as a potential therapy for human melanoma.

Peripheral Blood Lymphocytes as Target Cells of Retroviral Vector-Mediated Gene Transfer

AbstractPeripheral blood lymphocytes (PBLs) are key target cells for gene therapy of a number of inherited and acquired blood disorders. We have systematically compared four retroviral vectors, designed according to different strategies, for their efficiency in transfer and expression in human PBLs of the same reporter gene. The receptor gene used in the study codes for the human low-affinity nerve growth factor receptor (LNGFR), and is not expressed on the majority of human hematopoietic cells, thus allowing quantitative analysis of the transduced gene expression by immunofluorescence, with single cell resolution. Peripheral blood mononuclear cells (PBMCs), as well as human hematopoietic cell lines of myeloid and lymphoid origin, were transduced with the four vectors and analyzed for efficiency of gene transfer, integration and stability of vector proviruses, and LNGFR expression at both RNA and protein level. Fluorescence-activated cell sorter analysis of coexpression of LNGFR and lineage-specific cell surface markers was performed in transduced cell lines, PBLs, and T-cell clones to study gene expression on specific cell subpopulations. Although crucial differences were observed among different constructs, all retroviral vectors could transduce, under appropriate infection conditions, T-cell populations representative of the normal immune repertoire. Gene transfer and expression could be demonstrated also in circulating progenitors of mature T cells. Expression of the transduced gene was heterogeneous among cell populations infected with the different vectors, with optimal results obtained by two of the four constructs. Finally, we have devised a simple protocol based on vector-mediated gene transfer and positive immunoselection of the transduced cells that produces virtually 100% gene-modified cells. This may represent a crucial improvement in the way of designing efficacious protocols involving the use of gene-modified T lymphocytes in clinical studies.

Retroviral Vector-Mediated Gene Transfer into Human Primary Myogenic Cells Leads to Expression in Muscle FibersIn Vivo

Primary human myogenic cells isolated from fetal and adult muscle were infected with a high-titer, Moloney murine leukemia virus (MoMLV)-derived retroviral vector expressing a bacterial beta-galactosidase (beta-gal) gene under long terminal repeat (LTR) control. Gene transfer efficiency averaged 50% in both fetal myoblasts and adult satellite cells, as revealed by beta-gal staining. The reporter gene was stably integrated, faithfully inherited, and expressed at significant levels in myogenic cells for at least 10 generations under clonal growth conditions, and throughout the culture life span upon differentiation into myotubes. Comparable gene transfer efficiency was obtained in myogenic cells from muscle biopsies of patients affected by a number of genetic or acquired myopathies, including Duchenne muscular dystrophy. Transduced normal human satellite cells were injected into regenerating muscle of immunodeficient mice, where they formed new muscle fibers in which the product of the reporter gene was detectable for 2 months after injection. These results show that retroviral vectors can be used to transfer foreign genes with high efficiency into normal or abnormal primary human myogenic cells, leading to stable expression into mature muscle. Satellite cells engineered in this way might represent an effective tool for gene therapy of muscular dystrophies as well as for systemic delivery of recombinant gene products for correction of inherited and acquired disorders. The human-mouse model described here will allow in vivo testing of such gene therapy approaches.

DIFFERENTIATION THERAPY OF CANCER TARGETING THE RI-ALPHA REGULATORY SUBUNIT OF CAMP-DEPENDENT PROTEIN-KINASE (REVIEW)

Consideration of the cancer process as a problem of blocked ontogeny makes attractive the approach to the control of cancer through differentiation therapy. The use of antisense strategy and retroviral vector-mediated gene transfer technology provided direct evidence that two isoforms of cAMP receptor protein, the RI and RII regulatory subunits of cAMP-dependent protein kinase, have opposite, roles in cell growth and differentiation, RI being growth stimulatory while RII is a growth-inhibitory and differentiation-inducing protein. As RIalpha expression is enhanced during cell transformation, and in primary human tumors and cancer cell lines as compared to their normal counterparts, it is an attractive target for cancer treatment. 8-Cl-cAMP and RIalpha antisense oligodeoxynucleotide, those that effectively down-regulate RIalpha and upregulate RIIbeta without producing cytotoxicity, provide new approaches toward differentiation therapy of cancer.

