Gene therapy of human severe combined immunodeficiency (SCID)-X1 disease

Gene therapy of hematopoietic stem cells: strategies for improvement

Gene therapy of hematopoietic stem cells (HSC) is limited by low frequency of the target cells, their quiescent nature, poor engraftment of treated HSC, and lack of a selective growth advantage of genetically modified cells. Lentiviral vectors combined with positive selection strategies using conditional cell-growth switches should allow for improvement.

Genome medicine: gene therapy for the millennium, 30 September-3 October 2001, Rome, Italy

The recent surge of DNA sequence information resulting from the efforts of agencies interested in deciphering the human genetic code has facilitated technological developments that have been critical in the identification of genes associated with numerous disease pathologies. In addition, these efforts have opened the door to the opportunity to develop novel genetic therapies to treat a broad range of inherited disorders. Through a joint effort by the University of Vermont, the University of Rome, Tor Vergata, University of Rome, La Sapienza, and the CSS Mendel Institute, Rome, an international meeting, 'Genome Medicine: Gene Therapy for the Millennium' was organized. This meeting provided a forum for the discussion of scientific and clinical advances stimulated by the explosion of sequence information generated by the Human Genome Project and the implications these advances have for gene therapy. The meeting had six sessions that focused on the functional evaluation of specific genes via biochemical analysis and through animal models, the development of novel therapeutic strategies involving gene targeting, artificial chromsomes, DNA delivery systems and non-embryonic stem cells, and on the ethical and social implications of these advances.

Mechanisms that regulate silencing of gene expression from retroviral vectors

The propensity of retroviruses toward transcriptional silencing limits their value as gene therapy vectors. Silencing has been shown to be particularly robust when stem cells are used for transduction, posing a significant problem for gene therapy of hematologic diseases. Stability of proviral expression with newer generation vectors is significantly improved over that obtainable with original vectors based on Moloney murine leukemia virus (MoMLV). However, strategies to increase resistance further to retroviral silencing are needed, because newer generation vectors have been shown to remain prone to a significant degree of silencing that could limit their efficacy as gene therapy vectors. Proviral silencing has been attributed to known mechanisms of cellular gene repression, such as DNA methylation and histone modification, as well as uncharacterized mechanisms that act independently of DNA methylation. A further understanding of transcriptional silencing that occurs in stem cells and during hematopoietic development is needed for design of effective vectors for gene therapy of hematologic diseases.

Optimising gene repair strategies in cell culture

Gene repair, the precise modification of the genome, offers a number of advantages over replacement gene therapy. In practice, gene targeting strategies are limited by the inefficiency of homologous recombination in mammalian cells. A number of strategies, including RNA-DNA oligonucleotides (RDOs) and short DNA fragments (SDFs), show promise in improving the efficiency of gene correction. We are using GFP as a reporter for gene repair in living cells. A single base substitution was introduced into GFP to create a nonsense mutation (STOP codon, W399X). RDOs and SDFs are used to repair this mutation episomally in transient transfections and restore green fluorescence. The correction efficiency is determined by FACS analysis. SDFs appear to correct GFP W399X in a number of different cell lines (COS7, A549, HT1080, HuH-7), although all at a similar low frequency ( approximately 0.6% of transfected cells). RDOs correct only one of our cell lines significantly (HT1080-RAD51), these cells overexpress the human RAD51 gene; the bacterial RecA homologue. The GFP W399X reporter is a fusion gene with hygromycin (at the 5' end), this has allowed us to make stable cell lines (A549, HT1080) to study genomic correction. Initial studies using our correction molecules show only low efficiencies of genomic repair ( approximately 10(-4)). Polyethylenimine (PEI) is used to deliver RDOs and SDFs into mammalian cells in culture for our study. We have used fluorescently labelled RDOs and SDFs to study the effectiveness of this process. FACS analysis of transfected nuclei implied efficient delivery (>90%) both with SDFs and RDOs. However, confocal fluorescence microscopy suggests that a large proportion of the complexed RDO/SDF appears to remain outside the nucleus (or attached to the nuclear membrane). On the basis of these data we are assessing new delivery methods and factors that may alter recombination status to optimise gene repair.

Gene transfer to ovarian cancer versus normal tissues with fiber-modified adenoviruses

Adenovirus serotype 5 (Ad5) displays unparalleled gene transfer efficacy to cells with high coxsackie-adenovirus receptor (CAR) expression. Unfortunately, cells isolated from clinical human cancers, both ovarian and other types, express highly variable and often low levels of CAR. Fortunately, native Ad5 tropism can be modified to circumvent CAR deficiency and to enhance infectivity. Ad5/3luc1 incorporates the serotype 3 fiber knob and binds to a receptor distinct from CAR, while the fiber of Ad5lucRGD is modified with an RGD-4C motif, allowing CAR-independent binding to integrins. We studied the liver tropism and blood clearance of these viruses after intravenous (i.v.) injection, and biodistribution after intraperitoneal (i.p.) injection to tumor-bearing mice. To estimate efficacy, we assessed gene transfer to purified human primary ovarian cancer cells, and in a mouse model of ovarian cancer. Ad5/3luc1 achieved improved gene transfer over Ad5lucRGD, and both infectivity-enhanced viruses were superior to the isogenic control with an unmodified Ad5 capsid. In the presence of malignant ascites, gene transfer was improved with both Ad5/3luc1 and Ad5lucRGD. Thus, retargeting to the Ad3 receptor enhances gene transfer to clinically relevant ovarian cancer substrates, while the mouse toxicity and biodistribution profile of both fiber-modified Ad vectors is comparable to Ad5.

Preclinical evaluation of gene transfer products: safety and immunological aspects

As any new drug in development, gene transfer products have to be tested for their potential toxicity in preclinical studies. Strategies for preclinical safety evaluation of gene transfer compounds are similar to those undertaken for biotechnology-derived pharmaceuticals with the added complexity of having to test additional components, such as the vector and genetic material. Some recommendations have been issued by regulatory agencies to provide assistance in the toxicological assessment of gene transfer products before administration to humans. However, the design of such studies is complicated and has to be approached case-by-case. Crucial aspects for safety evaluation are: (1) the choice of animal models with respect to the pharmacological activity of the gene transfer product, the susceptibility to infection in the case of viral vectors, and to the immunogenicity of all entities; (2) biodistribution of the vector after administration, avoiding germinal transmission. Immunological and immunotoxicity endpoints should also be assessed. This paper reviews some of the properties of gene transfer vectors with emphasis on their potential effects on the immune system, and also highlights some of the problems likely to be encountered during the preclinical safety evaluation.

Effect of temperature, medium composition, and cell passage on production of herpes-based viral vectors

Our work uses replication-defective genomic herpes simplex virus type-1 (HSV-1)-based vectors to transfer therapeutic genes into cells of the central nervous system and other tissues. Obtaining highly purified high-titer vector stocks is one of the major obstacles remaining in the use of these vectors in gene therapy applications. We have examined the effects of temperature and media conditions on the half-life of HSV-1 vectors. The results reveal that HSV stability is 2.5-fold greater at 33 degrees C than at 37 degrees C and is further stabilized at 4 degrees C. Additionally, a significantly higher half-life was measured for the vector in infection culture conditioned serum medium compared to fresh medium with or without serum. Synchronous infections incubated at 33 degrees C produced 2-fold higher amounts of vector than infected cells incubated at 37 degrees C, but with a lag of 16-24 h. Vector production yielded 3-fold higher titers and remained stable at peak levels for a longer period of time in cultures incubated at 33 degrees C than 37 degrees C. A pronounced negative effect of increased cell passage number on vector yield was observed. Vector production at 33 degrees C yielded similar levels regardless of passage number but was reduced at 37 degrees C as passage number increased. Together, these results contribute to improved methods for high-titer HSV vector production.

Genetic marking as an approach to studying in vivo hematopoiesis: progress in the non-human primate model

Retroviral insertion site analysis following transplantation of marked hematopoietic stem cells (HSCs) is a powerful method for studying hematopoiesis in vivo. High-level gene transfer efficiency was achieved in murine models in the late 1980s, but early human gene transfer protocols into hematopoietic stem and progenitor cells using the murine methodology showed consistently poor results. The utility of non-human primates as pre-clinical models has since become apparent. Modifications in retroviral transduction conditions have resulted in stable long-term gene transfer efficiency as high as 15-20% to primitive repopulating cells in non-human primate models. This has permitted, for the first time in a large animal model, tracking of individual stem and progenitor cell clones via insertion site analysis, an advantage over competitive transplantation studies, which cannot firmly evaluate the number or life span of individual clones contributing to hematopoiesis. Retroviral tracking studies in mice suggest that stable hematopoiesis may be dominated by a small number of clones, but these studies have been limited by insensitive detection methods, low numbers of transplanted stem cells, and limited life span of immunodeficient mice. Autologous transplantation studies in non-human primates have just begun and have the potential to shed light on controversial issues such as the number of clones contributing to stable hematopoiesis, clonal succession, and lineage commitment, as well as the effect of clinically relevant manipulations such as cytokines, chemotherapy, and radiation on hematopoiesis. These approaches will have significant impact in studying various aspects of stem cell biology including the phenomenon of stem cell plasticity.