Gene transfer of herpes simplex virus type I thymidine kinase gene as a drug sensitivity gene into human lung cancer cell lines using retroviral vectors.

One of the recent strategies for gene therapy as a cancer control is the targeted introduction of a drug-sensitivity gene into tumor cells. We investigated the gene transfer of herpes simplex virus type I thymidine kinase (HSV-TK) gene as a drug-sensitivity gene into human lung cancer cell lines. We used a recombinant retroviral vector derived from Moloney murine leukemia virus (MuLV) as one of potential vectors for gene therapy. The amphotropic retroviral vector consisted of the HSV-TK gene and the neomycin-resistant gene under Rous sarcoma virus (RSV) promoter control. The antiherpes drugs, acyclovir (ACV) and ganciclovir (GCV), were chosen for testing the activity of HSV-TK that was transferred into human lung cancer cell lines. ACV and GCV are nucleoside analogs specifically converted by HSV-TK to a toxic form capable of inhibiting DNA synthesis. The cytotoxicity was determined by using a tetrazolium-based colorimetric assay (MTT assay). The results obtained from our experiments demonstrated that the retroviral vector-mediated HSV-TK gene transfer leads to ACV- and GCV-dependent cytotoxicity in human lung cancer cell lines, which were both small cell carcinoma and non-small cell carcinoma established from human specimens. These findings suggest that the gene transfer of HSV-TK gene into tumor cells would be one of the models for the use of gene therapy to control lung cancer.

Generation of human monoclonal antibodies by transformation of lymphoblastoid B cells with ras oncogene

Human monoclonal antibodies (hu-mAbs) of predetermined specificity and isotype are potentially important for a variety of applications, including therapy and diagnosis. Their efficient generation, however, is still hampered by technical difficulties. Even the most established approaches to the generation of hu-mAbs, i.e., B cell immortalization by Epstein-Barr virus (EBV) and/or fusion with appropriate myeloma cell lines, are characterized by a relatively low efficiency. It has been shown that expression of activated Ha- or N-ras oncogenes causes the malignant transformation and plasmacytoid differentiation of EBV-immortalized lymphoblastoid cell (LC) lines, suggesting that activated ras oncogenes can convert LC lines into effective hu-mAb producers. We have used retroviral vector-mediated gene transfer to introduce an activated Ha-ras (v-ras) oncogene into four distinct LC lines producing hu-mAbs of different classes (IgM and IgG) and specificities (to human insulin, human thyroglobulin and rabies virus glycoprotein). The cloning efficiency and antibody secretion of these ras-transformed LC (ras-LC) lines were compared with those of the hybrid LC (hyb-LC) lines generated by fusing the same parental LC lines with the Ig non-secretor F3B6 human-mouse hybrid cells. ras-LC lines were comparable to their hybrid counterparts in either parameter tested. This, together with the relatively higher efficiency of the method, suggests that ras transformation may constitute a valid alternative to the currently available technologies for hu-mAbs production from LC lines.

Transfer of the ADA gene into human ADA-deficient T lymphocytes reconstitutes specific immune functions