Development of gene therapy for blood disorders by gene transfer into haematopoietic stem cells

Haematopoietic stem cells (HSCs) are important target cells for gene therapy of blood disorders due to their pluripotency and ability to reconstitute haematopoiesis following myeloablation and transplantation. HSCs can 'self-renew' and generate new stem cells. Genetically modified stem cells are therefore expected to last a lifetime in the recipient following blood and marrow transplantation, and can potentially cure haematological disorders. Oncoretroviral vectors have been the main vectors used for HSCs because of their ability to integrate into the chromosomes of their target cells. Because oncoretroviral vectors require dividing target cells for successful localization of the preintegration complex and subsequent chromosomal integration of the provirus, only the dividing fraction of the target cells can be transduced. As only a small fraction of haematopoietic stem cells is dividing at any one time, oncoretroviral vector transduction of human HSCs has been low in clinical trials. However, patients with severe combined immune deficiency-X1 (SCID-X1) have recently been treated successfully by gene therapy of autologous bone marrow cells using oncoretroviral vectors containing the common gamma chain gene. While several additional disorders may potentially be treated successfully using oncoretroviral gene transfer to HSCs, many disorders may require much higher gene transfer efficiency than was achieved in the SCID-X1 study. Therefore, lentiviral vectors have recently emerged as promising vectors for human HSCs because they can transduce dividing and nondividing HSCs efficiently, and may become the vectors of choice in the future for treatment of blood disorders where a large fraction of HSCs has to be corrected.

Gene transfer to human placenta ex vivo: a novel application of dual perfusion of human placental cotyledon

OBJECTIVE

The purpose of this study was to determine whether the transfer of a marker gene in dual recirculating human placental perfusion is feasible and whether the transgene production is detectable by X-Gal histochemistry.

STUDY DESIGN

Four term human placentas were perfused for 9 to 16 hours in a dual perfusion chamber. At the beginning of each experiment, an adenoviral vector that carried beta-galactosidase gene was added to the maternal perfusate that was entering the intervillous space; at the end, the placental tissues were analyzed for beta-galactosidase activity by X-Gal staining.

RESULTS

Adenovirus-mediated gene transfer resulted in a 0.5% to 1% gene transfer efficiency in placental trophoblastic cells after 9 hours of perfusion, whereas the gene transfer efficiency was much higher, to 5% after 16 hours of perfusion. When postperfusion tissue explant cultures were analyzed for beta-galactosidase expression 56 hours after the perfusion, the transfection rate was as high as 11%.

CONCLUSION

Perfused human placenta can be efficiently transfected with adenoviral vectors, and the expression of the transgene can be detected in the trophoblastic cells. This system can be used for the optimization and analysis of gene transfer conditions to human placenta without any risk to the fetus.

Primary cellular immunodeficiencies

Genetic defects in T-cell function lead to susceptibility to infections or to other clinical problems that are more grave than those seen in disorders resulting in antibody deficiency alone. Those affected usually present during infancy with either common or opportunistic infections and rarely survive beyond infancy or childhood. The spectrum of T-cell defects ranges from the syndrome of severe combined immunodeficiency, in which T-cell function is absent, to combined immunodeficiency disorders in which there is some, but not adequate, T-cell function for a normal life span. Recent discoveries of the molecular causes of many of these defects have led to a new understanding of the flawed biology underlying the ever-growing number of defects. Most of these conditions could be diagnosed by means of screening for lymphopenia or for T-cell deficiency in cord blood at birth. Early recognition of those so afflicted is essential to the application of the most appropriate treatments for these conditions at a very early age. The latter treatments include both transplantation and gene therapy in addition to immunoglobulin replacement. Fully defining the molecular defects of such patients is also essential for genetic counseling of family members and prenatal diagnosis.

Analysis of adeno-associated virus-mediated ex vivo transferred human beta-globin gene in bone marrow engrafted mice

Adeno-associated virus (AAV)-2 was developed as a useful vector for human gene therapy. In this report, we analyzed the integration and expression of AAV-mediated ex vivo transferred human beta-globin gene in bone marrow (BM) reconstituted mice. Recombinant AAV (rAAV) containing human beta-globin gene was packaged by infecting individual G418-resistant BHK-21 cell clones integrated with the plasmid AV53HS432Deltabeta2.0Neo with recombinant herpes simplex virus, which can express rep and cap genes of wild-type AAV. The titer of rAAV was determined using slot blot hybridization with a result of 10(13) virus particles/ml (genome copy number). Low-density mononuclear cells were isolated from fetal livers of embryos from pregnant C57BL/6 mice at 14-16 days of gestation and were infected with rAAV. The transduced hematopoietic cells were then reinfused into lethally irradiated C57BL/6 recipient mice via tail vein injection. To analyze the provirus in short-term and long-term BM reconstituted mice, PCR/Southern blot and RT-PCR were performed to identify the integrity of the provirus and to detect the expression of human beta-globin gene, respectively. Genomic DNA was extracted from spleen nodules of BM reconstituted mice 12 days after transplantation. Human beta-globin gene was detected in 1 out of 6 nodules using PCR combined with Southern blot. Human beta-globin gene was also detected in the BM and thymus of mouse Y6161, in the thymus and spleen of mouse Y6162 and in the BM of mice Y6211 and Y6212. RT-PCR revealed low levels of expression of human beta-globin gene in the BM of mouse Y6211. Our results suggested that the efficiency of AAV-mediated human beta-globin gene integration into hematopoietic stem/progenitor cells was very low. It is necessary to perform further research on AAV biology before applying gene therapy that requires integration of a foreign gene into host chromosomes.

Biology and treatment of familial hemophagocytic lymphohistiocytosis: importance of perforin in lymphocyte-mediated cytotoxicity and triggering of apoptosis

Familial hemophagocytic lymphohistiocytosis (FHL) is, without treatment, an invariably fatal disease of infancy and early childhood characterized by fever, hepatosplenomegaly, pancytopenia, and a widespread accumulation of T-lymphocytes and macrophages. During recent years, the diagnosis and the survival as well as the understanding of the disease have improved dramatically. Recent studies suggest that FHL is caused by impaired lymphocyte-mediated cytotoxicity and defective triggering of apoptosis, and that the symptoms are mediated by a pro-inflammatory hypercytokinemia. Moreover, specific genetic alterations, mutations in the perforin gene, have been revealed in FHL patients. Perforin, which normally is secreted from cytotoxic T-lymphocytes and natural killer (NK) cells upon conjugation between effector and target cells, is able to insert into the membrane of the target cell. It there polymerizes to form a cell death-inducing pore through which toxic granzymes may enter the cell and trigger apoptosis. The establishment of perforin deficiency as a cause of the rapidly fatal disease FHL has demonstrated the essential role of perforin in human immune homeostasis.

Sustained correction of X-linked severe combined immunodeficiency by ex vivo gene therapy

BACKGROUND

X-linked severe combined immunodeficiency due to a mutation in the gene encoding the common gamma (gamma(c)) chain is a lethal condition that can be cured by allogeneic stem-cell transplantation. We investigated whether infusion of autologous hematopoietic stem cells that had been transduced in vitro with the gamma(c) gene can restore the immune system in patients with severe combined immunodeficiency.

METHODS

CD34+ bone marrow cells from five boys with X-linked severe combined immunodeficiency were transduced ex vivo with the use of a defective retroviral vector. Integration and expression of the gamma(c) transgene and development of lymphocyte subgroups and their functions were sequentially analyzed over a period of up to 2.5 years after gene transfer.

RESULTS

No adverse effects resulted from the procedure. Transduced T cells and natural killer cells appeared in the blood of four of the five patients within four months. The numbers and phenotypes of T cells, the repertoire of T-cell receptors, and the in vitro proliferative responses of T cells to several antigens after immunization were nearly normal up to two years after treatment. Thymopoiesis was documented by the presence of naive T cells and T-cell antigen-receptor episomes and the development of a normal-sized thymus gland. The frequency of transduced B cells was low, but serum immunoglobulin levels and antibody production after immunization were sufficient to avoid the need for intravenous immunoglobulin. Correction of the immunodeficiency eradicated established infections and allowed patients to have a normal life.

CONCLUSIONS

Ex vivo gene therapy with gamma(c) can safely correct the immune deficiency of patients with X-linked severe combined immunodeficiency.

Hematopoietic stem cell gene therapy

Gene therapy applications that target hematopoietic stem cells (HSCs) offer great potential for the treatment of hematologic disease. Despite this promise, clinical success has been limited by poor rates of gene transfer, poor engraftment of modified cells, and poor levels of gene expression. We describe here the basic approach used for HSC gene therapy, briefly review some of the seminal clinical trials in the field, and describe several recent advances directed toward overcoming these limitations.