Peripheral blood lymphocytes obtained from a patient affected by adenosine deaminase (ADA) deficiency and severe combined immunodeficiency were infected with a retroviral vector containing two copies of a human ADA minigene, and injected into bg/nu/xid (BNX) immunodeficient mice. Six to 10 weeks after injection, human T cells were cloned from the spleens of recipient animals and analyzed for proliferative potential, T-cell surface markers, expression of ADA activity, integration of retroviral sequences, T-cell receptor (TCR) beta gene rearrangement, and specificity of antigen recognition. Efficient gene transfer and expression restored proliferative potential in vitro and long-term survival in vivo. All clonable human T lymphocytes obtained from the spleen of recipient animals had high levels of vector-derived ADA enzyme activity and showed predominantly the CD4+ phenotype. Retroviral integrations and TCR-beta gene rearrangements demonstrated the presence of a variety of different clones in the spleens of recipient mice. Furthermore, the combined analyses of vector integration and TCR rearrangement provided evidence that a circulating progenitor cell was transduced by the retroviral vector, giving rise to different and functional TCRs. Evaluation of antigen-specificity demonstrated both alloreactive and foreign antigen specific immune responses. These results suggest that restoration of enzyme activity in human ADA-deficient peripheral blood T cells by retroviral-mediated ADA gene transfer allows in vivo survival and reconstitution of specific immune functions. Therefore, retroviral vector-mediated gene transfer into circulating mononuclear cells could be successful not only in maintaining the metabolic homeostasis, but also for the development of a functional immune repertoire. This is a fundamental prerequisite for the usage of genetically engineered peripheral blood lymphocytes for somatic cell gene therapy of ADA deficiency.

Transfer of the ADA Gene Into Human ADA-Deficient T Lymphocytes Reconstitutes Specific Immune Functions

Peripheral blood lymphocytes obtained from a patient affected by adenosine deaminase (ADA) deficiency and severe combined immunodeficiency were infected with a retroviral vector containing two copies of a human ADA minigene, and injected into bg/nu/xid (BNX) immunodeficient mice. Six to 10 weeks after injection, human T cells were cloned from the spleens of recipient animals and analyzed for proliferative potential, T-cell surface markers, expression of ADA activity, integration of retroviral sequences, T-cell receptor (TCR) beta gene rearrangement, and specificity of antigen recognition. Efficient gene transfer and expression restored proliferative potential in vitro and long-term survival in vivo. All clonable human T lymphocytes obtained from the spleen of recipient animals had high levels of vector-derived ADA enzyme activity and showed predominantly the CD4+ phenotype. Retroviral integrations and TCR-beta gene rearrangements demonstrated the presence of a variety of different clones in the spleens of recipient mice. Furthermore, the combined analyses of vector integration and TCR rearrangement provided evidence that a circulating progenitor cell was transduced by the retroviral vector, giving rise to different and functional TCRs. Evaluation of antigen-specificity demonstrated both alloreactive and foreign antigen specific immune responses. These results suggest that restoration of enzyme activity in human ADA-deficient peripheral blood T cells by retroviral-mediated ADA gene transfer allows in vivo survival and reconstitution of specific immune functions. Therefore, retroviral vector-mediated gene transfer into circulating mononuclear cells could be successful not only in maintaining the metabolic homeostasis, but also for the development of a functional immune repertoire. This is a fundamental prerequisite for the usage of genetically engineered peripheral blood lymphocytes for somatic cell gene therapy of ADA deficiency.

Correction of alpha-L-fucosidase deficiency in fucosidosis fibroblasts by retroviral vector-mediated gene transfer.

A full-length cDNA clone encoding the lysosomal hydrolase alpha-L-fucosidase was cloned into two retroviral vectors, one using the human cytomegalovirus immediate-early promoter for expression, and the other, the retroviral long terminal repeat (LTR). High-titer amphotropic virus was produced for both constructs by infection of PA317 cells, and used to efficiently transduce the alpha-L-fucosidase gene into both human and canine fucosidosis fibroblasts. This resulted in correction of the alpha-L-fucosidase enzyme deficiency characteristic of these fibroblasts. The high levels of recombinant enzyme produced corrected the degradative defect normally seen in these cells, enabling them to catabolize efficiently the accumulated storage product present in lysosomes. Therefore, these retroviral constructs should allow us to start evaluating the value of gene therapy in treating the central nervous system pathology associated with fucosidosis and other lysosomal storage disorders in humans, using a canine model of fucosidosis.