Gene therapy and reproductive medicine

OBJECTIVE

To review the literature on the principles of gene therapy and its potential application in reproductive medicine.

DESIGN

Literature review.

SETTING

Gene therapy involves transfer of genetic material to target cells using a delivery system, or vector. Attention has primarily focused on viral vectors. Significant problems remain to be overcome including low efficacy of gene transfer, the transient expression of some vectors, safety issues with modified adenoviruses and retroviruses, and ethical concerns. If these issues can be resolved, gene therapy will be applicable to an increasing spectrum of single and multiple gene disorders, as the Human Genome Project data are analyzed, and the genetic component of human disease becomes better understood. Gynecologic gene therapy has advanced to human clinical trials for ovarian carcinoma, and shows potential for the treatment of uterine leiomyomata. Obstetric applications of gene therapy, including fetal gene therapy, remain more distant goals.

CONCLUSION(S)

Concerns about the safety of human gene therapy research are being actively addressed, and remarkable progress in improving DNA transfer has been made. The first treatment success for a genetic disease (severe combined immunodeficiency disease) has been achieved, and ongoing research efforts will eventually yield clinical applications in many spheres of reproductive medicine.

Highly efficient retroviral gene transfer based on centrifugation-mediated vector preloading of tissue culture vessels

Efficient retroviral gene transfer into primary cells is a prerequisite for various gene therapeutic strategies. We have developed a transduction protocol based on the preloading of tissue culture vessels with retroviral particles by low-speed (1000g) centrifugation. We show that vector-preloaded tissue culture vessels allow highly efficient gene transfer into various target cells. We obtained transduction rates of up to 85% for primary T lymphocytes after just a single round of transduction. Under clinically relevant conditions using a vector developed for suicide gene therapy and produced under good manufacturing practice (GMP) conditions, the described method allowed generation of large numbers (>2x10(9)) of gene-modified T cells. The preloading concept ensures transduction of target cells in their optimal growth medium regardless of the medium used for vector production. This facilitated highly efficient gene transfer into quite different target cells such as CD34(+) and AC133(+) bone marrow progenitor as well as mesenchymal stem cells. The presented method combines high gene-transfer rates with a great potential for standardization in accordance with GMP guidelines and is consequently well suited for both research and clinical applications. (c)2002 Elsevier Science (USA).

Development of gene therapy for hematopoietic stem cells using lentiviral vectors

Lentiviral vectors are promising tools for the development of gene therapy since they can transduce both quiescent and dividing target cells. Lentiviral vectors may be particularly promising gene delivery tools for hematopoietic stem cells since these target cells tend to be quiescent and are therefore difficult target cells for vectors that require dividing targets. Human hematopoietic stem cells that can repopulate NOD/SCID mice have been efficiently transduced using HIV-1-based lentiviral vectors and similar vectors can also transduce murine hematopoietic stem cells. HIV-1 vectors that contain strong general promoters can generate high levels of transgene expression and very high expression levels can be generated in erythroid cells in vivo using beta-globin regulatory sequences to control the expression of the transgene. Current lentiviral vectors have a similar level of biosafety as oncoretroviral vectors and can therefore theoretically be used in clinical gene therapy protocols. Future challenges include the generation of lentiviral vectors that can express more than one transgene at high levels and the generation of safe permanent packaging cells for practical use in clinical gene therapy trials.

Enhanced transgene expression in primitive hematopoietic progenitor cells and embryonic stem cells efficiently transduced by optimized retroviral hybrid vectors

Oncoretroviral vectors have been successfully used in gene therapy trials, yet low transduction rates and loss of transgene expression are still major obstacles for their application. To overcome these problems we modified the widely used Moloney murine leukemia virus-derived retroviral vector pMX by replacing the 3'LTR with the spleen focus-forming virus LTR and inserting the woodchuck hepatitis B virus post-translational regulatory element. To compare requirements crucial for efficient transgene expression, we generated the hybrid retroviral vectors pMOWS and pOWS that harbor the complete murine embryonic stem cell virus (MESV)-leader sequence or a shortened MESV-leader not comprising primer binding site (PBS) and splice donor (SD). Applying these retroviral vectors significantly augmented transgene expression in hematopoietic cell lines and progenitor cells. For transduction of murine embryonic stem (ES) cells the retroviral vector pMOWS that harbors the MESV-PBS and -SD was superior resulting in 65% green fluorescent protein (GFP) expressing ES cells. Surprisingly, in murine and human primitive hematopoietic progenitor cells (HPC), the highest efficiency of up to 66% GFP expressing cells was achieved with pOWS, a retroviral vector that retains the negative regulatory element coinciding with the MoMuLV-PBS. In summary our hybrid retroviral vectors facilitate significantly improved transgene expression in multipotent cells and thus possess great potential for reconstituting genes in primary cells of disease models, as well as for gene therapy.

Successful transduction of human multipotent, lymphoid (T, B, NK) and myeloid, and transplantable CD34+CD38low cord blood cells using a murine oncoretroviral vector

Hematopoietic stem cells (HSC) are subject to great interest because of their medical importance and their biological properties. Therefore, the possibility of genetically modifying human HSC is a major concern in several inherited pathologies. In this study, we aimed to demonstrate that a murine oncoretroviral vector can transduce multipotential cord blood (CB) stem cells. Sorted CB CD34(+)CD38(low) cells were transduced with a Moloney-based MFG retroviral vector containing the coding sequence of the murine CD2 (mCD2). CD34(+)mCD2(+) cells were sorted by flow cytometry and cultured either in bulk or at one cell per well in culture conditions that allow differentiation along lymphoid (T, B, and NK) and myeloid (M) lineages. Phenotypic analysis of cells generated in culture showed that CD34(+)mCD2(+) cells could give rise to all lymphoid and myeloid progeny, indicating that the MFG/mCD2 vector had transduced progenitors of all tested lineages. Moreover, clonal cultures of 660 CD34(+)mCD2(+) cells showed that approximately 5% of these cells were able to generate both myeloid and lymphoid (B + NK) progenies; for 25% of them, this included the production of lymphoid T cells. We also demonstrate that transduced CD34(+)CD38(low) CB cells with lymphoid and myeloid potentials were capable of engraftment into the bone marrow (BM) of nonobese diabetic-severe combined immunodeficiency (NOD-SCID) mice during several months. These results show that MFG retroviral vectors can transduce multipotent (T, B, NK, M) human hematopoietic progenitors with in vivo repopulating activity.

Critical issues in gene therapy for neurologic disease

Gene therapy for the nervous system is a newly emerging field with special issues related to modes of delivery, potential toxicity, and realistic expectations for treatment of this vital and highly complex tissue. This review focuses on the potential for gene delivery to the brain, as well as possible risks and benefits of these procedures. This includes discussion of appropriate vectors, such as adeno-associated virus, lentivirus, gutless adenovirus, and herpes simplex virus hybrid amplicons, and cell vehicles, such as neuroprogenitor cells. Routes of delivery for focal and global diseases are enumerated, including use of migratory cells, facilitation of vascular delivery across the blood-brain barrier, cerebrospinal fluid delivery, and convection injection. Attention is given to examples of diseases falling into different etiologic types: metabolic deficiency states, including Canavan disease and lysosomal storage disorders; and degenerative conditions, including Parkinson's disease and other neurodegenerative conditions.

Successful treatment of murine beta-thalassemia intermedia by transfer of the human beta-globin gene

The beta-thalassemias are caused by more than 200 mutations that reduce or abolish beta-globin production. The severity of the resulting anemia can lead to lifelong transfusion dependency. A genetic treatment based on globin gene transfer would require that transgene expression be erythroid specific, elevated, and sustained over time. We report here that long-term synthesis of chimeric hemoglobin (mualpha(2):hubeta(A)(2)) could be achieved in mice with beta-thalassemia intermedia following engraftment with bone marrow cells transduced with a lentiviral vector encoding the human beta-globin gene. In the absence of any posttransduction selection, the treated chimeras exhibit durably increased hemoglobin levels without diminution over 40 weeks. Ineffective erythropoiesis and extramedullary hematopoiesis (EMH) regress, as reflected by normalization of spleen size, architecture, hematopoietic colony formation, and disappearance of liver EMH. These findings establish that a sustained increase of 3 to 4 g/dL hemoglobin is sufficient to correct ineffective erythropoiesis. Hepatic iron accumulation is markedly decreased in 1-year-old chimeras, indicating persistent protection from secondary organ damage. These results demonstrate for the first time that viral-mediated globin gene transfer in hematopoietic stem cells effectively treats a severe hemoglobin disorder.