Retroviral vector-mediated gene transfer into hematopoietic cells: prospects and issues.

Gene therapy is a developing technology that may allow the treatment of a variety of congenital and acquired genetic disorders as well as infectious diseases through the introduction of exogenous genetic material into relevant cellular populations. Currently, the most effective method for gene transfer into cells of the hematopoietic system is with retroviral vectors. Appropriate cellular targets for gene transfer include totipotent hematopoietic stem cells as well as long-lived lineage committed cells such as T lymphocytes. Although retroviral vector-mediated gene transfer into totipotent stem cells and subsequent long-term expression of transduced genetic material in stem cell progeny has been observed in murine bone marrow transplantation experiments, similar observations have not been made in clinically relevant large-animal models. A number of recent advances in gene delivery systems, purification of stem cells, defining extramedullary sources of stem cells, characterizing the biologic processes that regulate the proliferation and developmental potential of stem cells, and construction of more effective models for assessing stem cells, may result in improvements in gene transfer into large animal and human totipotent stem cells.

Induction of HIV-Specific CTL and Antibody Responses in Mice Using Retroviral Vector-Transduced Cells

Recombinant retroviral vectors can efficiently transduce and express foreign genes in mammalian cells. We have examined the utility of retroviral vector-mediated gene transfer to deliver genes which encode human immunodeficiency virus type I (HIV) antigens capable of stimulating specific immune responses. Murine fibroblast cell lines were transduced with a nonreplicating murine retroviral vector carrying the gene encoding the HIV-IIIB envelope protein and were shown to express the gp160/120 protein. Mice immunized with syngeneic vector-transduced cells developed CD8+, class I major histocompatibility complex (MHC)-restricted cytotoxic T lymphocytes (CTL) specific for targets expressing the HIV envelope protein. The CTL also exhibited lytic activity on target cells coated with synthetic peptides derived from the gp120 V3 hypervariable region of both the HIV-IIIB and HIV(MN) isolates. Following adoptive transfer in a murine tumor model, these CTL were shown to be effective in vivo by their ability to eliminate established tumor cells expressing the HIV protein. Vector-transduced syngeneic cells were also capable of eliciting HIV envelope-specific antibody responses in immunized mice. Sera obtained from these mice were found to bind to the HIV-IIIB gp160 protein as well as a peptide-defined neutralizing antibody epitope contained within the V3 domain of gp120. These sera exhibited virus-neutralizing activity in that they markedly reduced the ability of HIV to infect and form syncytia of a human T-cell line. This is the first demonstration that cells transduced with a retroviral vector encoding the HIV-IIIB envelope protein are capable of inducing effective HIV-specific cellular and humoral immune responses in mice.

Toward Gene Therapy for Gaucher Disease

We are studying the transfer and expression by retroviral vectors of the human glucocerebrosidase (GC) gene into bone marrow cells as a model of gene therapy for genetic diseases of hematopoietic cells. A simple retroviral vector (G2) was developed that contains a normal human GC cDNA under the control of the Moloney murine leukemia virus long-terminal repeat (LTR) enhancer/promoter. Murine bone marrow was transduced with the G2 vector and maintained in long-term bone marrow culture (LTBMC). Expression of the human GC gene in the transduced murine LTBMC cells exceeded the level of endogenous murine GC mRNA. Murine bone marrow cells were also transduced with G2 and transplanted into irradiated syngeneic recipients. High levels of GC gene transfer and expression were seen in day-12 CFU-S foci, and to a lesser extent in the hematopoietic organs 4 months after gene transfer/bone marrow transplant (BMT). Human bone marrow, from a patient with Gaucher disease, was also used in studies of GC gene transduction. Gene transfer into 35-40% of the Gaucher hematopoietic progenitor cells was achieved, following prestimulation of the marrow with recombinant hematopoietic growth factors. Equal rates of gene transfer were obtained using either total marrow mononuclear cells or progenitor cells enriched 100-fold by immunomagnetic bead separation. GC gene transduction corrected the enzymatic deficiency of the Gaucher marrow. Our results demonstrate the potential utility of retroviral vector-mediated gene transfer for gene therapy of Gaucher disease. Current efforts are aimed at achieving more consistent in vivo GC expression in the murine BMT model and demonstrating transduction of pluripotent human hematopoietic stem cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of a Foreign Gene in Cats Reconstituted With Retroviral Vector Infected Autologous Bone Marrow