Drug selection with paclitaxel restores expression of linked IL-2 receptor gamma -chain and multidrug resistance (MDR1) transgenes in canine bone marrow

Unstable expression of transferred genes is a major obstacle to successful gene therapy of hematopoietic diseases. We have investigated in a canine large-animal model whether expression of transduced genes can be recovered in vivo. Mixed-breed dogs had undergone autologous bone marrow transplantation (BMT) with stem cell factor and granulocyte-colony-stimulating factor-mobilized retrovirally marked hematopoietic cells. The bicistronic retroviral vector construct allowed for coexpression of MDR1 and human IL-2 receptor common gamma-chain cDNAs. The latter gene is deficient in X-linked severe combined immunodeficiency. After initial high-level expression, P-glycoprotein and the gamma-chain were undetectable in blood and bone marrow 17 months post-BMT. Six months later, one dog was treated i.v. with 125 mg/m2 paclitaxel. Three administrations restored expression of the two linked genes to high levels in blood and bone marrow. Two dogs treated with higher paclitaxel doses died from myelosuppression after the first administration. As determined by flow cytometry, both genes were expressed in granulocytes, monocytes, and lymphocytes of the surviving animal. PCR analysis of DNA from peripheral blood confirmed that the retroviral cDNA was increased after paclitaxel treatment, suggesting enrichment of transduced cells. P-glycoprotein was detectable for more than 1 year after cessation of paclitaxel. Repeated analyses of blood and bone marrow aspirates gave no indication of hematopoietic disturbance after BMT with transduced cells and paclitaxel treatment. In summary, we have shown that with the use of a drug-selectable marker gene, chemotherapy can select for cells that express an otherwise nonselected therapeutic gene in blood and bone marrow.

Primary immunodeficiency diseases: natural mutant models for the study of the immune system

Primary immunodeficiency diseases represent many natural mutant models for the analysis of many aspects of immunology. Examples dealing with T- and B-cell receptors are herein discussed. They also represent privileged models in medicine, because well characterized monogenic inherited diseases can in some instances be viewed as good targets for gene therapy as shown here for severe combined immunodeficiency (SCID).

Oncoretroviral gene transfer to NOD/SCID repopulating cells using three different viral envelopes

BACKGROUND

The aim of this study was to investigate gene transfer to human umbilical cord blood (CB) CD34(+)/CD38(low) and NOD/SCID repopulating cells using oncoretroviral vectors and to compare the transduction efficiency using three different viral envelopes.

METHODS

CB cells were transduced on Retronectin using an MSCV-based vector with the gene for GFP (MGIN), which was packaged into three different cell lines giving different envelopes: PG13-MGIN (GALV), 293GPG-MGIN (VSV-G) or AM12-MGIN (amphotropic).

RESULTS

Sorted CD34(+)/CD38(low) cells were efficiently transduced after 3 days of cytokine stimulation and the percentage of GFP-positive cells was 61.8+/-6.6% (PG13-MGIN), 26.9+/-3.5% (293GPG-MGIN), and 39.3+/-4.8% (AM12-MGIN). For transplantation experiments, CD34(+) cells were pre-stimulated for 2 days before transduction on Retronectin preloaded with vector and with the addition of 1/10th volume of viral supernatant on day 3. On day 4, the expanded equivalent of 2.5x10(5) cells was injected into irradiated NOD/SCID mice. All three pseudotypes transduced NOD/SCID repopulating cells (SRCs) equally well in the presence of serum, but engraftment was reduced when compared with freshly thawed cells. Simultaneous transduction with all three vector pseudotypes increased the gene transfer efficiency to SRCs but engraftment was significantly impaired. There were difficulties in producing amphotropic vectors at high titers in serum-free medium and transduction of CD34(+) cells using VSV-G-pseudotyped vectors under serum-free conditions was very inefficient. In contrast, transduction with PG13-MGIN under serum-free conditions resulted in the maintenance of SRCs during transduction, high levels of engraftment (29.3+/-6.6%), and efficient gene transfer to SRCs (46.2+/-4.8%).

CONCLUSIONS

The best conditions for transduction and engraftment of CB SRCs were obtained with GALV-pseudotyped vectors using serum-free conditions.