A Moloney murine leukemia virus based retroviral vector was used to transfer the bacterial neomycin resistance gene (neoR) into feline hematopoietic cells. We reconstituted four cats that had been lethally irradiated with autologous bone marrow that had been infected with the N2 or SAX retroviral vector. Bone marrow cells from all four cats expressed the neoR gene 30 days posttransplant and three of four cats still had the neoR gene and a low level of drug resistant colony-forming unit granulocyte-macrophage after more than 200 days. Two of the four cats unexpectedly developed diabetes mellitus 90 days posttransplantation. The expression of a foreign gene in cats, albeit at a low level, demonstrates that retroviral vectors can be used for gene transfer in noninbred large animal species and may be useful for gene therapy of humans. The development of diabetes mellitus in two of the subjects emphasizes the value of animal models for the study of possible deleterious effects of retroviral vector-mediated gene transfer.

Expression of a foreign gene in cats reconstituted with retroviral vector infected autologous bone marrow

A Moloney murine leukemia virus based retroviral vector was used to transfer the bacterial neomycin resistance gene (neoR) into feline hematopoietic cells. We reconstituted four cats that had been lethally irradiated with autologous bone marrow that had been infected with the N2 or SAX retroviral vector. Bone marrow cells from all four cats expressed the neoR gene 30 days posttransplant and three of four cats still had the neoR gene and a low level of drug resistant colony- forming unit granulocyte-macrophage after more than 200 days. Two of the four cats unexpectedly developed diabetes mellitus 90 days posttransplantation. The expression of a foreign gene in cats, albeit at a low level, demonstrates that retroviral vectors can be used for gene transfer in noninbred large animal species and may be useful for gene therapy of humans. The development of diabetes mellitus in two of the subjects emphasizes the value of animal models for the study of possible deleterious effects of retroviral vector-mediated gene transfer.

Enhancement of the fibrinolytic activity of sheep endothelial cells by retroviral vector-mediated gene transfer

In an attempt to enhance the fibrinolytic activity of endothelial cells (EC), a retroviral vector containing the human tissue-type plasminogen activator (t-PA) cDNA was constructed. Sheep EC were stably transduced with the vector, resulting in a 30-fold increase in t-PA activity over that detected in EC transduced with a control vector. Southern and Northern analyses confirmed the presence of both the vector sequence and the appropriate mRNA transcripts. Secretion of high levels of recombinant human t-PA continued in vitro for the duration of the experiments, up to 11 weeks after transduction, although the rate of t- PA secretion decreased in some of the EC lines. Zymographic analysis of conditioned medium from t-PA-transduced EC showed the presence of two new molecular species with plasminogen activator activity that could be specifically immunoprecipitated with a monoclonal antihuman t-PA antibody. The relative molecular masses of these species (60 to 80 and 110 Kd) suggest that they represent recombinant human t-PA both free and bound to sheep plasminogen activator inhibitor 1 (PAI-1). Consistent with this interpretation, the 110-Kd species could be specifically immunoprecipitated with antiserum to PAI-1. These studies demonstrate that retroviral vector-mediated gene transfer may be used to increase total EC fibrinolytic activity.