Retroviral transduction and engraftment ability of primate hematopoietic progenitor and stem cells transduced under serum-free versus serum-containing conditions

The ability to efficiently transduce hematopoietic stem and progenitor cells under serum-free conditions would be desirable for safety and standardization of clinical gene therapy protocols. Using rhesus macaques, we studied the transduction efficiency and engraftment ability of CD34-enriched SCF/G-CSF mobilized progenitor cells (PBSC) transduced with standard amphotropic marking vectors under serum-free and serum-containing conditions. Supernatants were collected from producer cells 16 hours after serum-free medium or medium containing 10% fetal calf serum was added. Vector titers were approximately two- to threefold higher when producer cells were cultured in serum-containing medium. However, retroviral transduction of rhesus CFU-GM was improved using serum-free vector-containing medium. For analysis of engraftment with transduced cells, three macaques had CD34+ peripheral blood stem cells split into two fractions for transduction. One fraction was transduced using serum-free vector-containing medium, and the other fraction was transduced using standard serum-containing medium. The two fractions were re-infused simultaneously following total body irradiation. In all three animals, there was equivalent marking from both vectors for 7-9 months post-transplantation. These data are encouraging regarding the removal of serum-containing medium from clinical hematopoietic cell transduction protocols, given the lack of a detrimental effect on transduction and engraftment with transduced cells.

Myeloprotection with drug-resistance genes

One of the many applications of gene transfer for cancer gene therapy is the transfer of drug-resistance genes into bone-marrow stem cells for myeloprotection. Protection of the hosts' bone marrow should allow for dose escalation that may be useful for eradicating minimal residual disease in a post-transplant situation. A number of drug resistance genes, whose products include mutant forms of enzymes that confer resistance to chemotherapeutic drugs, are discussed. Advances in hematopoietic stem cell isolation and ex vivo manipulation has kept pace with improvements in retroviral vector technology to make hematopoietic stem cell transduction a distinct reality. Clinical trials, which have established that the approach is safe, are now being designed to address more therapeutically relevant issues.

Globin gene transfer for the treatment of severe hemoglobinopathies: a paradigm for stem cell-based gene therapy

The prospect of treating blood disorders with genetically modified stem cells is highly promising. This therapeutic approach, however, raises a number of fundamental biological questions, spanning several research fields. Further investigation is required to better understand how to isolate and efficiently transduce hematopoietic stem cells (HSCs), while preserving optimal homing and self-renewing properties; how to design safe vectors permitting controlled expression of the transgene products; and how to promote host repopulation by engrafted HSCs. This article addresses basic issues in stem cell-based gene therapy from the perspective of regulating transgene expression, taking globin gene transfer for the treatment of severe hemoglobinopathies as a paradigm.

Comparison of various envelope proteins for their ability to pseudotype lentiviral vectors and transduce primitive hematopoietic cells from human blood

Substantial effort has been invested in developing methodologies for efficient gene transfer into human, repopulating, hematopoietic stem cells. Oncoretroviral vectors are limited by the lack of nuclear mitosis in quiescent stem cells during ex vivo transduction, whereas the preintegration complex of lentiviral vectors contains nuclear-localizing signals that permit genome integration without mitosis. We have developed a flexible and versatile system for generating lentiviral vector particles and have pseudotyped such particles with amphotropic, ecotropic, feline endogenous virus (RD114) or vesicular stomatitis virus (VSV-G) envelope proteins. Particles of all four types could be concentrated approximately 100-fold by ultracentrifugation or ultrafiltration. RD114 or amphotropic particles were more efficient than VSV-G-pseudotyped particles at transducing human cord blood CD34(+) cells and clonogenic progenitors within that population. Amphotropic particles transduced cytokine-mobilized, human peripheral blood CD34(+) cells capable of establishing hematopoiesis in immunodeficient mice more efficiently than the other two types of particles. We conclude that the use of amphotropic pseudotyped lentiviral vector particles rather than the commonly used VSV-G-pseudotyped particles should be considered in potential applications of lentiviral vectors for gene transfer into this therapeutically relevant target cell population.

Functional epitope of common gamma chain for interleukin-4 binding

Interleukin 4 (IL-4) can act on target cells through an IL-4 receptor complex consisting of the IL-4 receptor alpha chain and the common gamma chain (gamma(c)). An IL-4 epitope for gamma(c) binding has previously been identified. In this study, the gamma(c) residues involved in IL-4 binding were defined by alanine-scanning mutational analysis. The epitope comprises gamma(c) residues I100, L102, and Y103 on loop EF1 together with L208 on loop FG2 as the major binding determinants. These predominantly hydrophobic determinants interact with the hydrophobic IL-4 epitope composed of residues I11, N15, and Y124. Double-mutant cycle analysis revealed co-operative interaction between gamma(c) and IL-4 side chains. Several gamma(c) residues involved in IL-4 binding have been previously shown to be mutated in X-linked severe combined immunodeficiency. The importance of these binding residues for gamma(c) function is discussed. These results provide a basis for elucidating the molecular recognition mechanism in the IL-4 receptor system and a paradigm for other gamma(c)-dependent cytokine receptor systems.