Enhancement of the Fibrinolytic Activity of Sheep Endothelial Cells by Retroviral Vector-Mediated Gene Transfer

In an attempt to enhance the fibrinolytic activity of endothelial cells (EC), a retroviral vector containing the human tissue-type plasminogen activator (t-PA) cDNA was constructed. Sheep EC were stably transduced with the vector, resulting in a 30-fold increase in t-PA activity over that detected in EC transduced with a control vector. Southern and Northern analyses confirmed the presence of both the vector sequence and the appropriate mRNA transcripts. Secretion of high levels of recombinant human t-PA continued in vitro for the duration of the experiments, up to 11 weeks after transduction, although the rate of t-PA secretion decreased in some of the EC lines. Zymographic analysis of conditioned medium from t-PA-transduced EC showed the presence of two new molecular species with plasminogen activator activity that could be specifically immunoprecipitated with a monoclonal antihuman t-PA antibody. The relative molecular masses of these species (60 to 80 and 110 Kd) suggest that they represent recombinant human t-PA both free and bound to sheep plasminogen activator inhibitor 1 (PAI-1). Consistent with this interpretation, the 110-Kd species could be specifically immunoprecipitated with antiserum to PAI-1. These studies demonstrate that retroviral vector-mediated gene transfer may be used to increase total EC fibrinolytic activity.

Comparison of the Effects of Growth Factors on Retroviral Vector-Mediated Gene Transfer and the Proliferative Status of Human Hematopoietic Progenitor Cells

We have examined the ability of the recombinant hematopoietic growth factors (HGF) interleukin-3 (IL-3), IL-6, and granulocyte-macrophage colony-stimulating factor (GM-CSF) to increase retroviral vector-mediated gene transfer into human hematopoietic progenitor cells (HPC). The efficiency of neo gene transfer by the N2 vector into human HPC was enhanced by preculture with either GM-CSF or IL-3 (but not IL-6) and with each combination of the three factors. The combination of IL-3 plus IL-6 consistently produced significantly higher levels of G418-resistant colonies (50-60%) than any of the other combinations of HGF tested. Following preculture with HGF and transduction by N2, marrow was maintained in long-term bone marrow culture (LTBMC) for 2 months. The levels of G418-resistant HPC remained stable, and no apparent depletion of total HPC content resulted from the prior exposure to highly stimulatory doses of factors. The proliferative status of the HPC, following exposure to the HGF, was measured as the percentage of HPC that were inhibited from forming colonies by exposure to the S-phase-specific drug, hydroxyurea. The ability of the different HGF to increase the rate of gene transfer by N2 correlated significantly with the extent to which they stimulated HPC proliferation. These results suggest that the mechanism by which HGF increase rates of gene transfer into HPC is by stimulating cell proliferation. Techniques that produce high rates of gene transfer into long-lived human HPC will facilitate studies to quantitate expression of exogenous genes in hematopoietic cells and may be applicable to clinical gene therapy.

Genes transferred by retroviral vectors into normal and mutant myoblasts in primary cultures are expressed in myotubes.

Retroviral vectors were used to transfer genes efficiently into rat and dog myoblasts in primary cultures under conditions which permitted the transduced myoblasts to differentiate into myotubes expressing the transferred genes. The transduced myotubes expressed normal markers of differentiation and were morphologically indistinguishable from uninfected myotubes. Retroviral vector-mediated gene transfer was also used to correct a genetic enzyme deficiency in mutant canine muscle cells.

Genes Transferred by Retroviral Vectors into Normal and Mutant Myoblasts in Primary Cultures Are Expressed in Myotubes

Retroviral vectors were used to transfer genes efficiently into rat and dog myoblasts in primary cultures under conditions which permitted the transduced myoblasts to differentiate into myotubes expressing the transferred genes. The transduced myotubes expressed normal markers of differentiation and were morphologically indistinguishable from uninfected myotubes. Retroviral vector-mediated gene transfer was also used to correct a genetic enzyme deficiency in mutant canine muscle cells.

Retroviral vector-mediated gene transfer and expression in nonhuman primates following autologous bone marrow transplantation.

Retroviral vector-mediated gene transfer and expression in nonhuman primates following autologous bone marrow transplantation.